“Micropropagation Studies On Bambusa Tulda, Dendrocalamus Longipathus And Chemoprofiling Of Rauwolfea Serpentine”

INTRODUCTION

1.1 Biotechnology
The term biotechnology represents a fusion or an alliance between
biology and technology. Biotechnology is as old as human civilization and is
an integral part of human life. There are records that wine and beer were
prepared in as early as 600 B.C. bread and curd in 4000 B.C. The term
biotechnology was introduced in 1917 by Hungarian engineer, Karl Ereky.

It concerns with the exploitation of biological agents or their
components for generating useful products / services. The area covered
under biotechnology is very vast and the techniques involved are highly
divergent.

1.1.1 Definition of Biotechnology :
• Biotechnology consists of ‘the controlled use of biological agents, such as,
micro-organisms or cellular components, for beneficial use”.
U.S. National Science Foundation

• Biotechnology is “the integrated use of biochemistry, microbiology and
engineering sciences in order to achieve technological application of the
capabilities of micro organisms, cultured tissues / cells and parts thereof”.
European Federation of Biotechnology (1981)

• Biotechnology comprises the “controlled and deliberate application of
simple biological agents – living or dead, cells or cell components – in
technically useful operations, either of productive manufacture or as
service operation”.
J.D. Bu’lock (1987)

• The application of biological organisms, systems or process constitutes
biotechnology.
British Biotechnologist

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• Biotechnology is “the use of living organisms in system or processes for
the manufacture of useful products, it may involve algae, bacteria, fungi,
yeast, cells of higher plants and animals or sub systems of any of these or
isolated components from living matter”.
Gibbs and Greenhalgh (1983)

• Biotechnology is the application of scientific and engineering principles to
the processing of materials by biological agents to provide goods and
services”.
Organization of Economic Co-operation and Development (1981)

• Biotechnology is the application of biochemistry, biology, microbiology and
chemical engineering to industrial process and products and on
environment.
International Union of Pure and Applied Chemistry (1981)

1.1.2 Major Fields of Biotechnology :

Medicines Animal health
Human health
Animal husbandry

Fisheries &
aquaculture
Dairy

Mining

Chemicals &
biochemicals
Population
control BIOTECHNOLOGY
Food processing &
beverages
Renewable
energy and fruits

Crimes &
percentage
Environment
Agriculture

Horticulture & Forestry Plant
floriculture Biotechnology
1.1.3 Importance of Biotechnology :
Biotechnology has rapidly emerged as an area of activity having a
worked realized as well as potential impact on virtually all domains of human

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welfare ranging from food processing, protecting the environment, to human
health. It how plays a very important role in employment, production and
productivity, trade, economics and economy, human health and the quality of
human life throughout the world.

The importance of biotechnology to human welfare as for the protection
of human health, production of monoclonal antibodies, DNA & RNA probes
(for disease diagnosis), artificial vaccines (for inoculation), rare and highly
valuable drugs, such as human interferon, insulin etc. (for disease treatment)
and the technology for gene therapy (for treatment of genetic diseases) are
some of the notable achievements.

Micro-organisms are being employed since several decades for the
large scale production of a variety of biochemical’s ranging from alcohol to
antibiotics in processing of foods and feeds. Enzymes, isolated mainly from
microorganisms and immobilized in suitable polymers (called matrices) are
preferred over the whole organisms for a variety of reasons; they are
becoming increasing popular in many commercial ventures.

Several biological agents, such as, viruses, fungi, amoebae etc. are
being exploited for the control of plant diseases and insect pests. Bacteria are
being utilized for detoxification of industrial effluent (wastes), for treatment of
sewage and for biogas production.

Invitro fertilization and embryo transfer techniques have permitted
childless couples, suffering from one or the there kind of sterility, to have their
own babies (test tube babies).

Genetic engineering is being employed to develop transgenic animals /
plants resistant to certain diseases.

In agriculture, rapid and economic clonal multiplication of fruit and
forest trees, production of virus free stocks of clonal crops through genetic
engineering have opened up exciting possibilities in crop production,
protection and improvement.

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1.2 Plant Biotechnology
Plant Biotechnology in the implication of biotechnological tools for
improving the genotype, phynotypic tool for improving the genotype,
phenotype, performance, multiplication rate of plant or exploiting cell
constituent, generating useful products.

Plant biotechnology may be defined as generations of useful products
or services from plant cells, tissue & organs. Such cells, tissues and organs
are either continuously maintained invitro or they pass through a variable.

In vitro phase to enable generation from them of complete plantlets
which is ultimately transferred to field therefore plant tissue culture technique
form an integral part of plant biotech activities.

1.2.1 Objectives : The various objectives achievable / achieved by plant
biotechnology may be summarized as under :
1. Rapid clonal multiplication (adventitious shoots / bulb/protocorm or SE
regeneration, axillary bud proliferation).
2. Germplasm conservation of vegetatively reproducing plants or those
producing recalcitrant seeds (cryo-preservation, slow – growth cultures,
DNA clones).
3. Production / recovery of difficult to produce hybrids (embryo rescue,
invitro pollination).
4. Virus elimination (thermo-cryo or chemo - therapy coupled with ē
meristem culture).
5. Rapid development of homozygous lines by producing haploids
(anther culture, ovary culture, interspecific hybridization).
6. Useful biochemical production (large scale cell culture).
7. Genetic modification of plants (somaclonal variation, somatic
hybridization, cybridization and genetic engineering).
8. Creation of genome maps and use of molecular markers to assist
conventional breeding efforts.
9. Haploid production.

1.3 Techniques In Plant Biotechnology

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Plant biotechnology comprises two major techniques
1. Plant Genetic Engineering
2. Plant Tissue Culture

1.3.1 Plant Genetic Engineering :
Genetic engineering is an umbrella term, which can cover a wide range
of way of changing the genetic material the DNA code – in living organisms.
This code contains all the information, stored in a long chain chemical
molecule which determines the nature of the organisms. The technique not
only allows more precise changes, but also it greatly increases the efficiency
of generating genetically engineered plants to use as food, fuel or to absorb
carbon and cleaning the environment.

Genetically engineering plants is a time intensive process. Methods
currently used to deliver genetic changes are imprecise, so its often necess
any to generate thousands of plants to find one that happens to have the
desired alteration.

Concept :
Genetic engineering is the alteration of genetic material by direct
intervention in genetic processes with the purpose of producing new
substances or improving functions of existing organisms. It is a very young,
exciting, and controversial branch of the biological sciences. On the one hand,
it offers the possibility of cures for diseases and countless material
improvements to daily life. The Human Genome Project, a vast international
effort to categorize all the genes in the human species, symbolizes hopes for
the benefits of genetic engineering. On the other hand, genetic engineering
frightens many with its potential for misuse; either in Nazi-style schemes for
population control or through simple bungling that might produce a biological
holocaust caused by a man-made virus. Symbolic of the alarming possibilities
if the furor inspired by a single concept on the cutting edge of genetic
engineering : cloning.
Principles :
Just as DNA is at the core of studies in genetics, recombinant DNA
(rDNA) that is, DNA that has been genetically altered through a process

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known as gene splicing – is the focal point of genetic engineering. In gene
splicing, a DNA strand is cut in half lengthwise and joined with strand from
another organism or perhaps even another species. Use of gene splicing
makes possible two other highly significant techniques. Gene transfer, or
incorporation of new DNA into an organism’s cells, usually is carried out with
the help of a microorganism that serves as a vector, or carrier. Gene therapy
is the introduction of normal or genetically altered genes to cells, generally to
replace defective genes involved in genetic disorders.

DNA also can be cut into shorter fragments through the use of
restriction enzymes. (An enzyme is a type of protein that speeds up chemical
reactions). The ends of these fragments have an affinity for complementary
ends on other DNA fragments and will seek those out in the target DNA. By
looking at the size of the fragment created by a restriction enzyme,
investigators can determine whether the gene has the proper genetic code.
This technique has been used to analyze genetic structures in fetal cells and
to diagnose certain blood disorders, such as sickle cell anemia.

The ability to isolate and clone genes, coupled with the development of
reliable techniques for introducing genes into plants has opened a new route
to genetic improvement of plants that can circumvent the limitations of
conventional breeding methods.

Once a useful gene is isolated, it can be transferred to many different
crops without a lengthy breeding program.

Such useful traits as resistance to herbicides and disease have been
identified and gene transfer herbicide resistant and disease resistant has
produced plants.

A model genetic engineering of a plant comprised of the following
general steps:-

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1. Selection of a plant gene, whose introduction in other plants would be
of positive agricultural value,
2. Identification and isolation of such genes.
3. Transfer of isolated genes to the plant cell and
4. Regeneration of complete plants from transferred cells or tissues.

Successful attempts at introducing disease, herbicide and pesticide
resistance in plants following the aforesaid steps have already been reported
from several laboratories.

Some of the goals of plant genetic engineers include production of
plants that are
a. Resistant to herbicide, insect, fungal and viral pathogens,
b. Improved protein quality and amino acid composition,
c. Improved photosynthetic efficiency, and
d. Improved post harvest handling.

1.3.2 Plant Tissue Culture
Plant tissue culture broadly refers to the invitro cultivation of plants,
seeds and various parts of the plants (organs, embryos, tissues, single cells
protoplasts). The cultivation process is invariably carried out in a nutrient
culture medium under aseptic conditions.

It has advanced the knowledge of fundamental botany, especially in
the field of agriculture, horticulture, plant breeding, forestry, somatic cell
hybridization, phytopathology and industrial production of plant metabolites
etc.

The term tissue culture is actually a misnomer borrowed from the field
of animal tissue culture. It is a misnomer because plant micropropagation is
concerned with the whole plantlet and not just isolated tissues, though the
explant may be a particular tissue. The terms plantlet culture or
micropropagation, therefore are more accurate. However, whether we call it
cloning, tissue culture, micropropagation or growing in vitro.

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Plant cells have certain advantages over animal cells in culture system
unlike ‘animal cells’; highly mature and differentiated plant cells retain the
ability of totipotency i.e. the ability of change in meristematic state and
differentiate into a whole plant.

Definition : Culturing of living plant material (explant axillary bud,
apical meristem, leaf and root tip) under aseptic condition on an artificial
media is called tissue culture.

1.3.2.1 Some Salient Features of Tissue Culture are :
1. The culture of the cells / tissues is carried out in a sterile medium under
controlled conditions.
2. Clones generated through tissue culture are identical in terms of size,
development stage and rate of metabolic activities.
3. The rate of tissue multiplication is rapid within a small area.
4. The clones are capable of performing the transformative activity c
involves biotransformation to produce primary and secondary
metabolites in the tissue culture medium.

1.3.2.2 Principle of PTC :
The principles of tissue culture are all around us in nature, in the field
and in the greenhouse.

The technique has developed around the concept that a cell is
totipotent that is has the capacity and ability to develop into whole organism.
The principles involve in plant tissue culture are very simple & primarily an
attempt, whereby an explant can be to some extent freed from inter-organ,
inter-tissue and inter-cellular interactions and subjected to direct experimental
control.

Cell culture is the cultivation of cells on a solid gel medium, the latter
commonly known as cell suspension culture. Callus culture is the
multiplication of callus (a mass of disorganized, mostly undifferentiated or
undeveloped cells) usually on a solid medium.

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The apical meristem is the new, undifferentiated tissue of the
microscopic tip of a shoot. It is often virus free even in diseased plants
because these meristematic cells are not yet joined to the plant’s vascular
system and perhaps they grow faster than the viruses. Thus, if the few virus
free cells that make up the microscopic dome of apical meristem are removed
from the plant and placed in a culture, they can grow and produce healthy,
disease free plants.

1.3.2.3 Importance of Plant Tissue Culture :
1. Plant tissue culture enables to develop better strains at a high
multiplication rate.
2. It is clean and rapid way for genetic engineers to grow material for
identifying and manipulating genes.
3. It provides reliable and economic method for maintenance of pathogen
free plantlets in such a state to allow rapid clonal propogation.
4. Plant tissue culture can be initiated with a small explant if limited tissue
is available.
5. Micropropagation can be carried out throughout year independent of
seasons.
6. The variety of technique that collectively comprise plant tissue culture
have permitted investigation at many levels, molecular, cellular,
organismal and have been applied to a range of disciplines
biochemistry, genetics, physiology, anatomy and cell biology.
7. Plant tissue culture is preferable in case of recalcitrant and endangered
species and in following situations :
a. Seeds nongerminable or shows long dormancy period.
b. Species highly heterozygous.
c. Species does not produce seeds.

1.3.2.4 Pathways in Tissue Culture Technique:
Morphogenesis : Organs such as shoots leaves and flowers can
frequently be induced to form adventitiously on cultured plant tissues. The
creation of new form and organization where previously it was lacking is
termed morphogenesis or organogenesis.

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OR
Formation of morphological organs under in vitro condition is known as
morphogenesis or organogenesis.

Hicks (1980) described the two methods of morphogenesis as direct
and indirect organogenesis respectively.

Direct Organogenesis : When relatively large pieces of intact plants are
transferred to nutrient media, new shoots, roots, somatic embryos and even
flower initials are often formed without the prior growth of callus tissue, small
explant show organogenesis only rarely, although some exceptions have
been reported. The part of the original plant from which the explant is taken is
important in influencing its morphogenetic potential.

Indirect Organogenesis: In this pathway media and plant growth regulator
which favour rapid cell proliferation and formation of callus from an explant,
are not usually conducive to the initiation of the morphogenetic meristems
which give rise to roots or shoots. However, organogenesis is medium, but
may be prevented if it is subcultured onto a fresh medium. In other cases
unorganized callus initiated on one medium needs to be transferred to
another of a different position with different combinations of growth regulators
(a regeneration medium) for shoot initiation to occur.

Organs are formed in callus tissues from single cells or several cells
which divide to give rise to groups of small meristematic cells filled with
densely staining cytoplasm and containing large nuclei. These specialized
cells or cell groups are termed ‘meristemoids’ by some research workers
(Hicks, 1980).

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1.3.2.5 Growth Profile of The Plant Culture and Its Measurement

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a. Cell culture b. Callus culture

a. Growth profile for cell culture :
The various stages of the growth exhibited by the plant cell culture are
to a great extent similar to those of the microorganisms. The various stages of
growth are displayed in figure & can be enumerated as.

