Ultra structure of a bacterial cell

Ultra Structure
of
a Bacterial Cell

GISHA GP
MSC BIOTECHNOLOGY
MAHATMA GANDHI UNIVERSITY
KOTTAYAM

The Structure of the Prokaryote Cell
• Small size ( 0.5 to 2um)
• Large surface area to volume ratio
• A variety of shapes
• Outer cell wall- very thick made of specialized
molecules
• Cell membranes may have a different constituency of
molecules from eukaryote cells
• Ribosomes smaller
• No organelles, no nuclear membrane
•1 ds circular loop of DNA

• Procaryotic cells almost always are bounded by a chemically
complex cell wall.
• Inside this wall, and separated from it by a periplasmic space, lies
the plasma membrane.
• The genetic material is localized in a discrete region, the
nucleoid, and is not separated from the surrounding cytoplasm by
membranes.
• Ribosomes and larger masses called inclusion bodies are scattered
about in the cytoplasmic matrix.
• Both gram-positive and gram-negative cells can use flagella for
locomotion.
• In addition, many cells are surrounded by a capsule or slime layer
external to the cell wall.

Cell wall
• The cell wall is the layer, usually fairly rigid, that
lies just outsidethe plasma membrane.
• Give them shape and protect them from osmotic
lysis;
• The cell walls of many pathogens have
components that contribute to their
pathogenicity.
• The wall can protect a cell from toxic substances
and is the site of action of several antibiotics.
• Peptidoglycan-the most important molecule in
the cell walls of bacteria

• The gram-positive cell wall consists of a single
20 to 80 nm thick homogeneous
peptidoglycan or murein layer lying outside
the plasma membrane
• the gram-negative cell wall is quite complex. It
has a 2 to 7 nm peptidoglycan layer
surrounded by a 7 to 8 nm thick outer
membrane.

• Peptidoglycan or murein is an enormous
polymer composed of many identical
subunits. The polymer contains two sugar
derivatives, N-acetylglucosamine and Nacetylmuramic acid (the lactyl ether of Nacetylglucosamine), and several different
amino acids, three of which—D-glutamic
acid, D-alanine, and meso-diaminopimelic acid

Gram + cell wall
• Homogeneous cell wall of gram-positive
bacteria is composed primarily of
peptidoglycan, which often contains a peptide
interbridge
• The teichoic acids are connected to either the
peptidoglycan by a covalent bond with Nacetylmuramic acid or to plasma membrane
lipids are called lipoteichoic acids.

Gram – cell wall
• The outer membrane lies outside the thin
peptidoglycan layer
• The most abundant membrane protein is Braun’s
lipoprotein,covalently joined to the underlying
peptidoglycan and embedded in the outer membrane
by its hydrophobic end.
• constituents of the outer membrane are its
lipopolysaccharides
• outer membrane is more permeable than the plasma
• membrane due to the presence of special porin
proteins

Capsules, Slime Layers, and S-Layers
•

Some bacteria have a layer of material lying outside the cell wall. When the layer is well
organized and not easily washed off, it is called a capsule.

•

A slime layer is a zone of diffuse, unorganized material that is removed easily

•

Many gram-positive and gram-negative bacteria have a regularly structured layer called an Slayer on their surface

•

The S layer has a pattern something like floor tiles and is composed of protein or glycoprotein

•
•

In gram-negative bacteria the S-layer adheres directly to the outer membrane; it is associated
with the peptidoglycan surface in gram-positive bacteria.

•

It may protect the cell against ion and pH fluctuations, osmotic stress, enzymes, or the
predacious bacterium Bdellovibrio. The S-layer also helps maintain the shape and envelope
rigidity of at least some bacterial cells. It can promote cell adhesion to surfaces.

Pili and Fimbriae
• Many gram-negative bacteria have short, fine, hairlike appendages
that are thinner than flagella and not involved in motility. These are
usually called fimbriae
•

Pilus are similar appendages, about 1 to 10 per cell, that differ
from fimbriae in the following ways.

•

Pili often are larger than fimbriae (around 9 to 10 nm in diameter).

• They are genetically determined by sex factors or conjugative
plasmids and are required for bacterial mating.

•

Some bacterial viruses attach specifically to receptors on sex pili at
the start of their reproductive cycle.

Flagella and Motility
• Motile bacteria move by use of flagella
• Threadlike locomotor appendages extending
outward from the plasma membrane and cell
wall.
• They are slender, rigid structures,about 20 nm
across and up to 15 or 20 m long.

 Flagella is a hair like structure.
 Flagellar filaments are made of subunits of a
single protein-flagellin.
The transmission electron microscope studies
have shown that flagellum is composed of three
parts.
 Filament-extend from cell surface to the tip.
 Basal body-embeded in the cell.
 Hook.

Filament is a hollow rigid cylinder made of
flagellin,
Hook is curved portion, slightly wider than
filament.
Basal body is the most complex part of a
flagellum.
It differs in Gram positive and Gram negative
bacteria.

