Genetic Basis of Inheritance

KISHOR SAWAIKAR
M.SC., M.PHIL., PH. D.

The concept "Like begets like".
• i. Living organisms produce young ones similar to
them.
• ii. A dog gives puppies and a mango tree gives
mango seeds.
• iii. This basic principle of life giving rise to life of
its own kind is called "Like begets like".
• iv. This kind of making one's copies, a
fundamental characteristics of life, becomes
possible due to replication of DNA (genetic
material) and its transmission to next generation.

• i. Heredity: Transmission of characters from
one generation to the next generation is called
heredity.

• ii. Variation: The differences between parents
and offsprings or among the offsprings of the
same parents and among individuals of same
species is called variation.

• iii. Genetics: It is the branch of biology which
deals with the study of heredity and variation.
The term genetics was coined by
• William Bateson in 1906.

Father of Genetics
• Gregor Johann Mendel.

Kingdom: Plantae
(unranked): Angiosperms
(unranked): Eudicots
(unranked): Rosids
Order: Fabales
Family: Fabaceae
Genus: Pisum
Species: P. sativum
Binomial name
Pisum sativum
L.

Nutritional value per 100 g (3.5 oz)
Energy 339 kJ (81 kcal)
Carbohydrates 14.45 g
Sugars 5.67 g
Dietary fiber 5.1 g
Fat 0.4 g
Protein 5.42 g

Vitamins
Vitamin A equiv.beta-carotene
lutein zeaxanthin
(5%)38 μg(4%)
449 μg2477 μg
Thiamine (B1) (23%)0.266 mg
Riboflavin (B2) (11%)0.132 mg
Niacin (B3) (14%)2.09 mg
Vitamin B6 (13%)0.169 mg
Folate (B9) (16%)65 μg
Vitamin C (48%) 40 mg
Vitamin E (1%)
0.13 mg
Vitamin K (24%)24.8 μg

Calcium
(3%) 25 mg
Iron
(11%) 1.47 mg
Magnesium
(9%) 33 mg
Manganese
(20%) 0.41 mg
Phosphorus
(15%) 108 mg
Potassium
(5%) 244 mg
Sodium
(0%) 5 mg
Zinc
(13%) 1.24 mg

Mendelian inheritance
• i. Clone: Organisms produced by asexual
reproduction or plants produced by vegetative
propagation are identical to their parents are
called clones.

ii. Factor: Particle present in the organism which is responsible for the inheritance
and expression of the character.

• iii. Gene: (coined by Johannsen) Specific segment of DNA
which determines a particular character of an organism.
OR
• It is a particular segment of DNA which is responsible for the
inheritance and expression of that character.

iv. Alleles or Allelomorphs: (coined by Bateson)
Two or more alternative forms of a gene present
at the same loci of homologous chromosomes
and controlling the same character are called as
alleles or allelomorphs

• Homorygous: An individual having identical alleles for
a particular character is homozygous for that character.
It is ' pure or true breeding e.g. TT, tt.

• Heterorygous: An individual having dissimilar
alleles for a particular character is heterozygous
for that character. It is a hybrid. e.g. Tt

Genotype: It is the genetic constitution of
an organism. e.g. TT, Tt, tt.

Phenotype: The external appearance of an
organism. e.g. tallness, dwarfness.

Monohybrid cross: A cross between two pure parents differing
in single pair of contrasting character is called monohybrid cross.
The ratio for this cross is 3 : 1.

Dihybrid cross: A cross between two pure parents
differing in two pairs of contrasting characters is called
dihybrid cross. The ratio for such cross is 9 : 3 : 3 : l.

• Monohybrid: It is heterozygous for one trait
and produced by crossing two pure parents
differing in a single pair of contrasting
characters.

Dihybrid: It is heterozygous for two traits and produced
in a cross between two parents differing in
two pairs of contrasting characters
F1 generation:
• The hybrid individuals obtained by a cross between
two pure parents with contrasting characters is
• called F1 generation or first filial generation.
• F2 generation:
• The generation of offsprings obtained by selfing of F1
individuals is called F2 generation or second filial
generation.
• Dominant: The character expressed in F1 generation is
called dominant character.
OR
• It is an allele that expresses even in presence of an
alternative allele.

• Recessive: The character which is not
expressed in F1 generation is called recessive
character.
or
• It an allele which do not expressed in
presence of an alternative allele.
• Offsprings: The individuals produced by the
sexual reproduction are called offsprings.
• Progeny: All offsprings produced by the
parents are called progeny.

• Hybrid: Heterozygous individual produced by
parents having contrasting characters. e.g. Tt.
•
• Character: A visible feature is a character e.g.
height, seed colour.
• Trait: one form of the visible feature e.g.
tallness or dwarfness, yellow or green.