1. Lag Phase : In this phase, the cell regains the ability of division & the
tissue shows show growth.
2. Exponential Phase : This stage involves rapid cell division the
duration of this stage varies according to the cell and its nutrient regime
. In majority of the cases it is a short one & lasts for only 3-4
generations.
3. Linear Phase : The growth in this phase follows a linear pattern with
respect to time.
4. Progressive deceleration Phase : In this stage the rate of cell division
declines ē the aging of the culture.
5. Stationary Phase : During this phase the rate of production of cells is
equal to the rate of their death.
6. Senescent phase : During this phase the cells are dying.

b. Growth profile for callus culture:

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The growth profile for the callus to a great extent is similar to that of
cells suspension culture. The various stages of growth are :
1. Lag Phase : Following inoculation of an explant, there is a lag time
before the cells undergo cell division. Then a few cells start to divide
and the tissue resumes its growth, albeit a slower one.
2. Exponential Phase : This stage involves vigorous growth owning to
the rapid cell division. During this phase, the tissues consume nutrients
from the medium leading to their depletion.
3. Decline Phase : The depletion of elements from the medium leads to
starvation of some cells. This leads to a decline in the growth of callus
tissues.
4. Stationary Phase : From this stage onwards no growth is evident. For
further growth and development subculture is an imperative.

1.3.2.6 Basic Stages of Plant Tissue Culture : there are five basic stages
of plant tissue culture mentioned below

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A. Stage 0 : Preparative
B. State I : Establishment
C. State II : Multiplication
D. Stage III : Production
E. Stage IV : Hardening

A. Stage 0 : Preperative : Selection of healthy and disease free explants.
B. Stage I : Establishment : Success at this stage firstly requires that
explant should be safely transferred to the culture environment and
secondly that there should be an appropriate reaction (eg. growth of a
shoot tip or formation of callus on a stem piece).
C. Stage II : Multiplication : Stage II is to being about multiplicaton of
organs and structure that are able to give rise to new intact plants.
D. Stage III : Production : At stage III steps are taken to grow individual
plantlets that can carry out photosynthesis and survive without an
artificially supply of carbohydrate.

Stage III is often conveniently divided into :
Stage IIIa : The elongation of buds formed during stage II to uniform
shoots for stage III.
Stage III b : Roofing of stage IIIa shoots invitro or extra vitrum.

E. Stage IV : Hardening : This stage involves the establishment of
plantlets in soil. This is done by transferring the plantlets of stage III
from the laboratory to the environment of greenhouse. For some plant
species, stage III is skipped, and unrooted stage II shoots are planted
in pots or in suitable compost mixture.

1.3.2.7 Types of Plant Tissue Culture :
On the basis of explants, the plant tissue culture technique can be of
following types :

1. Organ culture (a) Meristem and shoot tip culture
(b) Leaf disc culture

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(c) Root tip culture
(d) Bud culture
(e) Storage organ culture
2. Cell culture
3. Callus culture
4. Embryo culture
5. Somatic embryogenesis
6. Anther and pollen culture
7. Ovary culture
8. Protoplast culture

1. Organ culture : The term ‘organ – culture’ includes the isolation
from whole plants of such definite structures as leaf primordial, immature
flowers and traits etc. and their growth in-vitro. For the purposes of plant
propagation, the most important kinds of organ culture are given below:

a. Meristem and shoot tip culture : Culture of the extreme tip of the
shoot (the shoot meristem) is used as a technique to free plant from virus
infections. Very small stem apices (0.2 – 1.0 mm in length), consisting of just
the apical meristem and one or two leaf primordia, must be transferred to
culture. This is usually described as ‘meristem culture’.

Culture of slightly larger stem apices (sometimes 5 or 10 mm in length)
is used as a very successfully method of propagation plants. Most workers
use the term ‘shoot tip culture’ for this technique.

Both types of culture ultimately give rise to small shoots. With
appropriate treatments, the original shoots can either be rooted to produce
small plants or ‘plantlets’ or axillary bud can be induced to grow to form a
cluster of shoots. Tissue cultured plantlets can then be removed from aseptic
conditions, hardened off and grown normally.

b. Leaf disc culture : Leaf disc culture can be established by keeping
leaf tips (apical portion) in suitable MS medium. After certain period of time;
growth of shoot and root takes place.

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c. Root tip culture : Root cultures can be established from root tips
taken from primary or lateral roots of many plants. Suitable explants are small
sections of aseptic roots bearing a primary or lateral root meristem. These
explants may be obtained, for example, from surface sterilized seeds
germinated in aseptic conditions. If the small root meristems continue normal
growth on a suitable medium, they produce a root system consisting only of
primary and lateral roots. No organized shoot buds will be formed. Isolated
root cultures do not feature in current micropropagation techniques although
shoots can be regenerated from root segments of some species. It has
however, been suggested that root cultures could afford are means of
germplasm storage.

d. Bud culture : The plant buds possess quiescent or active meristems
depending on the physiological state of the plant. Two types of bud cultures
are used : – single node culture and axillary bud culture.

Single node culture : This is a natural method for vegetative propagation
of plants both in in-vitro and in-vitro conditions. The bud found in the axil of
leaf is comparable to the stem tip, for its ability in micorpropagation. A bud
along with a piece of stem is isolated and cultured to develop into a plantlet.
Closed buds are used to reduce the chances of infections. In single node
culture, no cytokinine is added.

Axillary bud culture : In this method, a shoot tip along with axillary bud is
isolated. The cultures are carried out with high cytokinine concentration. As a
result of this, apical dominance stop and axillary buds develop.

e. Storage organ culture : Many ornamental and crop species that
naturally produce bulbs can be induced to form small bulbs in culture. They
arise on cultured tissues either at the base of a previously form vegetative
shoot or as a directly initiated storage organ with no extended vegetative
leaves. Buds giving rise to bulbils may arise adventitiously on pieces of leaf
on inflorescence stalks or on ovaries, but particularly on detached pieces of
bulb scale.

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Many small dormant tubers of the crops can be obtained from virus
free shoots and have the great advantage that they can be readily removed
from culture flasks, stored without aseptic precautions and than distributed to
growers fro the production of plants.

2. Cell culture : The culture of isolated individual cells, obtained from an
explant tissue or callus is regarded as cell culture. These cultures are carried
out in dispension medium and are referred to as cell suspension cultures.

3. Callus culture : Callus is a coherent but unorganized and amorphous
tissue, formed by the vigorous division of plant cells. In culture, callus is
initiated by placing small pieces of the whole plant (explants) into a growth
supporting medium under sterile conditions. With the stimulus of endogenous
growth substances or growth regulating chemicals added to the medium.

4. Embryo culture : Seed embryos are often used advantageously as
explants in plant tissue culture. In embryo culture, however, embryos are
individually isolated and ‘germinated’ in-vitro to provide one plant per explant.

Types of embryo culture : (a) Mature embryo culture
(b) Immature embryo culture

(a) Mature embryo culture : Mature embryos are isolated from ripe
seeds & cultured in vitro.
(b) Immature embryo culture : Immature embryos are isolated from unripe
or hybrid seeds which fail to germinate and
cultured in vitro.

5. Somatic embryogenesis : A somatic embryo in as embryo derived
from a somatic cell, other than zygote and obtained usually on culture of the
somatic cells in vitro.

6. Anther and Pollen culture : Haploids plants may be obtained from
pollen grains by placing anthers or isolated pollen grains on a suitable culture
medium, this constitutes anther and pollen culture, respectively.

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Flower buds of the appropriate developmental stage are collected,
surface sterilized and their anthers are excised and placed horizontally on
culture medium. Alternatively, pollen grains may be separated from anthers
and cultured on a suitable medium.

7. Ovary culture : Culture of unfertilized ovaries to obtain haploid plants
from egg cell or other haploid cells of the embryo sac is called ovary culture
and the process is termed as gynogenesis. Ovaries / ovules are generally
cultured in light, but at least in some species dark incubation favours
gynogenesis and minimizes somatic callusing.

8. Protoplast culture : Protoplasts have been isolated from virtually all plant
parts, but leafy mesophyll is the most preferred tissue. The protoplasts
cultured in a suitable medium. The media are supplemented with a
suitable osmoticum and almost always, with an auxin and a cytokinine.
After 7-10 days of culture, protoplasts regenerate cell wall, and the
osmolarity of medium is gradually reduced to that of normal medium. The
macroscopic colonies are transferred into normal tissue culture media. In
1971 an entire plant was first regenerated from a callus originating from an
isolated protoplast. The formation of embryoids directly from cultured
protoplasts has also been observed.

1.3.2.8 Applications of Plant Tissue Cultures :
Plant tissue cultures are associated with a wide range of application
the most important being the production of pharmaceutical, medicinal and
other industrially important compounds. In addition, tissue cultures are useful
for several other purposes listed below :
1. To study the respiration and metabolism of plants.
2. For the evaluation of organ functions in plants.
3. To study the various plant diseases and work out methods for their
elimination.
4. Single cell clones are useful for genetic, morphological and
pathological studies.

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5. Embryonic cell suspensions can be used for large scale clonal
propagation.
6. Somatic embryos from cell suspensions can be stored for long term in
germplasm banks.
7. In the production of variant clones with new characteristics, a
phenomenon referred to as somaclonal variations.
8. Production of haploids (with a single set of chromosomes) for
improving crops.
9. Mutant cells can be selected from cultures and used for crop
improvement.
10. Immature embryos can be cultured in vitro to produce hybrids, a
process referred to as embryo rescue.

1.3.2.9 Terms Used In Plant Tissue Culture :
A selected list of the most commonly used terms in tissue culture are
briefly explained.
Explant or Donor plant : An excised piece of differentiated tissue or organ
is regarded as an explant. The explain may be taken from
any part of the plant body eg. leaf, stem, root.
Callus: The organized and undifferentiated mass of plant cells is
referred to as callus i.e. a mass of parenchymatous cells.
Clone : The entire vegetatively produced descendants from a
single original seedling.
Dedifferentiation : The phenomenon of mature cells reverting to
meristematic state to produce callus is differentiation.
Redifferentiation : The ability of the callus cells to differentiate into a plant
organ or a whole plant is regarded as redifferentiation.
Totipotency : The ability of an individual cell to develop into a whole
plant is referred to as cellular totipotency. The inherent
characteristic features of plant cells namely
dedifferentiation and redifferentiation are responsible for
the phenomenon of totipotency.
1.3.3.0 General Technique of Plant Tissue Culture:
Steps involved for aseptic culture

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Washing of all the glassware and other useful apparatus

Preparation of tissue culture media with growth hormones in desired amount

Sterilization of glassware, media and distilled water and other useful apparatus

Selection of phenotypically superior plant in the morning

Washing of explant with extran and bavistin

Sterilization of explant, media, glassware and other instruments with UV
treatment under laminar air flow cabinet

Washing of explant before and after disinfactant treatment

Inoculation of explant in suitable medium

Maintenance of culture in culture room

Observation at fixed time intervals

Subculture – after establishment and multiplication of explant

Placing of plantlets from the laboratory to the environment of green house

1.3.3.1 Laboratory requirements :
A standard tissue culture laboratory should provide facilities for :

a. Washing and storage of glassware, plastic wares and other lab wares.
b. Preparation, sterilization and storage of nutrient media.
c. Aseptic manipulation of plant material.

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d. Maintenance of cultures under controlled conditions of temperature,
light and if possible, humidity.
e. Observation of cultures.
f. Acclimatization of in-vitro developed plants.

# Apparatus required for Plant Tissue Culture :
I. Culture vessels and other wares
a. Conical flasks
b. Volumetric flasks
c. Measuring cylinders
d. Graduated pipettes, test tubes, bottles , beakers, funnel, plastic
baskets, test tube and bottle caps, test-tube stands and filter paper.
e. Scalpal, blade, forceps, scissors, cotton, muslin cloths, chemicals,
burner, spatula etc.

II. Other large instruments
a. Double distilled water unit.
b. Electric hot air oven – for labwares drying.
c. Electronic balance – for weighing chemicals.
d. pH meter – for pH adjustment of media and other solutions.
e. Microwave – for melting agar
g. Shaker – for maintenance of suspension culture.
h. Autolcave (vertical and horizontal) - For steam sterilization of
media and apparatus.
i. Laminar air flow cabinet - For constant flow of purified air for
aseptic manipulation (Pore size – 45 um).

j. Air conditioner - For maintenance of temperature of
culture room.
1.3.3.2 Sterilization Techniques involved in Plant Tissue Culture are : -
All the materials, e.g., vessels, instruments, medium, plant material,
etc., used in culture work most be freed from microbes. This is achieved by
one of the following approaches (i) dry heat, (ii) flame sterilization, (iii)
autoclaving, (iv) filter sterilization, (v) wiping with 70% ethanol, and (vi)
surface sterilization.

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• Dry Heat : Glassware and Teflon plastic ware (empty vessels), and
instruments may be sterilized by dry heat in an oven at 160-180oC for 3 hr.
But most workers prefer to autoclave glassware and plastic ware etc. and
flame sterilize instruments like forceps, etc. More recently, glass bead
sterilizers (300oC) are being employed for the sterilization of forceps, scalpels,
etc. these devices use dry heat.

• Flame Sterilization: Instruments like forceps, scalpals, needles, etc. are
ordinarily flame sterilized by dipping them in 95% alcohol followed by flaming.
These instruments are repeatedly sterilized during the operation to avoid
contamination. It is customary to flame the mouths of culture vessels prior to
inoculation / subculture.

• Autoclaving : Culture vessels, etc. (both empty and containing media) are
genrally sterilized by heating in an autoclave or a pressure cooker to 121 oC at
15 p.s.i. (pounds per square inch, 1.06 kg/cm2) for 30 to 40 minutes.

• Filter Sterilization : Some growth regulators, e.g., GA3, zeatin, ABA
(abscisic acid), urea, certain vitamins, and enzymes are heat labile. Such
compounds are filter sterilized by passing their solution through a membrane
filter of 0.45 u or lower pore size. The membrane filter is held in a suitable
assembly, the assembly together with the filter is sterilized by autoclaving
before use. Filter a suitable assembly; the assembly together with the filter is
sterilized by autoclaving before use. Filter sterilized heat labile compounds
are added to autoclaved and cooled media, in case of agar medium, they are
added when the medium has cooled to about 40oC and is still liquefied.

• Wiping with 70% ethanol :The surfaces that can not be sterilized by other
techniques, e.g., platform of the laminar flow cabinet, hands of the operator,
etc. are sterilized by wiping them thoroughly with 70% ethyl alcohol and the
alcohol is allowed to dry.

• Surface sterilization : All materials to be used for culture are treated with
an appropriate sterilizing agent to inactivate the microbes present on their

22

surface, this is called surface sterilization. Surface sterilization protocol will
depend mainly on the source and the type of tissue of the explant, which will
determine the contamination load and tolerance to the sterilizing agent. An
explant is the excised piece of tissue or organ used for culture.

The sterilizing agents used for surface disinfection are calcium
hypochlorite (9-10%), H2O2 (10-12%) and antibiotics (4-50 mg/l). Of these,
calcium or sodium hypochlorite (very good results) and HgCl2 (satisfactory
results) are the most commonly used. The duration of treatment varies from
15-30 min. Since these agents are also toxic to plant tissues, the duration and
the concentration used should be such as to cause minimum tissue death,
and the rinsing after treatment should remove them as completely as
possible.

1.3.3.3 Plant Tissue Culture Media :
Culture media are largely responsible for the in-vitro growth and
morphogenesis of plant tissues. The success of the plant tissue culture
depends on the choice of the nutrient medium. In fact, the cells can be grown
in culture media.