• The basal body of gram negative bacteria has four
rings connected to a central rod.
• A pair of ring embeded in cell membrane(M ring
and S ring) and another pair associated with the
cell wall(L ring and P ring).
 The outer L and P rings associated with
lipopolysaccharide and peptidoglycan
respectively.
 The inner M ring-plasma membrane and S ringnear periplasmic space

• The Gram positive bacteria have only two
rings in their basal body.
The inner M ring-connected to plasma
membrane.
The outer S ring-attached to peptidoglycan.
Since Gram positive bacteria lack the outer
pair of rings, it is assumed that only the inner
rings are essential for flagellar motion.

The Bacterial Endospore
• A number of gram-positive bacteria can form a
special resistant, dormant structure called an
endospore.
• Endospores develop within vegetative bacterial
cells of several genera: Bacillus and Clostridium
(rods), Sporosarcina (cocci), and others.
• Spore formation, sporogenesis or
sporulation, normally commences when growth
ceases due to lack of nutrients.

The Plasma Membrane
• Membranes contain both proteins and lipids
• Bacterial plasma membranes usually have a higher proportion
of protein than do eucaryotic membranes
• lipids form a bilayer in membranes
• Bacterial membranes lack sterols such as cholesterol

• Cell membranes are very thin structures, about 5 to 10 nm
thick

Internal Membrane Systems
• Does not contain complex membranous organelles like
mitochondria or chloroplasts
• Mesosomes are invaginations of the plasma membrane in the
shape of vesicles, tubules, or lamellae
• Thus they may be involved in cell wall formation during
division or play a role in chromosome replication and
distribution to daughter cells.

Inclusion Bodies
• A variety of inclusion bodies, granules of organic or inorganic
material are present in the cytoplasmic matrix
• Used for storage (e.g., carbon compounds, inorganic
substances, and energy), and also reduce osmotic pressure by
tying up molecules in particulate form. for
example, polyphosphate granules, cyanophycin granules, and
some glycogen granules.
• Examples of membrane-enclosed(single layer) inclusion
bodies are poly--hydroxybutyrate granules, some glycogen
and sulfur granules, carboxysomes, and gas vacuoles.

• Cyanophycin granules (present in many cyanobacteria) are
composed of large polypeptides containing approximately
equal amounts of the amino acids arginine and aspartic acid.
• The granules store extra nitrogen for the bacteria.

• Carboxysomes are present in many cyanobacteria, nitrifying
bacteria, and thiobacilli.
• They are polyhedral, about 100 nm in diameter, and contain
the enzyme ribulose- 1,5-bisphosphate carboxylase in a
paracrystalline arrangement.
• They serve as a reserve of this enzyme and may be a site of
CO2 fixation.

• Gas vacuole -organic inclusion body present in many
cyanobacteria , purple and green photosynthetic bacteria, and
a few other aquatic forms such as Halobacterium and
Thiothrix. Gas vacuoles give them buoyancy.
• Gas vacuoles are aggregates of enormous numbers of
small, hollow, cylindrical structures called gas vesicles.
• Gas vesicle walls are composed entirely of a single small
protein. These protein subunits assemble to form
• a rigid enclosed cylinder that is hollow an impermeable to
water but freely permeable to atmospheric gases.

• Polyphosphate granules or volutin granules
• volutin granules function as storage reservoirs for
phosphate, an important component of cell constituents such
as nucleic acids.
• In some cells they act as an energy reserve, and
polyphosphate can serve as an energy source in reactions.
• These granules are sometimes called metachromatic
granules
• Magnetosome is used by some bacteria to orient in the
earth’s magnetic field. These inclusion bodies contain iron in
the form of magnetite

MAGNOTACTIC BACTERIA

Gas vacoules

Ribosomes
• Ribosomes loosely attached to the plasma
membrane. (70S ribosomes)
• Made of both protein and ribonucleic acid
(RNA).
• They are the site of protein synthesis;
• Matrix ribosomes synthesize proteins destined
to remain within the cell,
• Plasma membrane ribosomes make proteins
for transport to the outside.

Nucleoid
• Procaryotic chromosome is located in an irregularly
shaped region called the nucleoid
• composed of about 60% DNA, 30% RNA, and 10%
protein by weight
• procaryotes contain a single circle of doublestranded deoxyribonucleic acid (DNA), but some
have a linear DNA chromosome.

• Many bacteria possess plasmids in addition to their
chromosome.
• These are double-stranded DNA molecules, usually
circular, that can exist and replicate independently of the
chromosome or may be integrated with it(epoisomes)
• In both case they normally are inherited or passed on to the
progeny.
• Plasmid genes can render bacteria drug-resistant, give them
new metabolic abilities, make them pathogenic, or endow
them with a number of other properties.

Ultra structure of a bacterial cell

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Ultra structure of a bacterial cell