Showing posts with label Blood Group Inheritance. Show all posts
Showing posts with label Blood Group Inheritance. Show all posts

Wednesday, 15 May 2019

Chapter 5: Principles of Inheritance & Variation (Part 1)

Inheritance: Process by which character are passed from parents to progeny. Basis of heredity
            Term Genetics: Bateson
Heredity: Transmission of Characters
Variation: Degree by which progeny differs from parents.
Cause: Sexual rep


Exploited by humans for developing high yielding var of plants & animals. E.g. Sahiwal cows from wild cows by artificial selection & domestication.

Mendel: On basis of hybridization exp on garden peas (Pisum sativum -14 chr) for 7 yrs
Work rediscovered 34 yrs later by DeVries, Correns & Tschermak
Unique features of Mendel’s research:
·       Applied math & statistics to study biology
·       Large sample size
·       Continuous experiments on successive generations
  •     Studied visible traits with contrasting characters
Father of Genetics: Mendel

Checkpoint: At this point it is very important to review few terms:
·        Gene vs Allele
·        Homozygous vs Heterozygous
·        Dominant vs Recessive
·        Genotype Vs Phenotype

Make sure that you know them all clearly & confidently before proceeding ahead.


Mendel's Procedure: Artificial/cross pollination using true breeding plants
Selected 14 true breeding plants similar in all respects except 1 contrasting character
Inheritance of one Gene: Monohybrid Cross; Only one allelic pair considered

Dihybrid Cross: Two allelic pairs considered.


Laws of Inheritance: 3
  •  Law of Dominance: In a hybrid where both contrasting alleles present, only 1 factor/allele expresses itself, this is known as dominant allele. The other – recessive
              In F2: dominant : recessive:: 3:1 
  • Principle of segregation: When a pair of contrasting characters present in an organisms, the characters do not mix together, simply stay together. They are separated at the time of gamete formation, so that each gamete will have allele for only 1 contrasting trait.
             Also k/a Law of Purity of Gametes
  • Principle of Independent Assortment: Genes of different characters present together in a plant are not inherited together. They are inherited independent of each other.

A father produces two types of gametes, while a mother produces only 1 type. Which of Mendel’s law is justified by this? State if there are any situations which under normal circumstances show exception to this law.


Cause of Dominance: When one of the alleles in a heterozygous individual is non-functional, i.e. either is not transcribed, or does not produces a functional protein. That allele is recessive. The other functional allele is dominant.
Dominance is relative

Reciprocal Cross: two crosses with same characters taken in to consideration but with reversing the sexes.

Back Cross: Cross of F1 progeny with either of the parent

Test Cross: Crossing of F1 progeny with homozygous recessive parent.
Used to determine whether an individual with dominant trait is homozygous or heterozygous. During Test Cross:
All Tall: Homozygous                                                   Tall: Dwarf=1:1 Heterozygous




When Aa is crossed with aa, what is the genotype and ratio of various genotypes in progeny? Can you give a name for this type of cross?


Reasons for Mendel’s Success:

  •        Self-Fertilizing, easy to grow plant
  •        Diploid plant
  •        7 visible features
  • Focused on few contrasting characters, 1 or 2 at time
  • Kept accurate quantitative records

Post Mendel studies revealed interactions between genes.
Post Mendelism: Mendel stated ‘factors’ (genes) to be discrete units inherited independently of each other.


Gene Interactions of 2 types:
Intragenic (Interallelic): between two alleles, present on same gene locus on two homologous chromosomes. E.g. Incomplete Dominance, Codominance, Multiple Alleles.
Intergenic (Non-Allelic): two or more independent genes present on same or different chromosomes. E.g. epistasis, duplicate genes, complementary genes.
  • Incomplete Dominance: Dominant gene does not completely express itself in heterozygotes. E.g. Mirabilis jalapa,

P: Dom-Red, Rec- White
F1: Pink
F1 genotypic ratio & Phenotypic ratio: 1:2:1

  • Codominance: Alleles expressed equally in F1. 

E.g. Coat colour in Cattle.
P: Black Coat & White Coat
F1: Neither black/white, but fur with both white & black in patches (roan coat colour)
Genotypic & Phenotypic 1:2:1

  • Multiple Alleles: More than 2 alleles for a gene. Located at same locus, in different organisms in a population.

At a time one organism has only 2 forms of these alleles, & a gamete has only one form (??)
e.g. Blood Groups in humans


Blood Groups: ABO type – discovery: Dr. Karl Landsteiner)
Gene I; 3 alleles IA, IB, IO
Any 2 forms present in a person; so the genotype combinations can be:__________, _________, _________, _________, _________, ___________ (Total 6)

IA& IB Are codominant, while  IO is recessive to  IA& IB
On this basis work out the phenotypes from the genotypes you’ve listed above

Thus ABO blood gp is an example of Codominance & Multiple Allelism Cause of Blood Gps: The plasma membrane of the red blood cells has sugar polymers that protrude from its surface and the kind of sugar is controlled by the gene I.

  • Pleiotropism: when one gene controls more than 1 phenotype. 

E.g
·       Sickle Cells anaemia: Gene controls shape of RBC, & O2 carrying efficiency
·       B gene in Pea seeds: 2 forms B, b
Phenotype 1
ü  BB: large starch grains, more efficient starch synthesis
ü  Bb: intermediate size starch grains
ü  bb: small starch grains, less efficient starch synthesis
            Phenotype 2
ü  BB: round seeds
ü  Bb: round seeds
ü  Bb: wrinkled seeds
Can you tell the difference in expression pattern of the two phenotypes ??

Polygenic Inheritance: Poly ______; Genic: _______

Character expression controlled by many genes
3 or more genes have a cumulative effect on a particular character. Each dominant allele expresses a part of the trait. Full trait expression when all dominant alleles present.
e.g. Kernel colour in wheat (2 pairs of genes)
Height in humans (10 or more pairs of genes)

(interestingly shortness is dominant; so more the number of dominant alleles; shorter the person will be). Further height is also influenced by many environmental factors.