Basically, the plant tissue culture media should contain the same
nutrients as required by the whole plant. It may be noted that plants in nature
can synthesize their own food material. However, plants growing in vitro are
mainly heterotrophic i.e. they cannot synthesize their own food.

• Composition of media :
The composition of the culture media is primarily dependent on two
parameters.
1. The particular species of the plant.
2. The type of material used for culture i.e. cells, tissues, organs,
protoplasts.

Thus, the composition of a medium is formulated considering the
specific requirements of a given culture system. The media used may be solid

23

(solid medium) or liquid (liquid medium) in nature. The selection of solid or
liquid medium is dependent on the better response of a culture.

¤ Major types of media :-
The composition of the most commonly used tissue culture media is
briefly described below.

• White’s medium : This is one of the earliest plant tissue culture media
developed for root culture.
• MS medium : Murashige and Skoog (MS) originally formulated a
medium to induce organogenesis, and regeneration of plants in cultured
tissues. These days, MS medium is widely used for many types of culture
systems.

• B5 medium : Developed by Gamborg, B5 medium was originally
designed for cell suspension and callus cultures. At present with certain
modifications, this medium is used for protoplast culture.

• N6 medium : Chu formulated this medium and it is used for cereal
anther culture, besides other tissue cultures.

• Nitsch’s medium : This medium was developed by Nitsch and Nitsch
and frequently used for anther cultures.

Among the media referred above, MS medium is most frequently used
in plant tissue culture work due to its success with several plant species and
culture systems.

♣ Synthetic and natural media : When a medium is composed of
chemically defined components, it is referred to as a synthetic medium. On
the other hand, if a medium contains chemically undefined compounds (e.g.,
vegetable extract, fruit juice, plant, extract), it is regarded as a natural
medium.

Table :1.1 Composition of commonly used plant tissue culture media

24

Components Amount (mg l-1)
White’s Murashige and Gamborg (B5) Chu (N6) Nitsch’s
skoog (MS)
Macronutrients
MgSO4.7H2O 750 370 250 185 185
KH2PO4 - 170 - 400 68
NaH2PO4.H2O 19 - 150 - -
KNO3 80 1900 2500 2830 950
NH4NO3 - 1650 - - 720
CaCl2.2H2O - 440 150 166 -
(NH)42.SO4 - - 134 463 -
Micronutrients
H3BO3 1.5 6.2 3 1.6 -
MnSO4.4H2O 5 22.3 - 4.4 25
MnSO4.H2O - - 10 3.3 -
ZnSO4.7H2O 3 8.6 2 1.5 10
Na2MoO4.2H2O - 0.25 0.25 - 0.25
CuSO4.5H2O 0.01 0.025 0.025 - 0.025
CoCl2.6H2O - 0.025 0.025 - 0.025
Kl 0.75 0.83 0.75 0.8 -
FeSO4.7H2O - 27.8 - 27.8 27.8
Na2EDTA.2H2O - 37.3 - 37.3 37.3
Sucrose (g) 20 30 20 50 20
Organic supplements Vitamins
Thiamine HCl 0.01 0.5 10 1 0.5
Pyridoxine (HCl) 0.01 0.05 1 0.5 0.5
Nicotinic acid 0.05 0.5 1 0.5 5
Myoinositol - 100 100 - 100
Others
Glycine 3 2 - - 2
Folic acid - - - - 0.5
Biotin - - - - 0.05
Ph 5.8 5.8 5.5 5.8 5.8

Synthetic media have almost replaced the natural media for tissue
culture.

Expression of concentration in media : The concentrations of inorganic
and organic constituents in culture media are usually expressed as mass
values (mg/l or ppm or mg l-1). However, as per the recommendations of the
international Association of Plant Physiology, the concentrations of
macronutrients should be expressed as mmol/l-1 and micronutrients as
µmol/l.

¤ Constituents of media :

25

Many elements are needed for nutrition and their physiological
functions. Thus, these elements have to be supplied in the culture medium to
support adequate growth of cultures in vitro.

The culture media usually contain the following constituents :
1. Inorganic nutrients
2. Carbon and energy sources
3. Organic supplements
4. Growth regulators
5. Solidifying agents
6. pH of medium

¤ Inorganic nutrients :
The inorganic nutrients consist of macronutrients (concentration > 0.5
mmol/l-) and micronutrients (concentratioin <0.5 mmol/l-). A wide range of
mineral salts (elements) supply the macro and micronutrients. The inorganic
salts in water undergo dissociation and ionization. Consequently, one type of
ion may be contributed by more than one salt for instance, in MS medium, K+
ions are contributed by KNO3 and KH2PO4 while NO3 – ions come from KNO3
and NH4NO3.

¤ Macronutrient elements: The six elements namely nitrogen,
phosphorus, potassium, calcium, magnesium and sulfur are the essential
macronutrients for tissue culture. The ideal concentration of nitrogen, and
potassium is around 25 mmol l-1 while for calcium, phosphorus, sulfur and
magnesium, it is in the range of 1-3 mmol l-1 for the supply of nitrogen in the
medium, nitrates and ammonium salts are together used.

¤ Micronutrients : Although their requirement is in minute quantities,
micronutrients are essential for plant cells and tissues. These include iron,
manganese, zinc, boron, copper and molybdenum. Among the
microelements, iron requirement is very critical. Chelated forms of iron and
copper are commonly used in culture media.

¤ Carbon and energy sources :

26

Plant cells and tissues in the culture medium are heterotrophic and
therefore, are dependent on the external carbon for energy. Among the
energy sources, sucrose is the most preferred. During the course of
sterilization (by autoclaving) of the medium, sucrose gets hydrolyzed to
glucose and fructose. The plant cells in culture first utilize glucose and then
fructose. In fact, glucose or fructose can be directly used in the culture media.
It may be noted that for energy supply, glucose is as efficient as sucrose while
fructose is less efficient.

Table : 1.2 A selected list of elements and their functions in plants

Element Function(s)
Nitrogen Essential component of proteins, nucleic acids and some
coenzymes. (Required in most abundant quantity)

Calcium Synthesis of cell wall, membrane function, cell signaling
Magnesium Component of chlorophyll, cofactor for some enzymes.
Potassium Major inorganic cation, regulates osmotic potential.
Phosphorus Component of nucleic acids and various intermediates in
respiration and photosynthesis, involved in energy
transfer.

Sulfur Component of certain amino acids (methionine, cysteine
and cystine, and some cofactors).

Manganese Cofactor for certain enzymes.
Iron Component of cytochromes, involved in electron transfer.
Chlorine Participates in photosynthesis.
Copper Involved in electron transfer reactions, cofactor for some
enzymes.

Cobalt Component of vitamin B12.
Molybdenum Component of certain enzymes (e.g., nitrate reductase),
cofactor for some enzymes.

Zinc Required for chlorophyll biosynthesis, cofactor for certain
enzymes.
It is a common observation that cultures grow better on a medium with
autoclaved sucrose than on a medium with filter-sterilized sucrose. This
clearly indicates that the hydrolyzed products of sucrose (particularly glucose)
are efficient sources of energy. Direct use of fructose in the medium subjected
to autoclaving, is found to be detrimental to the growth of plant cells.

27

Besides sucrose and glucose, other carbohydrates such as lactose,
maltose, galactose, raffinose, trehalose and cellobiose have been used in
culture media but with a very limited success.

¤ Organic Supplements :
The organic supplements include vitamins, amino acids, organic acids,
organic extracts, activated charcoal and antibiotics.

• Vitamins : Plant cells and tissues in culture (like the natural plants)
are capable of synthesizing vitamins but in suboptimal quantities, inadequate
to support growth. Therefore, the medium should be supplemented with
vitamins to achieve good growth of cells. The vitamins added to the media
include thiamine, riboflavin, niacin, pyridoxine, folic acid, pantothenic acid,
biotin, ascorbic acid, myoinositol, para-amino benzoic acid and vitamin E.

• Amino acids : Although the cultured plant cells can synthesize amino
acids to a certain extent, media supplemented with amino acids stimulate cell
growth and help in establishment of cells lines. Further, organic nitrogen (in
the form of amino acids such as L-glutamine, L-asparagine, L-arginine, L-
cysteine) is more readily taken up than inorganic nitrogen by the plant cells.

• Organic acids : Addition of Krebs cycle intermediates such as citrate,
malate, succinate or fumarate allow the growth of plant cells. Pyruvate also
enhances the growth of cultured cells.

• Organic extracts : It has been a practice to supplement culture media
with organic extracts such as yeast, casein hydrolysate, coconut milk, orange
juice, tomato juice and potato extract.

It is however, preferable to avoid the use of natural extracts due to high
variations in the quality and quantity of growth promoting factors in them. In
recent years, natural extracts have been replaced by specific organic
compounds e.g., replacement of yeast extract by L-asparagine, replacement
of fruit extracts by L-glutamine.

28

• Activated charcoal : Supplementation of the medium with activated
charcoal stimulates the growth and differentiation of certain plant cells (carrot,
tomato, orchids). Some toxic inhibitory compounds (e.g. phenols) produced by
cultured plants are removed (by adsorption) by activated charcoal, and this
facilitates efficient cell growth in cultures.

Addition of activated charcoal to certain cultures (tobacco, soybean) is
found to be inhibitory, probably due to adsorption of growth stimulants such as
phytohormones.

¤ Antibiotics : It is sometimes necessary to add antibiotics to the
medium to prevent the growth of microorganisms. For this purpose, low
concentration of streptomycin or kanamycin are used. As far as possible,
addition of antibiotics to the medium is avoided as they have an inhibitory
influence on the cell growth.

1.3.3.4 Plant Growth Regulators :
The naturally occurring compounds within plant tissue (endogenously)
and have a regulatory rather than a nutritional role in growth and development
are called as growth hormones. These compounds are generally active at
very low concentrations. Synthetic chemicals with similar physiological
activities to plant growth hormones or compounds having an ability to modify
plant growth by some means are termed as plant growth regulators.

Auxins : Auxins induce cell division, cell elongation, and formation of
callus in cultures. At a low concentration, auxins promote root formation while
at a high concentration callus formation occurs.

CH2-COOH

N

29

H
An auxin
(Indole acetic acid)

Table: 1.3 A selected list of plant growth regulators used in culture
media
Growth regulator (abbreviation/name) Chemical name
Auxins
IAA Indole 3-acetic acid
IBA Indole 3-butyric acid
NAA 1-Naphttyl acetic acid
2, 4-D 2, 4-Dichlorophenoxy acetic acid
2, 4, 5-T 2, 4, 5-Trichlorophenoxy acetic acid
4-CPA 4-Chlorophenoxy acetic acid
NOA 2-Naphttyloxy acetic acid
MCPA 2-Methyl 4-chloropheoxy acetic acid
Dicamba 2-Methoxy 3, 6-dichlorobenzoic
Picloram 4-Amino 2, 5, 6-trichloropicolinic acid

Cytokinins : Chemically, cytokinins are derivatives of a purine namely
adenine. These adenine derivatives are involved in cell division, shoot
differentiation and somatic embryo formation. Cytokinins promote RNA
synthesis and thus stimulate protein and enzyme activities in tissues.
HN-CH3
N
N

N N
A cytokinin
H (N6-Methylaminopurine)

Table: 1.4 A selected list of plant growth regulators used in culture
media :

Growth regulator (abbreviation/name) Chemical name
Cytokinins
BAP 6-Benzyl aminopurine
BA Benzyl ademine
2 ip (IPA) N6-(2-isopentyl) adenine
DPU Diphenyl urea
Kinetin 6-Furfuryl aminopurine
Zeatin 4-Hydroxy 3-methyltrans
2-butenyl aminopurine
Thidiazuron 1-Phenyl 3-(1, 2, 3-thiadiazol-5 yl)

30

urea
Among the cytokinins, kinetin and benzyl aminopurine are frequently
used in culture media.

Ratio of auxins and cytokinins : The relative concentrations of the
growth factors namely auxins and cytokinins are crucial for the
morphogenesis of culture systems. When the ratio of auxins to cytokinins to
high, embryogenesis, callus initiation and root initiation occur. On the other
hand, for axillary and shoot proliferation, the ratio of auxins to cytokinins is
low. For all practical purposes, it is considered that the formation and
maintenance of callus cultures require both auxin and cytokinin, while auxin in
needed for root culture and cytokinin for shoot culture. The actual
concentration of the growth regulators in culture media are variable depending
on the type of tissue explant and the plant species.

Gibberellins : About 20 different gibberellins have been identified as growth
regulators. Of these, gibberellin A3 (GA3) is the most commonly used for tissue
culture. GA3 promotes growth of cultured cells, enhances callus growth and
induces dwarf plantlets to elongate.

Gibberellins are capable of promoting or inhibiting tissue cultures,
depending on the plant species. They usually inhibit adventious root and
shoot formation.

OH
CH2

O
C=O

31

HO
CH3 COOH A gibberellin

Abscisic acid (ABA) : The callus growth of cultures may be stimulated or
inhibited by ABA. This largely depends on the nature of the plant species.
Abscisic acid is an important growth regulation for induction of
embryogenesis.

1.3.3.5 Solidifying agents :
For the preparation of semisolid or solid tissue culture media,
solidifying or gelling agents are required. In fact, solidifying agents extend
support to tissues growing in the static conditions.

Agar : Agar, a polysaccharide obtained from seaweeds, is most
commonly used as a gelling agent for the following reasons

1. It does not react with media constituents.
2. It is not digested by plant exzymes and is stable at culture temperature.

Agar at a concentration of 0.5 to 1% in the medium can form a gel.

32

Gelatin : It is used at a high concentration (10%) with a limited success. This
is mainly because gelatin melts at low temperature (25 oC) and consequently
the gelling property is lost.

Other gelling agents : Biogel (polyacrylamide pellets), phytagel, gelrite and
purified agarose are other solidifying agents, although less frequently used. It
is in fact advantageious to use synthetic gelling compounds, since they can
form gels at a relatively low concentration (1.0 to 2.5 g l-1).

1.3.3.6 pH of medium :
The optimal pH for most tissue cultures in the range of 5.0 – 6.0. The
pH generally falls by 0.3 – 0.5 units after autoclaving. Before sterilization, pH
can be adjusted to the required optimal level while preparing the medium. It is
usually not necessary to use buffers for the pH maintenance of culture media.

At a pH higher than 7.0 and lower than 4.5, the plant cells stop growing
in cultures. If the pH falls during the plant tissue culture, then fresh medium
should be prepared. In general, pH above 6.0 gives the medium hard
appearance, while pH below 5.0 does not allow gelling of the medium.

