Biology Notes for Class 12

Chapter 5: Principles of Inheritance and Variation

Chapter Summary

           Ø Genetics is a branch of biology which deals with principles of inheritance and its practices. Progeny resembling the parents in morphological and physiological features has attracted the attention of many biologists. Mendel was the first to study this phenomenon systematically. While studying the pattern of inheritance in pea plants of contrasting characters, Mendel proposed the principles of inheritance, which are today referred to as ‘Mendel’s Laws of Inheritance’. He proposed that the ‘factors’ (later named as genes) regulating the characters are found in pairs known as alleles. He observed that the expression of the characters in the offspring follow a definite pattern in different–first generations (F1 ), second (F2 ) and so on. Some characters are dominant over others. The dominant characters are expressed when factors are in heterozygous condition (Law of Dominance). The recessive characters are only expressed in homozygous conditions. The characters never blend in heterozygous condition. A recessive character that was not expressed in heterozygous conditon may be expressed again when it becomes homozygous. Hence, characters segregate while formation of gametes (Law of Segregation).

          Ø Not all characters show true dominance. Some characters show incomplete, and some show co-dominance. When Mendel studied the inheritance of two characters together, it was found that the factors independently assort and combine in all permutations and combinations (Law of Independent Assortment). Different combinations of gametes are theoretically represented in a square tabular form known as ‘Punnett Square’. The factors (now known as gene) on chromosomes regulating the characters are called the genotype and the physical expression of the chraracters is called phenotype.

           Ø After knowing that the genes are located on the chromosomes, a good correlation was drawn between Mendel’s laws : segregation and assortment of chromosomes during meiosis. The Mendel’s laws were extended in the form of ‘Chromosomal Theory of Inheritance’. Later, it was found that Mendel’s law of independent assortment does not hold true for the genes that were located on the same chromosomes. These genes were called as ‘linked genes’. Closely located genes assorted together, and distantly located genes, due to recombination, assorted independently. Linkage maps, therefore, corresponded to arrangement of genes on a chromosome.

         Ø Many genes were linked to sexes also, and called as sex-linked genes. The two sexes (male and female) were found to have a set of chromosomes which were common, and another set which was different. The chromosomes which were different in two sexes were named as sex chromosomes. The remaining set was named as autosomes. In humans, a normal female has 22 pairs of autosomes and a pair of sex chromosomes (XX). A male has 22 pairs of autosomes and a pair of sex chromosome as XY. In chicken, sex chromosomes in male are ZZ, and in females are ZW.

          Ø Mutation is defined as change in the genetic material. A point mutation is a change of a single base pair in DNA. Sickle-cell anemia is caused due to change of one base in the gene coding for beta-chain of hemoglobin. Inheritable mutations can be studied by generating a pedigree of a family. Some mutations involve changes in whole set of chromosomes (polyploidy) or change in a subset of chromosome number (aneuploidy). This helped in understanding the mutational basis of genetic disorders. Down’s syndrome is due to trisomy of chromosome 21, where there is an extra copy of chromosome 21 and consequently the total number of chromosome becomes 47. In Turner’s syndrome, one X chromosome is missing and the sex chromosome is as XO, and in Klinefelter’s syndrome, the condition is XXY. These can be easily studied by analysis of Karyotypes.

PRINCIPLES OF INHERITANCE AND VARIATION:

Ø  Genetics: deals with the inheritance, as well as the variation of characters from parents to offsprings.

Ø  Inheritance: is the process by which characters are passed on from parent to progeny.

Ø  Variation: is the degree by which progeny differ from their parents.

5.1 MENDEL’S LAWS OF INHERITANCE:

Ø  Gregor Mendel. Conducted hybridization experiments on garden peas for seven years (1856 – 1863) and proposed laws of inheritance.

Ø  Mendel conducted artificial pollination/cross pollination experiments using several true-breeding pea lines.

Ø  A true breeding line is one that, having undergone continuous self-pollination for several generations.

Ø  Mendel selected 14 true-breeding peas’ plant varieties, as pair’s which were similar except for one character with contrasting traits.

  • True breed selected by Mendel
  • Stem height- Tall / dwarf
  • Flower color- Violet/white
  • Flower position – Axial / terminal
  • Pod shape- Inflated / beaded or constricted
  • Pod color- Green / yellow
  • Seed color- Yellow/ green
  • Seed shape – round / wrinkled

5.2 INHERITANCE OF ONE GENE:

Ø  Mendel crossed tall and dwarf pea plants to study the inheritance of one gene.

Ø  He collected the seeds produced as a result of this cross and grew them to generate plants of the first hybrid generation. This generation is called filial progeny or the F1.

Ø  Mendel observed that all the F1 progeny plants ere tall, like one of its parents; none were dwarf.

Ø  He made similar observations for the other pairs of traits – he found that the F1 always resembled either one of the parents, and that the trait of the other parent was not seen in them.

Ø  Mendel then self – pollinated the tall F1 plants and to his surprise found that in the F2 generation some of the offsprings were ‘dwarf; the character that was not seen in the F1 generation was now expressed.

Ø  The proportion of plants that were dwarf was 1/4th of the F2 plants while 3/4th of the F2 plants were tall.

Ø  The tall and dwarf traits were identical to their parental type and did not show any blending, that is all the offsprings were either tall or dwarf, none were of in between height.

Ø  Similar results were obtained with the other traits that he studied: only one of the parental traits was expressed in the F1 generation while at the F2 stage both the traits were expressed in the proportion of 3:1.