• Homologous chromosomes or Homologues:
• Morphologically, physiologically and
genetically similar chromosomes present in
diploid cells are called homologues or
homologous chromosomes.
• In each pair of homologous chromosome is
maternal and the other is paternal.

• Emasculation: Removal of stamens well
before anthesis is called emasculation. It is
don in bud condition.

• Genome: Entire genetic constitution of an
organism is called genome.
• Pure line: An individual or a group of
individuals (population) that is homozygous or
true breeding for one or more traits.

Punnett square/Checker Board?
• Punnett square is a graphical representation
to calculate the probability of all possible
genotypes and phenotypes of offsprings in a
genetic cross.
• It was developed by Reginald C. Punnett

Dominant and Recessive character

Mendel conducted experiment in
following three steps

• Monohybrid cross: A cross between two pure
parents differing in single pair of contrasting
character is called monohybrid cross. The ratio
for this cross is 3 : 1.

Law of dominance states that "in a cross between two
homozygous organisms differing in a single pair of
contrasting character, the character which is expressed
in the F1 generation is called dominant character and
the character which is not expressed is the recessive
character,,.
e.g. Tallness in pea plant is a dominant character while dwarfness is a recessive
character.

• In a cross between pure tall and pure dwarf
pea plant, only tall character is expressed in all
the individuals of F1 generation.
• Hence it can be inferred that in pea plants,
tallness is the dominant character while
dwarfness is a recessive character.
• Tallness in F1 hybrid is determined by
genotype Tt in which the dominant allele 'T,
suppresses the recessive allele 't' thereby
suppressing its expression in the phenotype.

Law of segregation is also called law of
purity of gametes.
• i. The character present in F1 hybrid has alleles
for both dominant and recessive traits.
• ii. In a heterozygous individual, both of these
forms may be present in a diploid cell lying in
close proximity.
• iii. But they do not affect each other and when
formation of gametes takes place, the two
alleles e.g. T and t would separate. Thus each
gamete is pure for the character.

• Law of segregation states that "when the two
alleles for contrasting character are brought
together in a hybrid union, they do not mix or
contaminate but segregate or separate out from
each other during gamete formation".
• i. Each organism contains two factors for each
trait in its diploid cells and the factors segregate
during the formation of gametes.
• ii.. Each gamete then contains only one factor
from each pair of factors. iii. When fertilization
occurs, the new organism has two factors for
each trait, one from each parent.

• When Mendel crossed a homozygous tall
plant with a homozygous dwarf plant, the
offspring resulted from this cross was found to
be a hybrid tall (F1 generation).
• The hybrid tall thus produced has two alleles
viz. 'T' (tallness) and 't' (dwarfness).
• When this hybrid tall forms the gametes, the
two alleles viz. 'T” and 't' segregate as shown
below:

• The two alleles (contrasting characters) do not
mix, alter or dilute each other and the
gametes that formed are 'pure' for the
characters which they carry.
• Hence, this law is also called the law of purity
of gametes.

Dihybrid: It is heterozygous for two traits and produced in a
cross between two parents differing in two pairs of
contrasting characters

State Mendel's third law of inheritance or law of
independent assortment and explain it with
dihybrid cross
• The law of independent assortment states
that "when two parents differing from each
other in two or more pairs of contrasting
characters are crossed, then the inheritance of
one pair-of character is independent of the
• other pair of character."

• For example, we cross a pure tall, red flowered
pea plant with a pure dwarf white flowered
pea plant, we get 9 tall red, 3 tall white, 3
dwarf red and 1 dwarf white plants in the F2
generation.
• A cross between two homozygous individuals
differing in two characters is called dihybrid
cross

• When the two homozygous parents differing
in two pairs of contrasting traits are crossed,
the inheritance of one pair is independent of
the other. In other words when a Dihybrid
forms gametes, assortment (distribution) of
alleles of different traits is independent of
their original combinations in the parents.

• Many genes are located on one chromosome
i.e. they are linked. therefore, they pass
through gametes in the form of a linkage
group. However recombination are due to the
crossing over that takes place during meiosis.
• Therefore, the law of independent assortment
is applicable only for the traits which are
located on different chromosomes. Thus law
of independent assortment is not universally
applicable.

Distinguish between monohybrid cross
and dihybrid cross.

What is a back cross?
• The cross between F1 hybrid and any one of
the parents is called back cross

What is a test cross?
• The cross between F1 hybrid and the recessive
parent is called test cross.

When is back cross not a test cross?
• A back cross with dominant parent is not a
test cross.

Deviations from Mendelian ratio

Genetic Basis of Inheritance

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