1.4 CHEMOTAXONOMY
The use of biochemistry in taxonomic studies is called
chemotaxonomy. Living organisms produce many types of natural products in
varying amounts, and quite often the biosynthetic pathways responsible for
these compounds also differ from one taxonomic group to another. The
distribution of these compounds and their biosynthetic pathways correspond
will with existing taxonomic arrangements based on more traditional criteria
such as morphology. In some cases, chemical data have contradicted existing
hypotheses, which necessitates a reexamination of the problem or, more
positively, chemical data have provided decisive information in situations
where other forms of data are insufficiently discriminatory.

33

Modern chemotaxonomists often divide natural products into two
classes (1) micromolecules, that is, those compounds with a molecular weight
of 1000 or less, such as alkaloids, terpenoids, amino acids, fatty acids,
flavonoid pigments and other phenolic compounds, mustard oils, and simple
carbohydrates, and (2) macromolecules, that is, those compounds (often
polymers) with a molecular weight over 1000, including complex
polysaccharides, proteins, and the basis of life itself, deoxyribonucleic acid
(DNA).

A crude extract of a plant can be separated into its individual
components, especially in the case of micromolecules, by using one or more
techniques of chromatography, including paper, thin-layer, gas, or high-
pressure liquid chromatography. The resulting chromatogram provides a
visual display or “fingerprint” characteristics of a plant species for the
particular class of compounds under study.

The individual, separated spots can be further purified and then
subjected to one or more types of spectroscopy, such as ultraviolet, infrared,
or nuclear magnetic resonance or mass spectroscopy (or both), which may
provide information about the structure of the compound. Thus, for taxonomic
purposes both visual patterns and structural knowledge of the compounds can
be compared from species to species.

1.5 CHROMATOGRAPHY
The term chromatography (chromaG = a colour, grapheinG = to write)
was originally applied by a Russian chemist, Mechael Semonovich Twsett
(LT. 1872-1919), in 1906 to a procedure where a mixture of different colored
pigments (chlorophylls and xanthophylls) is separated from each other. He
used a column of CaCO3 to separate the various components of petroleum
either chlorophyll extract into green and yellow zones of pigments. He termed
such a preparation as chromatogram and the procedure as chromatography.

Chromatography may be defined as the technique of separation of
substances according to their partition coefficients below (i.e., their relative
solubilities in) two immiscible phases. In this method, the separation of the

34

components of a mixture is a function of their different affinities for a fixed or
stationary phase (such as a solid or a liquid) and their differential solubility in a
moving or mobile phase (such as a liquid or a gas, Separation starts to occur
when one component is held more firmly by the stationary phase than the
other which tends to move on faster in the mobile phase.

PRINCIPLE - The various chromatographic techniques fall principally under 2
categories: adsorption chromatography and partition chromatography. In
adsorption chromatography, the stationary phase is a finely divided adsorbent
such as alumina or silica gel and the mobile phase can be a gas or more
commonly a liquid. Partition chromatography involves partition between two
liquids rather than adsorption by a solid from a liquid. Here the stationary
phase a liquid, which is held on an inert porous supporting liquid.

Types of Chromatography : Some major chromatographic techniques
are discussed below :
1. Paper Chromatography
2. Thin layer Chromatography
3. Column Chromatography : a. Affinity Chromatography
b. Ion - exchange Chromatography
c. Size exclusion Chromatography
4. Gas Chromatography
5. Liquid Chromatography
1. Paper Chromatography :
Paper chromatography is an analytical chemistry technique for
separating and identifying mixtures that are or can be colored, especially
pigments.Two Russian workers, Izmailov and Schraiber (1938) discovered
this important techniques. This method is especially useful for the detection
and separation of amino acids. Here the filter paper strips are used to support
a stationary water phase while a mobile organic phase moves down the
suspended paper strip in a cylinder. Separation is based on a liquid partition
of the components. Thus, this is essentially a form of partition
chromatography between two liquid phases through adsorption to the paper
may also take place.

35

In this method, a drop of solution containing a mixture of amino acids
(or other compounds) to be separated is applied at a marked point, about 3
cm from one end of a strip of filter paper. Whatman No. 1 paper is most
frequently used for this purpose.

The filter paper is then dried and ‘equilibrated’ by putting it into an air-
tight cylindrical jar which contains an aqueous solution of a solvent. The most
widely applicable solvent mixture is n-butanol acetic acid: water (4:1:5), which
is abbreviated as BAW. The end of the filter paper nearest the applied drop is
inserted into the solvent mixture at the bottom of the jar, taking care that the
marked point of application remains will above the level of the solvent in the
jar. The paper is suspended in such a manner so that it hangs freely without
touching the sides of the container. Thus, the solvent will ascend into the
paper and different components of a mixture are separated.

2. Thin Layer Chromatography :
Thin layer chromatography is adsorption chromatography performed on
open layers of adsorbent materials supported in glass plates. This technique
combines many of the advantages of paper such a preparation as
chromatogram and the procedure as chromatography.

Thin layer Chromatography chromatography with those of column
chromatography. Here a thin uniform film of adsorbent (like silica gel or
alumina powder) containing a binding medium (like calcium sulfate) is spread
onto a glass plate. The thin layer is allowed to dry at room temperature and is
then activated by bearing in an oven between 100oC to 250oC. The activated
plate is then placed flat and samples spotted with micropipettes carefully on
the surface of the thin layer. After the solvent has evaporated, the plates are
placed vertically in glass tank containing a suitable rising through the thin
layer. The glass plate is a variety of reagents.

3. Column Chromatography :
Column chromatography is a separation technique in which the
stationary bed is within a tube. The particles of the solid stationary phase or

36

the support coated with a liquid stationary phase may fill the whole inside
volume of the tube (packed column) or e concentrated on or along the inside
tube wall leaving an open, unrestricted path for the mobile phase in the middle
part of the tube (open tubular column). Differences in rates of movement
through the medium are calculated to different retention times of the sample.

¤ Types of column chromatography:
a. Affinity chromatography
b. Ion exchange chromatography
c. Size exclusion chromatography

a. Affinity chromatography is based on selective non-covalent
interaction between an analyte and specific molecules. It is very specific, but
not very robust. It is often used in biochemistry in the purification of proteins
bound to tags. These fusion proteins are labeled with compounds such as
His-tags, biotin or antigens, which bind to the stationary phase specifically.
After purification, some of these tags are usually removed and the pure
protein is obtained.

b. Ion exchange chromatography uses ion exchange mechanism to
separate analytes. It is usually performed in columns but can also be useful in
planar mode. Ion exchange chromatography uses a charged stationary phase
to separate charged compounds including amino acids, peptides, and
proteins. In conventional groups which interact with oppositely charged
groups of the compound to be retained. Ion exchange chromatography is
commonly used to purify proteins.

c. Size exlusion chromatography (SEC) is also known as gel
permeation chromatography (GPc) or gel filtration chromatography and
separates molecules according to their size (or more accurately according to
their hydrodynamic diameter or hydrodynamic volume). Smaller molecules are
able to enter the pores of the media and, therefore, take longer to elute,
whereas larger molecules are excluded from the pores and elute faster. It is
generally a low-resolution chromatography technique and thus it is often
reserved for the final, “polishing” step of purification. It is also useful for

37

determining the tertiary structure and quaternary structure of purified proteins,
especially since it can be carried out under native solution conditions.

4. Gas Chromatography (OR GC) :
Gas chromatography is a dynamic method of separation and detection
of volatile organic compounds and several inorganic permanent gases in a
mixture. GC as an instrumental technique was first introduced in the 1950s
and has evolved into a primary tool used in many laboratories. Significant
technological advance in the area of electronics, computerization and column
technology have yielded lower and lower detectable limits and more accurate
identification of substances through improved resolution and qualitative
analysis techniques. GC is very versatile technique that can be used in most
industry area, environmental, pharmaceutical, petroleum, chemical
manufacturing, clinical, forensic, food science and many more. Several
leading manufactures of gas chromatographs provide fairly extensive
resources for training, method development and operational support services.

5. Liquid Chromatography :
Liquid chromatography (LC) is a separation technique in which the
mobile phase is a liquid. Liquid chromatography can be carried out either in a
column or a plane. Present day liquid chromatography that generally utilizes
very small packing particles and a relatively high pressure is referred to as
high performance liquid chromatography (HPLC).

In the HPLC technique, the sample is forced through a column that is
packed with irregularly or spherically shaped particles of a porous monolithic
layer (stationary phase) by a liquid (mobile phase) at high pressure. HPLC is
historically divided into two different sub-classes based on the polarity of the
mobile and stationary phases. Technique mobile phase, silica as the
stationary phase) is called normal phase liquid chromatography (NPLC) and
the opposite (e.g. water-methanol mixture as the mobile phase and C18 =
octadecylsilyl as the stationary phase) is called reversed phase liquid
chromatography (RPLC). Ironically the “normal phase” has fewer applications
and RPLC is therefore used considerably more.

38

HIGH PERFORMANCE LIQUID CHROMATOGRAPHY
HPLC was developed in the late 1960s & 1970s. Today it is a widely
accepted separation technique for both sample analysis and purification in a
variety of areas including the pharmaceutical, biotechnological,
environmental, polymer and food industries. HPLC is enjoying a steady
increase in no. of both instrumental sales and publications that describe new
and innovative applications. Some recent growth areas include miniaturization
of HPLC analysis of nucleic acids intact proteins and protein digests, analysis
of CBH and chiral analysis.

Basic Principle :
The basic principle of reverse phase HPLC separation is the
hydrophobic interaction between the own polar hydrocarbonaceous matrix of
the column material and the hydrophobic groups of the analyte. Two different
mechanisms, adsorption and partition are responsible for retention of solutes
in the stationary phase.

In the adsorption model, a solute is adsorbed on the hydrophobic
surface of the solid support the remains adsorbed until the attractive forces
are weakened by a sufficiently high concentration of the organic modifier in
the mobile phase. At this critical concentration, the adsorbed solute molecules
are replaced by the molecules of the organic modifier and eluted from the
column e little further interaction e the stationary phase. The process can be
regarded as endothermic and entropically driven.
In the partition model the solid surface is considered a hydrophobic
bulk phase and equilibrium is achieved when a solute partitions between this
solid phase and the mobile phase. With the downward flow of the mobile
phase, the solute moves in and out of the stationary phase. Solutes e higher
equilibrium constants are retained longer in the column. The equilibrium can
be shifted toward the liquid phase by increasing the concentration of the
organic modifier.

Working:
Chromatography is a technique in which solutes are resolved by
differential rates of elution as they pass through a chromatographic column.

39

Their separation is governed by their distribution bet the mobile and the
stationary phases. The successful use of liquid chromatography for a given
problem requires the right combination of a variety of operating conditions
such as the type of column packing and mobile phase, column length and
diameter, mobile phase flow rate, column temperature sand sample size.

HPLC instrumentation is made up of eight basic components :-
1. Mobile phase reservoir
2. Solvent delivery system
3. Sample introduction device
4. Column
5. Detector
6. Waste reservoir
7. Connective tubing
8. Computer

injection waste

A C D E

B F G H

Figure: Basic configuration of an HPLC instrument, where A- solvent
reservoir, B- pumping system , C- fixed volume sample injector,
D- guard column , E-analytical column , F-detector , G- data
system , H- printer.
Required Sample Properties:-
State : Sample must be in liquid form for injection into the instrument,
solid samples must be dissolved in a solvent compatible with the
mobile and stationary phases.
Amount: 1-100 µl injected (generally 5-10 µl); mass amounts injected
vary depending on the sensitivity and dynamic range of the
detector for the analyte.
Preparation: Limited or extensive sample prep may be required as defined by
the relative complexity of the sample. Sample preparation may
include any of the following steps dilution, preconcentration,
filteration, extraction, ultrafilteration or derivatization.

40

Analysis time : Analysis time is in a range from 5 min to 2 hr. (generally
10-25 min). Sample preparation differs from sample to sample.
Sample preparation may be extensive and require more time
than the analysis.

Applications of HPLC :-
1. Separation of a wide variety of compounds, organic, inorganic and
biological compounds, organic, inorganic and biological compounds,
polymers, chiral compounds, thermally labile compounds and small
ions to macromolecules.
2. Analysis of impurities.
3. Analysis of both volatile and nonvolatile compounds.
4. Determination of neutral, ionic or zwitterionic molecules.
5. Isolation and purification of compounds.
6. Separation of closely related compounds.
7. Ultratrance to preparative and process.
8. Nondestructive method.
9. Qualitative and quantitative method.

Limitations :
1. Compound identification may be limited unless high PLC is interfaced e
mass spectrometry.
2. Resolution can be difficult to attain e complex samples.
3. Only one sample can be analyzed at a time.
4. Requires training in order to optimize separations.
5. Time analysis can be long (compared e capillary electrophoresis).
6. Sample preparation of often required.

1.6 BAMBOOS IN WORLD :

Bamboo is monocotyledonous woody grass belonging to the sub-family
Bambusoideae of the family Poaceae.Bamboos are the fastest growing plant
in the world (60 cm/day). Worldwide there are m They occur across East Asia,
from 50°N latitude in Sakhalin through to Northern Australia, and west to India
and the Himalayas. They also occur in sub-Saharan Africa, and in the

41

Americas from the Mid-Atlantic United States, south to Argentina and Chile,
reaching their southernmost point anywhere, at 47°S latitude. Major areas
with no native bamboos include Europe and Antarctica.India is very rich in
bamboo diversity. More than 1,250 species under 75 genera of bamboo,
which are unevenly distributed in the various parts of the humid tropical, sub-
tropical and temperate regions of the earth (Subramaniam, 1998).

1.6.1 BAMBOOS IN INDIA :

India is the seventh largest country in the world covering an area of
328.78 million ha. It lies entirely in the northern hemisphere and extends
between 8oN to 37oN latitudes and 68oE to 97oE longitudes. The forest cover
is over an area of 63.3 million ha which is 19.27 per cent of the total
geographical area. Overall six percent of world species are found in India. It is
one of the twelve mega-biodiversity countries. (Status of bamboo and rattan in
India Jk rawat and dc khanduri, 1. forest research institute India and 2.
ministry of environment and forest India).

Table 1.5 Distribution of main bamboo species in India (ICFRE 1998) :

Species States / UTs
Bambusa arundinacea Arunachal Pradesh, Karnataka, Orissa,
Maharashtra, Himachal Pradesh,
Andhra Pradesh and Gujarat
Bambusa balcooa Arunachal Pradesh, Mizoram
Bambusa pallida Arunachal Pradesh, Nagaland,
Mizoram, Tripura
Bambusa tulda Arunachal Pradesh, Assam, Mizoram,
Nagaland, Tripura
Bambusa polymorpha Tripura
Dendrocalamus hamiltonii Arunachal Pradesh, Assam, Mizoram,
Nagaland

42

Dendrocalamus longispathus Mizoram
Dendrocalamus strictus Andhra Pradesh, Assam, Gujarat,
Maharashtra, Himachal Pradesh,
Madhya Pradesh, Manipur, Orissa,
Karnataka, Uttar Pradesh, Rajasthan
Melocanna bambusoides Assam, Mizoram, Nagaland, Tripura,
Manipur, Meghalaya
Neebenzia balcooa Nagaland
Oxytenanthera nigrociliata Tripura, Assam
Oxytenanthera parviflora Assam
Pseudostachhys polymorphium Arunachal Pradesh

There are 124 indigenous and exotic species, under 23 genera, found
naturally and/or under cultivation (Naithani, 1993). This natural resource plays
a major role in the livelihood of rural people and in rural industry. This green
gold is sufficiently cheap and plentiful to meet the vast needs of human that is
why sometimes it is known as "poor man's timber.

India is one of the leading countries in the world in bamboo production.
Because of the versatile uses of bamboos there is great demand for this
resource throughout India. Annual production of bamboos in India is about
13.47 m tons a year is far short of the 26.69 mt. demand a year. Till recently
the area under bamboo is confined to the 12.8% of forest cover; two third of
the growing stock (80.42mt) located in the north east (Latest press information
release Govt. of India).

An estimated 8.96 million ha forest area of the country contains
bamboo (Rai and Chauhan, 1998). It is found to grow practically all over the
country, particularly in the tropical, sub-tropical and temperate regions where
the annual rainfall ranges between 1,200 mm to 4,000 mm and the
temperature varies between 16oC and 38oC.

1.6.2 BAMBOOS IN MADHYA PRADESH :

Bamboo is also found at places in M.P. forests. Normally
Dendrocalamus strictus is the main bamboo species found. It is distributed
over Balaghat, Seoni, Chhindwara , Betul ,Mandala ,Shahdol and Sehore

43

(near Budni railway station).In M.P. alone 40000 basods depend entirely for
their livelihood on bamboo.(Singhal and Gangopadhyaya 1999).

Table 1.6 Various uses of bamboo (Tiwari 1992) :
Use of bamboo as plant Use of bamboo as material
Ornamental horticulture Local industries
Ecology Artisanat
Furniture
Stabilization of the soil A variety of utensils
Stabilizing Houses
Uses on marginal land
Hedges and screens Wood and paper industries
Minimal land use
Sand Boards
Medium Density Fiberboard
Agro-forestry Laminated lumber
Paper and rayon
Natural stands Parquet
Plantations
Mixed agroforestry systems Nutritional industries
Young shoots for human consumption
Fodder
Chemical Industries
Biochemical products
Pharmaceuitcal industry
Energy

44

Charcoal
Pyrolysis
Gasification

ABOUT SPECIES

SPECIES A
Classification :
Kingdom - Plantae
Sub-kingdom - Tracheobionata
Division - Magnoliophyta
Class - Liliopsida
Sub-class - Commelinideae
Order - Cyperales
Family - Gramineae
Genus - Bambusa
Species - tulda

Vernacular name :
Assam - Wamunna, Wagi, Nal-bans
Bengal - Tulda, Jowa
Duars (west) - Kiranti, Matela, Garo-Wati
Kamrup - Bijuli, Jati, Jao, Ghora
Tripura - Mirtinga, Hindi – Peka
Others - Bengal bamboo, Spineless bamboo,
Calcutta bamboo etc.
Distribution :

45

In India, it is found in the states of Assam, Bihar, Meghalaya, Mizoram,
Nagaland and Tripura. Cultivated in Arunachal Pradesh, Karataka and
Bengal. The species is extensively grown in low hills of central Assam.

It is also occurs in Bangladesh, Myammar and Thailand. It is one of the
major species of Bangladesh. This species life-span is 25-40 years.

Climate & Soil : Frequently found to grow as an under growth sporadically
or in patches in the mixed semi-deciduous forests. Grows well in moist and
moderately high rainfall (4000 – 6500 mm) area with temperature range from
4-37 or 40oC. It commonly grows on the flat alluvial deposits land along water
courses up to 1500 m. attitude. Soils under this species contained reserve of
organic matter, nitrogen, Ca, K, P.

Description : This species is a evergreen or deciduous, tufted,
gregarious bamboo.

Culms : Culms usually 7-23 m high and 5-10 cm in diameter, glabrous,
green when young, gray-green on maturity, nodes slightly thickened, lower
ones have fibrous roots, internodes 40-70 cm long.

Culm sheaths : It is 15-25 cm long and broad, attenuate upwards and
rounded or truncate at top, deciduous, adaxial surface smooth and often with
whitish powder, abaxial surface sometimes covered with appressed brown
hairs.

Leaves : Leaf 15-20 cm long and 2-4 cm broad, linear and lanceoalate,
alternate on opposite sides leaf – sheath striate, glabrous, 2.5 mm long hairy
petiole.

Inflorescene : Its occur on leafless branches and spikelets variable in
length from 2.5 – 7.5 cm long and 5 mm broad, sessile, glabrous, cylindrical
and acute at first, after wards divided into many flowers separated by
conspicuous rachillae, becoming first 1-2 short bracts, then 2-4 usually
gemmiparous empty glumes, 4-6 fertile flowers and 1 or 2 imperfect or male
terminal flowers.

46

Stamens long exerted, anther 7.5 mm, glabrous, blunt at the tip or
emarginated, ovary, obovate oblong, white, hairy above, surrounded by a
short haring style, divided into 3 long plumose wavy stigmas.

Flowering cycle : Flowering cycle is reported to vary from 30-60 years. It
flowers gregariously over considerable areas. Flowering was observed in
Bengal during the years 1867-68, 1872, 1884, 1919, 1930 & 1936, in Assam
during 1886, 1910 & 1930, in Myanmar during 1892, 1903, 1908, 1911 &
1914 and in Bangladesh in 1876, 1886, 1929-30, 1976-77, 1978-79, 1982-83
& 1983-84.

Recently it flowered at Dehradun in 1986, flowering only once in their
lifetime and die after they bloom.

Fruit : Coryopsis type, oblong, 7.5 mm long, hirsute the apex,furrowed.

Propagation : Vegetative propagation using one year old, culm cutting
treated with NAA + K or IAA + K in July gave maximum rooting. Planting in
summer season was better (Adarsh Kumar et al., 1988). An efficient protocol
for invitro propagation through shoot proliferation is developed (Saxena,
1990). About 80% survival is reported when the seedlings are transferred to
soil after hardening. It takes 6-10 years for the new seedling to mature after
gregarious flowering.

Uses : The species is used through out North-East India for covering
the houses and scaffolding. The tender shoots are used for making excellent
pickles. It is suitable for the manufacture of wrapping, writing and printing
paper.

Used in Tripura for making toys, mats, screens, wall plates, wall
hangers, hats, baskets, food grain containers etc.

In Arunachal Pradesh this species is used for flute, locally “Eloo” and
used for priests during “Dree” festival with the belief that the sound will keep
the evil spirits away.

47

In Northern Thailand, it is one of the two most important edible species
until half a century ago. It has long been exported to Europe and the USA
under the names “Calcutta cane” or “East India Brown Bamboo”. It can be
used as reinforcement in cement concrete. The succulent shoots are rich in
phytosterols and the fermented shoots can be used for production of sterol
drugs.It is mainly used by the Indian paper pulping industry.

SPECIES – B

Classification : Kingdom - Plantae
Sub-Kingdom - Tracheobionata
Class - Liliopsida
Sub-class - Commelinideae
Order - Cyperales
Family - Gramineae
Genus - Dendrocalamus
Species - Longispathus

Vernacular name : Rupai

Distribution : The species is distributed in Mizoram and Tripura and
generally found in the village area of Dhalbhum tract of Singhbhumi district of
Bihar. The species has been introduced to Orissa and Western Peninsula. It
is cultivated in Calcutta and Malabar. Also reported from Bangladesh and
Myammar (Banik 1987a, Prasad 1965 and Gamble, 1986).

Description : It is a large tufted bamboo.

Culms : Usually 10-18 m high, glaucous green when young, grayish –
green on maturity, nodes-slightly swollen, internodes – 25 to 60

48

cm long and 6 to 10 cm diameter, covered by long papery
remnants of sheaths and dark brown pubescence.

Culm sheaths : 35-50 cm long and 10-20 cm broad, inner surface
glabrous and outer surface clothed densely with patches of stiff
dark – brown hair, margin light straw colored in the upper half.
Young shoots spear – shaped. Culm sheth ligulate.

Leaves : 10-30 cm long and 2.5 – 3.5 cm broad, oblong – lanceolate and
linear – lanceolate, short stalked, margin rough, leaf sheath
ligulate covered with brown pubescence and margin ciliate.
Inflorescence : A large panicle of interruptedly spicate clusters of
spikelets. Sometimes few flowers are blunt in spikelets heads.
Stamens – short, Anther-yellow, short, ending in a black
mucronate point, filaments – short, ovary – broadly avoid,
somewhat acute, hairy, ending in a rather short style and short
purple stigma.

Flowering : flowering cycle is reported to vary from 30-45 years. Flowering
has been reported from Bangladesh during the year 1876, 79,
80, 85, 1930 & 1977-79, from Myammar during 1862, 71, 75, 87,
91, 1912 & 1913.
Flowering was observed in the clumps planted at Nilambur and
Wynad (Kerala) in 1990.

Fruiting : Caryopsis type, 7-8 mm long, oblong and furrowed.

Propagation : Vegetative propagation by two nodded culm cuttings, rhizome
cuttings gives good response. Miropropagation through shoot
proliferation is developed (Saxena & Bhojwani 1993). The
species can be propagated by seeds.

Uses : It is generally used for the manufacture of paper. In Tripura it is
used for making baskets and containers. This is found as an

49

idea for the manufacture of good quality tooth picks. This being
an elegant species is grown in gardens.

Medicinal Plants

A medicinal plant is any plant which in one or more of its organs,
contains substance that can be used for therapeutic purpose of which is a
precursor for synthesis of useful drugs.

The plants that posses therapeutic properties or exert beneficial
pharmacological effects on the animal body are generally designated as
“Medicinal plants”.

Although there are no apparent morphological characteristics in the
medicinal plants growing with them, yet they posses some special qualities or
virtues that make them medicinally important. It has now been established
that the plants which naturally synthesis and accumulate some secondary
metabolites, like alkaloids, glycosides, tannins, volatile oils and contain
minerals and vitamins possess medicinal properties.

Medicinal plants constitute an important natural wealth of a country.
They play a significant role in providing primary health care services to rural
peoples. they serve as the therapeutic agents as well as important row
materials for the manufacture of traditional and modern medicine.

50

In India medicinal plants widely used by all sections of the population
and it has been estimated that in total over 7500 species of plants are used by
several ethnic communities.

Secondary metabolites :
Plants are the source of a large variety of biochemicals, which are
metabolites of both primary and second metabolism. But secondary
metabolites are of much greater interest since they have impressive biological
activities like antimicrobial, antibiotic, insecticidal, molluscicidal, hormonal
properties and valuable pharmacological and pharmaceutical activities, in
addition, many of them are used as flavours, fragrances, etc. The tem
secondary metabolite is ill-defined but convenient, it is applied to all those
compounds, which are not directly involved in the primary metabolite
processes, eg. photosynthesis, respiration protein and lipid biosynthesis etc.
Secondary metabolites include a wide variety of compounds.

Higher plants are the source of a large number of pharmaceutical
important biochemicals, about 25% of the prescribed medicines are solely
derived from plants.

Table 1.7 A Selected List of Some Groups of Biochemicals Obtained
From Plants :

S.No. Group Examples
1. Alkaloids Morphine, codeine, quinine, nicotine, cocaine,
hyoscyamine, lysergic acid etc.

2. Terpenoids Menthal, camphor, carotenoid pigments,
polyterpenes etc.

3. Phenylpropanoids Anthocyanins, coumarins, flavonoids, isoflavonoids,
stilbenes, tannins etc.

4. Quinones Anthraquinones, benzoquinones, naphthoquinones.

5. Steroids Diosgenin, sterols, ferruginol, etc.

51

Medicinal Plant - Rauwolfia serpentine

Classification :
Kingdom - Plantae
Class - Magnoliopsida
Order - Gentianales
Family - Apocynaceae
Genus - Rauwolfia
Species - serpentine

Common name : Snake root, serpentine root, sarpgandha etc.

Habitat :
It is grown in India, Pakistan, Srilanka, Burma and Thailand. In India, it
is widely distributed in the sub-Himalayan track from Punjab to Nepal, Sikkim
& Bhutan. It is also found in the lower hills of Gangetic plains, eastern and
Western Ghats and Andamans. It is mostly found in moist deciduous forests
at altitudes ranging from sea level to an altitude of 1,200 m high. In the
Deccan it is associated with bamboo forests.

52

Morphology description :
It is an evergreen, perennial, glabrous and erect undershrub grows up
to height of 60 cm (rarely more than it) roots are tuberous with pale brown
cork. leaves are in whorls of three, elliptic to lanceolate or obovate, bright
green above, pale green below, tip acute or acuminate, base tapering and
slender, petioles long. Flowers are in many flowered irregular corymbose
cymes. Peduncles long but pedicles stout flowers white, often has violet color.
Calyx glabrous bright red and lanceolate, corolla is longer than calyx, tube
slender, swollen a little above the middle, lobes 3 and elliptic oblong. Disc is
cup shaped. Drupes are slightly connate, obliquely avoid and purplish black in
color.

Reserpine is an indole alkaloid formerly used in treatment of
schizophrenia and hypertension (it’s still rarely used for hypertension therapy
today). Alkaloids often classified on the basis of their chemical structure. For
example, those alkaloids that contain a ring system called indole are known
as indole alkaloids. On this basis, the principal classes of alkaloids are the
pyrrolidines, pyridines, tropanes, pyrrolizidines, isoquinolines, indoles,
quinolines, and the terpenodis and steroids.

Molecular Formula : C33H40N2O9
Molecular mass : 608.68 g/mol
Uses :

53

This plant is used medicinally both in the Modern Western Medical
system and also in Ayurveda, Unani & folk medicine. It helps to reduce blood
pressure, depresses activity of central nervous system and acts as a hypnotic
snake root depletes catecholamines and serotonin from nerve in central
nervous system. Refined snakeroot has been used extensively in recent years
to treat hypertension. It is used as an antidote to the bites of poisonous reptile
like snakes.It is also used to treat dysentery and other painful affections of the
intestinal canal.

REVIEW OF LITERATURE

2.1 Plant Tissue Culture : A Historical Introduction
The science of plant cell and tissue culture is really not more than five
decades old. It was conceived and enunciated by Haberlandt in 1902.
Haberlandt visualized the idea of growing plant cells in artificial media in the
hope of rejuvenating a quiescent cell and triggering it into division and growth,
to form a tissue and eventually, regenerate a whole new plant. But in this, he
himself was unsuccessful. Robbins (1922a, b) was the first to develop a
technique for the culture of isolated roots. He conducted a series of
experiments using maize roots capable of being subcultured, and
demonstrated the efficiency of yeast extract (YE) for growth, indicating the
necessity for vitamin requirements. However, his cultures did not survive
indefinitely, perhaps because the selection of material was not good. In 1939
some more progress was reported in the successful culture of organized
structures such as tomato roots, storage roots of carrot. Street and his co-
workers carried out extensive studies on isolated root tips of several plants for
organ culture, to understand the factors concerned with their growth.
Gautheret, Heller and Camus (1939-1957) of the French School of Tissue

54

Culture, examined the histo-physiological changes brought about in explanted
tissues by substances such as B-vitamins, cysteine HCl, glucose and Indole
acetic acid (IAA) in the basic media. Experiments on the induction of vascular
tissues by grafting of shoot buds into callus, gave the clue to the influence of
growth hormones in cyto-differentiation and morphogenesis. Studies by
Wetmore and sorokin (1955). Wetmore and Rier (1963) and others in USA
confirmed the role of auxins and vitamins as controlling factors in growth.

Skoog and Miller (1957) demonstrated that regulation and
differentiation of roots and shoots (orgnogenesis) in tobacco pith cultures
depended on the relative concentration of auxin / cytokinin. The stimulatory
effect of coconut mil (CCM) in plant embryo nutrition in vitro was established
by van Overbeek (1941b) through his experiments with Daturu embryos.
Later, Steward, Caplin and Miller (1952) emphasized the importance of
coconut milk in nutrition, callus growth and embryogenesis or carrot, followed
by Reinert (1958) and Pilet (1961) who indicated their development on a
purely synthetic medium without the addition of the liquid endosperm or other
plant extracts. Culture of excised root tips of tomato (an example of organ
culture), indicated the need for vitamins of the B-group as growth
supplements in the medium (White, 1943).

Between 1939 and 1956, tissue culture studies were in a state of flux. It
was a period of exploration and innovation in approach and technique, using
such plants as carrot, tobacco and Helianthus tuberosus (Jerusalem
artichoke). By then considerable progress had been made on the question of
tissue nutrition. It soon came to be realized that no one single medium was
satisfactory for the growth of all tissues, and this led to the formulation of
different media to suit different tissues. A balanced solution which served as a
basic medium for a wide spectrum of plant tissues is that of Murashige-Skoog
(MS) (1962) and several modifications.

The demonstration of the development of somatic embryos
(embryoids) from carrot cells in suspension by Reinert in Germany and
Steward in USA (1958, 1959) and subsequently of leaf mesophyll cells of Mc

55

Cleaya cordata by Kohlenbach (1966, was another in the history of cell culture
technology).

Isolation and culture of shoot meristems and nodal meristems of plants
resulted in regeneration of multiple shoots and of plants free of virus and other
pathogens, widely applicable to breeding to true-to-type progenies, an
offshoot of the technique developed by Morel (1960) with orchids.

Single cell culture were developed by Muir (1953) and Muir et al.
(1958) by the paper-raft nurse technique, by Torrey (157) and Jones et al.
(1960) by the micro-chamber method (hanging drop culture), and by
Bergmann (1960) through the agar-planting method as for bacteria. By the
1960s, tissue culture techniques had become common place the world over.
Subsequently, some very exciting technical developments in the manipulation
of individual cells led to the isolation and release of cell protoplasts, by
treating the cell with cell wall degrading enzymes, through the pioneering
efforts of Edward Cocking at the University of Nottingham, UK in the 1970s.

The successful growth in vitro of ovary, ovule and embryo parts in
fruitset and seed development has been highlighted, as response to
exogeneous hormones, in a series of publications in the 1960s. A fascinating
outcome of tissue culture studies initiated at the University of Delhi has been
the spectacular demonstration for the first time of the development of pollen
embryoids and plantlets from another culture of Datura innoxia by Guha and
Maheshwari (1964, 1967).

Tissue cultures of elite forest tree genera such as Santalum album
(andalwood), Eucalyptus, teak (Tectona grandis) and Dalbergia latifolia (East
Indian rosewood), even from tissues isolated from mature 100-year-old trees
and from the oil palm, have been made at the Plant Bio-Technology Division
of Bhabha Atomic Research Centre (BARC), Bombay, the Indian Institute of
Science, bangalore, the National Chemical Laboratory, Pune, Central
Plantation Crop Research Institute, Kasaragod, Kerala, India and at the Indian
Institute of Horticultural Research, Bangalore, India. In vitro culture of grain

56

legumes, arboreal forms of Gramineae and of several conifers are also being
pursued at the Department of Botany, University of Delhi, India.

Yet another fruitful area has been recognized in the manipulation of
cultured cells for the increased production of high value secondary
compounds using industrial fermentors and bio-reactors. Lindsey and
Yeoman (1986) envisaged the application of the principle of aggregation and
passive immobilization of small groups of plant cells in a fixed bed reactor for
augmenting the biosynthetic potential of cell cultures and training cells to
produce and accumulate the desired compound.

Technical advances in recent years in cell culture have been
tremendous and unique in their application as commercial tools to horticulture,
silviculture, agriculture, biochemistry and plant pathology. Dramatic strides
have been made over the years in the step-by-step evolutionary progress in
the culture and manipulation of the plant cell.
2.2 Tissue Culture Research on Bamboo
The first paper on successful tissue culture is with Alexander and Rao
(1968) who described embryoculture. In the eighties there was a considerable
increase with propagation of seedlings in tissue culture (Nadgir et al., 1984),
the induction of somatic embryogenesis in bamboo seeds of tropical species
(Rao et al. 1985), clonal propagation of Guadua angustifolia (Manzur, 1988)
and other induction of somatic embryogenesis in bamboo seeds of tropical
species (Rao et al. 1985), clonal propagation of Guadua angustifolia (Manzur,
1988) and other species (Prutpongse and Gavinlertvatana, 1992), and the
induction of organogenesis (caulogenesis) in mature bamboos (Huang et al.,
1989).

The plants obtained through micropropagation based on
methodologies using seeds and seedlings are similar to the seedling material,
juvenile in appearance with “weedy” stems, and progress through growth
phases akin to seedlings. However, plantlets of Dendrocalamus latiflorus,
obtained adventitiously from callus generated from rhizome and internode
calli, shifted toa culm growth habit similar to cutting-derived planting material
within a year in the greenhouse (Zamora et al. 1991).

57

The number of papers about this subject however is much less, and
this is solely due to lack of success. Indeed, technically the propagation of
adult plants via axillary branching is much more difficult than with seedlings of
tropical bamboos. (Zomora, 1994 , Nadgauda et. al., 1997).

For bamboo different propagation techniques are available, such as
seed propagation, clump division, rhizome and culm cuttings (Banik, 1994).
But these methods suffer from serious drawbacks when one talks about large
or mass scale propagation.

For tissue culture of bamboo the use of starting material (seeds or
adult plants) and the choice of the propagation method are crucial (Gielis,
1999). The two major advantages of using seedlings are that seedlings
establish a new generation, and that the technology is easier. But the
disadvantages are considerable : (1) insufficient or no knowledge of genetic
background, (2) restricted availability of seeds for most species and rapid loss
of germination capacity, and (3) comparison of in vitro to in vivo performance
has not been thoroughly evaluated. In addition there is a huge variability in
responsiveness in tissue culture (Saxena and Dhawan, 1994).

For bamboo different propagation techniques are available, such as
seed propagation, clump division, rhizome and culm cuttings (Banik, 1994,
Banik, 1995). But these methods suffer from serious drawbacks for large or
mass scale propagation. For mass scale propagation (> 500 000 plants per
year) classical techniques are largely insufficient and inefficient, and tissue
culture is the only viable method. Indeed, the order of magnitude of the
demand for bamboo planting materials indicate that micropropagation will
inevitably be necessary for mass scale propagation (Subramanlam, 1994,
Gielis, 1999).

One of the main problems with bamboo is that it has been regarded as
a resource, which is simply there to take, as has been done for thousands of
years by people in rural economies. However, in industrial economies such
practice leads to considerable overexploitation and rapid depletion of bamboo

58

resources in the vicinity of the paper mills and factories. Up to the point that
transportation costs have become too high for bamboo to be economical
(indeed transportation of culms is a lot of air). Estimates regarding future use
of bamboo all indicate that there will be an huge shortage for bamboo planting
material in medium and long term (Subramanlam, 1994, Nadgauda, 1997).

Indeed, the order of magnitude of the demand for bamboo planting
materials indicates that micropropagation will inevitably be necessary for
mass scale propagation (Subramanlam, 1994, Gielis, 1995). Classical
techniques alone can never solve this problem.

The propogation of bamboos is done with seeds, clump divisions, and
rhizome and culm cuttings. However, gregarious flowering, low seed viability,
high costs, problems facing long-distance transportation of vegetative
propagules, and poor efficiency of plant production, compdelled development
of alternative propagation methods (Gielis et al., 2001).
Gielis and Oprins (2002), this invitro micro-propogation will be of choice
for mass scale propagation of bamboos because the regenerated plants are
genetically uniform. Since the diversity of bamboos is so vast, it is difficult to
present a unique step-by-step protocol for micropropagation of all plants
classified within this group.

In vitro micropropagation constitutes a feasible alternative to mass-
propagate individuals in this plant group. Somatic embryogenesis (Lin et al.,
2004 and references therein) and propagation using axillary buds (Jimenez et
al., 2006, Ramanayake et al., 2006 and references therein) have effectively
been used to multiply bamboos in vitro.

2.2.1 Research on Bambusa tulda :
Saxena (1990) given in vitro propagation of the Bambusa tulda through
shoot prolieration shoots from 3-week-old aseptically grown seedlings were
used to initiate cultures. Multiple shoots were obtained on liquid MS medium
supplemented with benzyladenine (8 x 10-6 M) and kinetin (4 x 10-6 M).
Continuous shoot proliferation at a rate of 4-5 fold every 3 weeks was
achieved through forced axillary branching. More than 90% of shoots were

59

rooted on a modified MS medium containing IAA (1 x 10-5 M) and cournarin
(6.8 x 10-5 M). Following simple hardening procedures, the in vitro raised
plants were transferred to soil with an > 80% success rate.

Banik (1980) given propagation of bamboos by clonal methods and by
seed. Techniques of bamboo propagation with special reference to pre-rooted
and prerhizomed branch cuttings and tissue culture discussed in proceedings
of a Workshop on Bamboo Research in Asia held on 28-30 May, 1980 in
Singapore.

Raina and Prasad in 1988 given effect of nutrients on the growth
behaviour of Bambusa tulda in the nursery.

Kumar and Dhawan, et al. in 1988 given vegetative propagation of
Bambusa tulda using growth promoting substances.

The communication describe standardization of an efficient in vitro
propagation and hardening procedure for obtaining plantlets from field grown
culms of Bambusa tulda. Administration for 10 min of 0.05 and 0.1% mercuric
chloride to explants collected in winter and summer seasons, respectively
facilitated optimum culture establishment and bud break, 0.1-0.2% mercuric
chloride in rainy season enhanced aseptic culture establishment but inhibited
bud break due to toxicity to explants. MS liquid medium enriched with 100 µM
glutamine, 0.1 µM indole-3-acetic acid and 12 µM 6-benzylaminopurine
supported maximum in vitro shoot multiplication rate of two-fold. The
proliferated shoots were successfully rooted on MS liquid medium
supplemented with 40 µM coumarin resulting in a maximum of 98% rooting.
The procedure requires 45 days cycle for the in vitro clonal propagation (15
days for shoot multiplication and 30 days for root induction) and 80 days for
acclimatized plantlet production (Yogeshwar et al. 2008).

2.2.2 Research on Dendrocalamus longispathus:
Rooting percentages for adult bamboos ranged from very low
percentages to 73% for adult Dendrocolamus longispathus (Saxena and
Bhojwani, 1993).

60

When using adult bamboos main problems are : (1) endogenous
contamination, (2) hyperhydricity and instability of multiplication rates, and (3)
many problems with rooting also in bamboos that root readily in nature.
Rooting percentages for adult bamboos ranged from very low percentages of
10% for Bambusa vulgaris to 73% for adult Dendrocalamus longispathus
(Saxena and Dhawan, 1994). A rooting percentage of 77% was obtained for
adult Dendrocalamus giganteus in 3 or 4 weeks (Ramanayake and
Yakandawala, 1997). Low rooting frequencies are the major bottleneck to
developing commercially viable protocols (Saxena, 1993). The combination of
photomixotrophic in vitro multiplication and photoauthtrophic in vitro rooting
stages resulted in improved transplanting success (Watanabe et al., 2000).
Improvement of rooting percentages and transplanting has been achieved in
various commercial laboratories.

Another recent study examining micropropagation of 4 years old plant
of Dendrocalamus longispathus has also found that the nature of the explant
and the season are important determinants of micropropogation success.
(Saxena and Bhojwani 1993).

61

TISSUE CULTURE WORK DONE ON BAMBOO SPECIES

Species Mode of culture Media Reference
Dendrocalamus Seedling/Organogeic MS, KN, BAP, CM, Phondke (19 90)
Braissi cultures IBA

Dendrocalamus Organogenic cultures B5, 2, 4-D IBA, NAA Nadgir et al. (1984)
strictus and Plantlet
regeneration

Somatic MS, 2, 4-D CM Rao et al. (1985)
embryogenesis and
plantlet regenration

Dendrocalamus Callus differentiation ----- Dekker and Rao
strictus (1989)

Bambusa Callus culture ----- Huang and
Muarshige (1983)

Bambusa bambos Seedling / MS, 2, 4-D CM Phondke (1990)
Organogenic culture

Bambusa Somatic Basal, 2, 4-D, BAP Yeh Chang (1986a)
beechyana embryogenesis and
Plantlet regeneration

Bambusa Organogenic callus MS, KN2 Dekkar and Rao
ventricosa (1989)

62

Bambusa oldhamii Somatic MS salts, White’s Yeh and Chang
embryogenesis Vitamin, malt (1986b)
extract and
digestive enzymes

Bambusa Protoplast HD Huang (1988)
multiplex
Phyllostachys Callus culture MS, Nitsch Huang and
Murshige (1983)

P. viridis Somatic --- Anas et al. (1987)
embryogenesis

Sasa Callus culture MS, KN, 2, 4-D Huang and
Murashige (1983)

Sonocalamus Somatic Basal, 2, 4-D Yeh and Chang
latiflora embryogenesis (1987)

Schizotachyum Organogenic callus NAA, CM Dekker and Rao
Brachyclaoum (1989)

MATERIALS AND METHOD

3.1 Preparation of glasswares and minor equipments :
3.1.1 Washing : glassware / labwares were soaked in chromic acid (conc.
H2SO4 / HCl + K2Cr2O7) overnight.
• They were then dipped or soaked in labolene (neutral liquid detergent)
solution for few hours.
• Glasswares are then washed with tap water with the help of brushes and
traces of detergent removed properly by rinsing 4-5 times with tap water.
• Other minor equipments such as forceps, scalpal etc. washed with
labolene.

3.1.2 Sterilization : for killing of all living microorganisms
• Petridishes were wrapped in papers, forceps and scalpels were paked in
test-tubes and are covered with aluminium foil. All the materials (bottles,
test tubes and caps etc.) were sterilize for 60 min. at 121oC temperature
and 15 psi pressure.

63

• The metal equipments and glasswares after autoclaving were dry heat
sterilized in oven at 140-160oC for 2 hours.
• The metal equipments such as forcep, scalpels were also sterilized by
dipping them in 100% alcohol followed by flaming and cooling during
inoculation.
• All dried and autoclaved equipments were kept under UV treatment in
laminar air flow cabinet for 30-45 min prior to inoculation.

A. Instruments used in sample preparation process for
chemoprofiling :
Extraction process
1. Rotary evaporat or (Rotavap)
The rotary evaporator was invented by Lyman C. Craig, while it was
first commercialized by Swiss company Buchi. The Buchi Rotavapor
continues to be the most widely used rotary evaporator, and Rotavapor has
become a synonym for such instruments. It is a device used in chemical and
biochemical laboratories for the efficient and gentle evaporation of solvents.
The main components of a rotary evaporator are a vacuum system, consisting
of a vacuum pump and a controller, a rotating evaporation flask that can be
heated in a heated water bath, and a condenser with a condensate-collecting
flask. The system works because lowering the pressure lowers the boiling
point of liquids, including that of the solvent. This allows the solvent to be
removed without excessive heating.

The Rotavapor is essentially a distillation unit incorporating a rotating
evaporation flask. The rotavapor will evaporate solvent at a much faster rate
than systems using stationary evaporation flasks.

The rotation transfers a thin film of the liquid sample to the whole of the
inner surface of the flask, markedly increasing evaporation rate and assisting
heat transfer from the heating bath. The rotating flask and vapor duct have a
sealing system, which allows operation under vacuum, further accelerating
the evaporation process because of the reduction in boiling point of the
solvent and efficient removal of the vapor phase. Vacuum operation also

64

permits heat labile materials to be successfully concentrated without
degradation. A typical rotary evaporator has a heatable water bath to keep the
solvent from cooling or even freezing during the evaporation process. The
solvent is removed under vacuum is trapped by a condenser and is collected
for reuse or disposal.

2. Soxhlet
Soxhlet extractor is a piece of laboratory apparatus invented in 1879 by
Franz von Soxhlet. It was originally designed for the extraction of a lipid from
a solid material. However, a Soxhlet extractor is not limited to the extraction of
lipids. Typically, a Soxhlet extraction is only required where the desired
compound has only a limited solubility in a solvent, and the impurity is
insoluble in that solvent. If the desired compound has a high solubility in a
solvent then a simple filtration can be used to separate the compound from
the insoluble substance.

The sample is placed in a thumblet. Normally a solid material
containing some of the desired compound is placed inside a thumblet made
from thick filter paper, which is loaded into the main chamber of the Soxhlet
extractor. The Soxhlet extractor is placed into a flask containing the extraction
solvent. The Soxhlet is then equipped with a condenser.

The solvent is heated to reflux. The solvent vapour travels up a
distillation arm, and floods into the chamber housing the thumblet of solid. The
condenser ensures that any solvent vapour cools, and drips back down into
the chamber housing the solid material.

The chamber containing the solid material slowly fills with warm
solvent. Some of the desired compound will then dissolve in the warm solvent.
When the Soxhlet chamber is almost full, the chamber is automatically
emptied by a siphon side arm, with the solvent running back down to the
distillation flask. This cycle may be allowed to repeat many times, over hours
of days.

65

During each cycle, a portion of the non-volatile compound dissolves in
the solvent. After many cycles the desired compound is concentrated in the
distillation flask. The advantage of this system is that instead of many portions
of warm solvent being passed through the sample, just one batch of solvent is
recycled.

3. Millipore-suctioin filteration pore
Nitrocellulose filters or cellulose nitrate and cellulose acetate filters are
used that consist of a close network of fibers providing very small pore size
that allows separation of very fine particles. Because of both the pore size and
surface tensions, liquids do not easily pass through these filter with gravity as
the driving force so that pressure or suction is usually employed. Filters of
various pore sizes are used.

The pores of filter are not circular but irregularly shaped and account
for roughly 80% of the surface area. The filters are sufficiently thin that are
retained parties.
4. Ultrasonicator
It is used for degassing. This instrument is based on sound to agitate
particles in a sample for various purposes.

5. HPLC
The instrument is an assemblage of a pressure pump, solvent delivery
system that is connected to the chromatography column through an injection
port (for loading sample). The column is kept in chromatographic oven that is
further connected to detector, which is in turn linked to a recorder.

Chemical used in HPLC for the extraction of reserpine
o Acetonitrile
o Hexane
o 3% HCl
o 10% NH3
o Sodium sulphate
o Chloroform

66

o Dragondroff’s reagent

3.1.3 Media Preparation and Sterilization
The invitro growth of the plant cells occurs in a suitable medium
containing all the requisite elements. The ingredients of the medium effect the
growth and metabolism of cells.

Murashige and Skoog’s growth medium referred to as MS medium was
used and supplemented with 100 mg/l of myo-inositol and 3% sucrose as
carbon source.

• Plant growth regulators – Auxin IAA (0.5 – 1.0 mg/l) and cytokinin (1.0 –
5.0 mg/l) were used.
• pH – pH was adjusted to 5.7 to 5.8 with 1N HCl & 1N NaOH.
• Solidifying agent – Solid growth medium prepared by supplementing 0.8%
agar.

Table 3.1 Composition of MS medium (Murashige & Skoog 1962) :
S.No. Compound Amount (mg/l)
1. NH4NO3 1650
2. KNO3 1900
3. MgSO4.7H2O 370
4. CaCl2.2H2O 440
5. KH2PO4 170
6. KI 0.83
7. H3BO3 6.2
8. MnSO4.4H2O 22.3
9. ZnSO4.7H2O 8.6
10. NaMoO4.2H2O 0.25
11. CuSO4.5H2O 0.025
12. CoCl2.6H2O 0.025
13. FeSO4.7H2O 27.8
14. Na2EDTA.2H2O 37.3
15. Inosited 100
16. Nicotinic acid 0.5
17. Pyridoxine HCl 0.5
18. Thiamine HCl 0.1
19. Glycine 2

PGR As per need

67

Sucrose 30% (30 mg/l)
Ph 5.7 – 5.8 (using 1 HCl or 1N NaOH)
Agar 0.8% (8 mg/l)

Table 3.2 Stock solutions :
Compound Amount mg/l
A. Stock I (20x) – Macronutrients
NH4NO3 33000
KNO3 38000
CaCl2.H2O 8800
MgSO4 7400
KH2PO4 3400
B. Stock II (200 x) – Micronutrients
KI 166
H3BO3 1240
MnSO4.4H2O 4460
ZnSO4.7H2O 1720
NaMoO4.7H2O 50
CuSO4.5H2O 5
CoCl2.6H2O 5
C. Stock III (200 x) – Iron
FeSO4.7H2O 5560
Na2EDTA.2H2O 7460
D. Stock IV (200 x) – Vitamin
Inositol 22000
Nicotinic acid 100
Pyridoxine HCl 100
Thiamine HCl 20
Glycine 400

For the preparation of stock solutions, each component should be
separately dissolved to the last particle and then mixed with the others.
• All components were dissolved separately in some amount of double
distilled water, mixed with each other and final volume is made up.
• Stock solutions were stored in refrigerator and iron stock stored in a amber
coloured bottle (to prevent photoxidation).

Volume of stock Volume of Media
solution 2000 ml 1000 ml 500 ml
Stock I 100 ml. 50 ml. 25 ml.
Stock II 10 ml. 5 ml. 2.5 ml.
Stock III 10 ml. 5 ml. 2.5 ml.
Stock IV 10 ml. 5 ml. 2.5 ml.

68

Procedure for preparation of 1 litre media

Take 500 ml. DDW in a flask

Add 50 ml of stock I

Add 5 ml. of stock II

Add 5 ml. of stock III

Add 5 ml. of stock IV

Add 30 gm. sucrose and dissolve it

Add required amount of auxin and cytokinin. Auxin dissolved
in alcohol & cytokinin dissolved in 1N NaOH

Make up the volume upto 1000 ml. with DDW

Maintain the pH value it should be 5.7 with
1N HCl & 1N NaOH

Add 8gm. agar in the medium, melt it in microwave oven

Pouring of media into test tubes & bottles and autoclaved for
30 min.

3.2 Explant
Tissue culture is started from pieces of whole plants. The small organs
or pieces of tissue that are used are called explants.

The part of the plant from which explants are obtained, depends on :
o The type of culture to be initiated
o The purpose of the proposed culture

69

o The plant species to be used

Collection time of explant
The time of explant affects the success of plant tissue culture. The
explant is favoured for tissue culture as it is less susceptible contamination as
compared to large sized explants.

3.3 Preparation of explant - A
Explant collection - Explant was collected from Bamborium /
Bambusetum of SFRI, Jabalpur.
• Criteria for clump selection : ♦ Clump should be phenotypically superior
♦ Clump should be healthy and
disease free.
♦ Number of culms should be more.
♦ Culm shows maximum branching.
• Criteria for explant selection (collected from mature culms)
♦ Nodal part having unsprouted bud was taken as explant.
♦ Nodal part should be free from dust & contamination.
♦ The size of explant would be ranging from few mm to few
inches.

Treatment of explant prior to inoculation

Explant (thin culms with nodes)

Washing with 5% extran / for 30-45 min.

70

Rinsing with distilled water 4-5 times

Washing with 2% Bavistin (antifungal agent) for
30-45 min.


Trimming of explant (above & below nodal region)

Removal of nodal ring

Wipping of explant with 80% alcohol

Keeping of explant in bottle containing distilled water and covering
with muslin cloth

Treatment of explant during inoculation (under aseptic condition)

o Explant was UV sterilized for 45 min in laminar air flow cabinet.
o Washing of explant was performed 3-4 times with sterilized double
distilled water.
o Explant was treated with 0.1% HgCl2 for 8-12 min. for surface
sterilization and again washed with sterilized double distilled water
(3-4 times).

• Inoculation
o Fresh culturing : The treated explant was inoculated in sterilized medium
test tubes and sealed with cellophan tape and inoculation date and
accession number was marked. This procedure was performed under
aseptic condition in Laminar Air Flow cabinet.

71

o Subculturing : The in-vitro grown shoots explants were cut above
(transverse cutting) and below (slant cutting) nodal region and transferred
in sterilized medium (in bottles) for further growth.
o Maintenance of culture : Inoculated culture vessels were transferred to
the culture rocks for growth (at 16 hrs. of photoperiod and 8 hours dark at
25 + 2oC temperature).
o Observation :
 Cultures were timely observed for growth and contamination.
 Contaminated cultures were immediately removed.

3.4 Preparation of explant : B
Explant collection : Explant was collected from bamborium /
bambusetum of SFRI ,Jabalpur. The plant was tissue cultured , which was
recently flowered in Dec 08- Jan 09.
• Criteria for seed selection :
 Seed should be healthy and disease free.

Treatment of explant prior to inoculation

Explant (seeds)
Washing with 5% extran for 10-20 min.


Washing with 2% bavistin (antifungal agent) for 10-20 min.


TreatmentKeeping of explant (seeds) in bottle containing distilled
of explant during inoculation (under aseptic condition)
water and covering with muslin cloth
o Explant was UV – sterilized for 45 min in Laminar Air Flow cabinet.
o Washing of explant (seeds) was performed 3-4 times with sterilized double
distilled water.
o Explant was treated with 0.1% HgCl2 for 5-10 min for surface sterilization
and again washed with sterilized double distilled water (3-4 times).

72

• Inoculation
o Fresh culturing : The treated explant was inoculated in sterilized
medium test tubes and sealed with cellophan tap and inoculation
date & accession number was marked. This procedure was
performed under aseptic condition in Laminar Air Flow cabinet.
o Sub culturing : Seeds were removed from in-vitro grown plants
and transferred in sterilized medium (in bottles) for further growth.

• Maintenance of culture : Inoculated culture vessels were transferred to
the culture racks for growth (at 16-18 hrs. of photoperiod and 6-8 hrs. dark
at 25 + 2oC temperature).

• Observation :
o Cultures were timely observed for growth and contamination.
o Contaminated culture was immediately removed

3.5 PREPARATION OF SAMPLE FOR HPLC :-
Procedure : Soxhlet process
o Collect the material and wash them.
o Keep for 15-25 days for drying.
o Take 2 gm. of dried powdered material.
o Perform solubility test.
o Refluxing in soxhlet apparatus for 8 hrs.
o Sample should be concentrated and recovery of solvent by rotary vapor.
o Then undergo for purification.

Dipping process :
o Take the 2 gm. of sample.
o Dipped into 150 ml. of acetonitrile (solvent).
o Kept in conical flask into water bath for 8 hrs.
o Filter the sample by Whatt’s man filter paper.
o Heat (again left for 8 hrs.).

73

o Load the collected sample in rotary vapor.
o Solvent was extracted out.
o Then undergo for purification.

Purification process :
1. Collect the concentrated sample and treat with equal amount of hexane
times.
2. Use pellet as a sample and add equal amount of 3% HCl mix properly and
filter it.
3. Take supernatant as a sample and adjust the pH 7-7.2 with the help of
10% NH3.
4. Filter it and treat with chloroform (3 times).
5. Take the supernatant as a sample and add 1 gm. of sodium sulphate and
dissolve it.
6. Test with dragondroff’s reagent for alkaloid sample is filtered through
Millipore suction filter.
7. Take 5 ml solution for injection into HPLC.
8. Sample injected into HPLC system through injector and loaded peak is
obtained after retention time.

Precautions :
1. Flushing
To cleanup column flushing is required for this run the solvent for at
least half an hour, when switch on the unit and half an hour before switch off
the unit.

74

RESULTS , DISCUSSION AND CONCLUSIONS

OBSERVATIONS – Species (Explant) A

Table – 1 – NO PGR

Species & explant Date of Total no. of Observations
inoculation inoculated Growth Total No. of After7 After 14 After 21 Treatments Remarks
test tubes initiation sprouted days(cm) days(cm) days(cm)
test tubes
No. of 1. Fungal
shoots 2-5 3-8 5-8 contamination was
observed after 2
Sprouting Length of A – 45 min. weeks in 4 test
13.03.09 15 after 3 11 shoots .1-.8 .4-1.8 .5 -2.6 B – 45 min. tubes.
days C – 8 min.
Root 2. Growth was good.
formation - - -
Bambusa tulda,
nodal region
No. of 1. Fungal
shoots 3-4 5-8 5-8 contamination was
A – 40 min. observed after 2
Sprouting
Length of B – 40 min. weeks in one test
16.03.09 15 after 3 13
shoots .1-.8 .1-1.5 .2-2.9 C – 9 min. tube.
days
Root 2. Growth was good.
- - -
formation

75

Table – 2 – IAA . 5:1 BAP

inoculation inoculated Growth Total No. of After After 14 After 21 Treatments Remarks
test tubes initiation sprouted 7days(cm) days(cm) days(cm)
test tubes
No. of 3. Fungal
shoots 2-6 3-7 5-8 contamination
observed after 1
Sprouting Length of A – 20 min. week in 1 test
0.3-1.
25.03.09 10 after 3 7 shoots 1-2.1 3-2.3 B – 20 min. tube.
7
days C – 6 min.
Root 4. Growth was slow
formation - - - after 14 days.
Bambusa tulda,
nodal region
No. of 3. Fungal
shoots 1 1 2 contamination not
A – 30 min. observed.
Sprouting
Length of B – 30 min.
25.04.09 10 after 5 4 0.5-1.
shoots 0.4 0.7 C – 10 min. 4. Growth was very
days 7
D – 30 min. slow.
Root
- - -
formation

76

Table – 3 – IAA . 5:1.5 BAP

test tubes
No. of 1. Fungal
shoots 2-5 4-7 5-9 contamination not
observed.
A – 20 min.
Sprouting Length of
B – 30 min.
26.03.09 10 after 4 7 shoots 0.2-1.8 0.2-2.2 2-3.2 2. Growth was
C – 10 min.
days average.
D – 20 min.
Root
formation - - -
Bambusa tulda,
nodal region
No. of 1. Fungal
A – 20 min. observed.
Sprouting
Length of B – 20 min.
09.04.09 24 after 4-8 8
shoots 0.2-1 0.3-1.9 0.5-2 C – 9 min. 2. Growth was very
days
slow.
Root
- - -
formation

77

Table – 4– IAA . 5 : 2 BAP

test tubes
No. of 1. Fungal
observed.
A – 20 min.
Sprouting Length of
B – 30 min.
25.03.09 20 after 2 19 shoots 0.2-1.8 0.3-2.7 2-5.2 2. Growth was very
C – 10 min.
days fast.
D – 20 min.
Root
formation - - -
Bambusa tulda,
nodal region
No. of 1. Fungal
shoots - - - contamination not
A – 30 min.
observed.
B – 30 min.
No. Length of 2. Sprouting was not
05.04.09 20 0 C – 10 min.
Sprouting shoots - - - observed between
D – 30 min.
7-21 days.
Root
- - -
formation

78

Table – 5 – IAA . 5 : 2.5 BAP
test tubes
No. of 1. Fungal
Sprouting Length of B – 30 min. days in 1 test tube.
26.03.09 20 after 3 14 shoots 0.2-1.5 0.4-1.8 1.3-2.1
days C – 10 min. 2. Growth was slow.
Root D – 20 min.
formation - - -
Bambusa tulda,
nodal region
No. of 1. Fungal
A – 30 min.
shoots - - - contamination not
B – 30 min. observed.
No. Length of
21.04.09 20 0 C – 10 min.
Sprouting shoots - - - 2. Sprouting was not
D – 30 min. observed between
Root 7-21 days.
- - -
formation

79

Table – 6 – IAA . 5 : 3 BAP
test tubes
No. of 1. Fungal
Sprouting Length of B – 40 min. week in 1 test tube.
23.03.09 20 after 3 16 shoots 0.2-1.8 0.3-2.1 0.7-3.8 2. Growth was slow
days C – 09 min. after 14 days.
Root
formation - - -
Bambusa tulda,
nodal region
No. of 1. Fungal
A – 40 min.
Sprouting
Length of
07.04.09 20 after 4 13 C – 10 min.
shoots 0.2-0.7 0.4-1.8 0.3-2 2. Growth was very
days
D – 30 min. slow.
Root
- - -
formation

80

test tubes
No. of 1. Fungal
shoots 2-4 3-5 4-9 A – 20 min. contamination not
observed.
B – 20 min.
Sprouting Length of
16.03.09 20 after 3 11 shoots 0.3-1 0.5-1.8 1.5-3 C – 10 min. 2. Growth was
days average.
D – 30 min.
Root
formation - - -
Bambusa tulda,
nodal region
No. of 1. Fungal
A – 30 min.
Sprouting
Length of
20.03.09 20 after 3 13 C – 10 min.
shoots 0.2-0.7 0.3-1.2 0.4-2.2 2. Growth was very
days
D – 30 min. slow.
Root
- - -
formation

81

OBSERVATIONS – Species (Explant) - B

inoculation inoculated Germination Total No. of After10 After 20 After 30 Treatments Remarks
test tubes germination days(cm) days(cm) days(cm)
test tubes
No. of 1. Fungal
1 1 1
shoots contamination not
MS 2-4 MS-3-5 MS-5-7
observed.
A – 20 min.
Length of
10 with Shoots 0.7-1.3 4-8.1 7.5-12 B – 20 min.
Dendrocalamus
After 2 variation MS .2-.8 MS 2-4 MS 1-6 2. Multiple shoots
longispathus 30.03.09 10 C – 04 min.
days in shoot formation in 2 test
Seed
growth tubes with slow
More More growth and root
Length of
5-4.8 than 5 than 5 formation not found.
Root
cm cm

∗ MS – Multiple Shoot

82

inoculation inoculated Germination Total No. of After10 After 20 After30 Treatments Remarks
test tubes
No. of 1 1 1 1. Fungal
MS 3 MS 5 MS 6 A – 10 min. observed.
1.6-3 5.3-5.9 7-8.9
3 with B – 20 min. 2. Multiple shoot
Length of
Dendrocalamus After 2 variation
30.03.09 10 shoots MS .3-.4 MS . MS.6-1.8 C – 05 min. formation in 1 test
longispathus days in shoot tube with slow
3-1.2
growth growth and root
Length of More More formation not found.
Root 2.5 than 5 than 5
cm cm


83

inoculation inoculated Germination Total No. of After 10 After 20 After30 Treatments Remarks
test tubes
shoots contamination
not
MS 8-16 MS13-39 MS15-60 observed.
(about) A – 10 min.
6 with .6-.8 2.2-3.8 5.6-6.3 B – 20 min. 2. Multiple shoot
Length formation in 4 test
Dendrocalamus After 2 variation
30.03.09 10 of C – 05 min. tubes with slow
longispathus days in shoot MS .3-.8 MS .5-1 MS
shoots growth and root
growth 1.2-2.6
formation not found.
Length
2.5-5 More than More
of Root
5 cm than 5 cm


84

Table – 4 – IAA . 5 : 2.5 BAP
inoculation inoculated Germination Total No. of After10 After20 After 30 Treatments Remarks
test tubes
No. of 1. Fungal
shoots 1 1 1 contamination
observed in 1 test
A – 10 min.
Length of tube after 20 days.
1.2 4 6.8
5 with shoots B – 20 min. 2. Multiple shoot not
Dendrocalamus After 2 variation found.
30.03.09 10 C – 05 min.
longispathus days in 3. Germination found
growth in 5 test tubes but
Length of More More
3 proper growth was
Root than 5 than 5
found in only 1 test
cm cm
tube .


85

test tubes
MS 2 MS 3 MS 4 A – 20 min. observed.
0.7-1.2 2.7-7.8 3.5-15
7 with Length of B – 30 min.
2. Multiple shoot
Dendrocalamus After 2 variation shoots
02.04.09 10 MS .2-.4 MS.3-.7 MS.3-1 C – 05 min. formation in only 1
longispathus days in
test tube with slow
growth
growth and root
Length of More
0.8-.16 2.7-4 formation not found.
Root than 5
cm


86

test tubes
MS 2-11 MS 3-20 MS 4-40 A – 20 min. observed.
(about)
8 with B – 30 min. 2. Multiple shoot
.8-2.8 4.5-13 5.7-16.9
Dendrocalamus After 3 variation Length of
06.04.09 42 C – 04 min. formation in 3 test
longispathus days in shoots tubes with slow
MS .2-.6 MS . MS .8-4
growth
5-2.8 growth and root
Length of More formation not found.
0.2-1 1-5
Root than 5
cm


87

Table – 7 – IAA . 2 : .5 BAP
test tubes
MS 2-3 MS 3 MS 4-5 A – 20 min. observed.
1-6.5 5-12.2 9-17.2
28 with Length of B – 30 min.
2. Multiple shoot
Dendrocalamus After 2 variation shoots
02.04.09 30 MS .2-.6 MS.5-2.8 MS .8-4 C – 05 min. formation in 3 test
longispathus days in shoot
tube with slow
growth
growth and root
Length of More More
0.2-4 formation not found.
Root than 5 than 5
cm cm


88

Table – 8 – IAA . 5 : 1 Kinetin
test tubes
No. of 1. Fungal
shoots 1 1 1 A – 20 min. contamination not
observed.
B – 30 min.
Length of
Dendrocalamus After 2 1.5-6.5 3.3-13.2 4.8-17.5
02.04.09 22 16 shoots C – 05 min. 2. Multiple shoot not
longispathus days
found.
Length of More More
0.4-3
Root than 5 than 5
cm cm


89

RESULTS

Species - A
The effects of different PGR combination on the in vitro growth pattern
of Bambusa tulda are as follows :

Induction of Multiple Shoots : (In fresh culturing)
Table 1 : NO PGR - The better shoot proliferation was observed.
Table 2 : IAA 0.5:1 BAP - The shoot proliferation was good in first trial but
very poor in second trial.
Table3:IAA 0.5 :1.5 BAP - The shoot proliferation was good in first but
average in second trial.
Table 4: IAA 0.5 : 2 BAP - The shoot proliferation was extensive in first trial
but no sprouting in second trial.
Table 5: IAA 0.5 : 2.5 BAP- The shoot proliferation was moderate in first
trial but no sprouting in second trial.
Table 6: IAA : 0.5 : 3 BAP - The shoot proliferation was average in first
trial and poor in second trial.
Table 7 IAA 0.5 : 4 BAP – The shoot proliferation was good in first trial but
poor in second trial.

Increase in Shoot Length :
Table 1 : NO PGR - The shoot growth was good.
Table 2 : IAA 0.5 :1 BAP - Shoot length was less (2.3 cm) in first trial and
very less (1.7 cm) in second trial.
Table 3:IAA 0.5:1.5 BAP - Shoot length was moderate (3.2 cm) in first trial &
less (2 cm) in second trial also.
Table 4:IAA 0.5:2 BAP - Shoot length was maximum (5.2 cm) in first trial.
Table 5:IAA 0.5:2.5 BAP - Shoot length was less (2.1 cm) in first trial.
Table 6:IAA 0.5:3 BAP - Shoot length was average (3.8 cm) in first trial &
less in (2 cm) second trial.
Table 7: IAA 0.5:4 BAP - Shoot length was good (4 cm) in first trial & very
poor (2.2 cm) in second trial.

90

Sub Culturing :
During sub culturing of sprouted explant in all the combinations were
dried within 2-7 days.

Species – B
Induction of Shoots :
Table 1: IAA 0.5:1 BAP - The shoot proliferation was good but with
less germination percentage i.e. 40%.
Table 2 : IAA 0.5 : 1.5 BAP - The shoot proliferation was good but with
less germination percentage i.e. 30%.
Table 3 : IAA 0.5:2 BAP - The shoot proliferation was good but with
less germination percentage i.e., 60%.
Table 4 : IAA 0.5 : 2.5 BAP - The shoot proliferation was good but with
Table 5 : IAA 0.5 : 3 BAP - The shoot proliferation was good but with
Table 6 : IAA 0.5: 4 BAP - The shoot proliferation was good but with
Table 7 : IAA 0.2 : 0.5 BAP - The shoot proliferation was good with good
germination percentage i.e., 93%.
Table 8 : IAA 0.5 : 1 Kinetin - The shoot proliferation was good with good
germination percentage i.e., 72%.

In above all combinations the induction of root was also found with
shoot induction in single shoots only.

Increase in Shoot Length :
Table 1 : IAA 0.5 : 1 BAP - Increase in length was more in single shoot
(maximum 12 cm) and less in multiple shoot
(max. 5 cm).
Table 2 : IAA 0.5 : 1.5 BAP - Increase in length was more in single shoot
(max. 8.9 cm) and less in multiple shoot
(max. 1.8 cm).

91

(max. 2.6 cm).
(max. 6.8 cm), multiple shoot not found.
(max. 15 cm) and less in multiple shoot
(max. 1 cm).
(max. 4 cm).
(max. 3.2 cm).
Table 8 : IAA 0.5 : 1 Kinetin - Increase in length was in single shoot (max.
17.5 cm), multiple shoot not found.

Note : Growth of root length was found better in all PGR combinations.

92

DISCUSSION

Species – A
In all the combinations during second trial growth of shoot was not as
good as during first trial, it might be due to resting period of Bambusa tulda.

The shoot proliferation and length was extensive in IAA 0.5 : 2 BAP
(Table-4) combination. But in all other combinations the shoot proliferation
was moderate but growth of shoot length was as good as it should be.

In higher combination IAA 0.5 : 4 BAP (Table 7) proper sprouting was
obtained with less percentage.

Species – B
Among all the combinations IAA 0.2 : 0.5 BAP (Table 7) combination
was better for germination and shoot proliferation it is also better for increase
in length of single shoot and multiple shoot.

The combination IAA 0.5 : 4 BAP (Table 6) was also found better in
terms of shoot proliferation, increase in length of single and multiple shoot but
percentage of germination was very less.

There was emergence and better development of root in single shoots
for all the combinations but it was absent in case of multiple shoot.

CONCLUSIONS
Bamboo is a woody perennial evergreen grass having considerable
economic, social and ecological importance. It is an important raw material for
pulp and paper industry. Due to higher demand than that of production of
bamboo there is need to develop proper micropropagation technique to meet
out the existing demand.

Species Bambusa tulda is important for pulp - paper and rayon
industry.

93

Species Dendrocalamus longisphathus is important in terms of higher
edible portion (about 40%), manufacturing of good quality tooth picks and also
elegant to grow in the gardens.

During micropropagation of Bambusa tulda IAA 0.5 : 2 BAP (Table 4)
combination of PGR was found better, for fresh culturing but there is problem
of drying of sprouting explant during subculturing that is why the protocol for
the species is yet not developed.

During micropropagation of Dendrocalamus longispathus IAA 0.2 : 0.5
(Table 7) combination of PGR was found better for fresh culturing and sub
culturing was also found successful.

94

Sample chromatogram of an alkaloid :

RT(min) Peak name Area(mV*sec)
5.298 sample 368.611

Standard chromatogram of reserpine :

RT(min) Peak name Area(mV*sec)
4.643 std 841.338

Peak area of the sample/ µl injection sample wt. of std. (gm/ml)
X X 100
% Conc. = wt. of sample
Peak area of the standard/ µl injection standard (gm/ml)

95

= 368.611/5 x .001 x100
841.338/5 .013
= 3.32%

Conclusion
By comparing graph of sample and standard after injection it is
concluded that the sample is reserpine (alkaloid), which is of 3.32%
concentration.

96

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