Ø  The contrasting traits did not show any blending at either F1 or F2 stage.

Mendel’s proposition:

Ø  Mendel proposed that something was being stably passed down, unchanged, from parent to offspring through the gametes, over successive generations. He called these things as ‘factors’.

Ø  Now a day we call them as genes.

Ø  Gene is therefore are the units of inheritance.

Ø  Genes which codes of a pair of contrasting traits are known as alleles, i.e. they are slightly different forms of the same gene.

Alphabets used:

Ø  Capital letters used for the trait expressed at the F1 stage.

Ø  Small alphabet for the other trait.

Ø  ‘T’ is used for Tall and‘t’ is used for dwarf.

Ø  ‘T’ and ‘t’ are alleles of each other.

Ø  Hence in plants the pair of alleles for height would be TT. Tt. or tt.

Ø  In a true breeding tall   or   dwarf   pea   variety   the   allelic   pair   of   genes   for   height are identical or homozygous, TT and tt respectively.

Ø  TT and tt are called the genotype.

Ø  Tt plant is heterozygous for genes controlling one character (height).

Ø  Descriptive terms tall and dwarf are the phenotype.

Test cross:

Ø  When F1 hybrid is crossed back with the recessive parent, it is known as test cross.

Ø  It is used to know the genotype of the given plant/animal.

5.2.1 Law of Dominance:

Ø  Characters are controlled by discrete units called factors.

Ø  Factors occur in pairs.

Ø  In a dissimilar pair of factors one member of the pair dominates (dominant) the other (recessive).

5.2.2 Law of Segregation:

Ø  The alleles do not show any blending and that both the characters are recovered as such in the F2 generation though one of these is not seen at the F1 stage.

Ø  The parents contain two alleles during gamete formation; the factors or alleles of a pair segregate or

§  separate from each other such that a gamete receives only one of the two factors.

Ø  Homozygous parent produces all gametes that are similar i.e contain same type of allele.

Ø  Heterozygous parents’ produces two kinds of gametes each having one allele with equal proportion.

5.2.2.1 Incomplete dominance:

Ø  When a cross between two pure breed is done for one contrasting character, the F1 hybrid phenotype dose not resemble either of the two   parents   and   was   in   between   the   two, called incomplete dominance.

Ø  Inheritance of flower color in the dog flower (snapdragon orAntirrhinum sp.) is a good example of incomplete dominance.

Ø  F2 generation phenotypic ratio is 1:2:1 in stead of 3:1 as Mendelian monohybrid cross.

5.2.2.2 Co – dominance:

Ø  F1 resembled either of the two parents (complete dominance).

Ø  F1 offspring was in-between of two parents (incomplete dominance).

Ø  F1 generation resembles both parents side by side is called (co-dominance).

Ø  Best example of co-dominance is the ABO blood grouping in human.

Ø  ABO blood group is controlled by the gene I.

Ø  The plasma membrane of the RBC has sugar polymers (antigen) that protrude from its surface and the kind of sugar is controlled by the gene-I.

Ø  The gene I has three alleles I A,I B  and i.

Ø  The alleles I A and I B produce a slightly different form of sugar while allele i doesn’t produce any sugar.

Ø  Each person possesses any two of the three I gene alleles.

Ø  I A and I B are completely dominant over i.

Ø  When I A, and I B present together they both express their own types of sugar; this because of co- dominance. Hence red blood cells have both A and B type sugars. 

 

Multiple Alleles:

Ø  Example of ABO blood grouping produces a good example of multiple alleles.

Ø  There are more than two i.e. three allele, governing the same character.

A single gene product may produce more than one effect:

Ø  Starch synthesis in pea seeds is controlled by one gene.

Ø  It has two alleles B and b.

Ø  Starch is synthesized effectively by BB homozygote and therefore, large starch grains are produced.

Ø  The ‘bb’ homozygous has less efficiency hence produce smaller grains.

Ø  After maturation of the seeds, BB seeds are round and the bb seeds are wrinkle.

Ø  Heterozygous (Bb) produce round seed and so B seems to be dominant allele, but the starch grains produced are of intermediate size.

Ø  If starch grain size is considered as the phenotype, then from this angle the alleles show incomplete dominance.

5.3 NHERITANCE OF TWO GENES:

5.3.1 Law of independent Assortment:

Ø  When two characters (dihybrid) are combined in a hybrid, segregation of one pair of traits is independent of the other pair of traits.

5.3.2 CHROMOSOMAL THEORY OF INHERITANCE:

Why Mendel’s theory was remained unrecognized?

Ø  Firstly communication was not easy in those days and his work could not be widely publicized.

Ø  Secondly his concept of genes (or factors, in Mendel’s word) as stable and discrete units that controlled the expression of traits and of the pair of alleles which did not’ blend’ with each other, was not accepted by his contemporaries as an explanation for the apparently continuous variation seen in nature.

Ø  Thirdly Mendel’s approach of using mathematics to explain biological phenomena was totally new and unacceptable to many of the biologists of his time.

Ø  Finally he could not provide any physical proof for the existence of factors.

Rediscovery of Mendel’s result:

Ø  1990 three scientists (deVries, Correns and von Tschermak) independently rediscovered Mendel’s result on the inheritance of character.

Chromosomal theory of inheritance:

Ø  Proposed by Walter Sutton and Theodore Bovery in 1902.

Ø  They work out the chromosome movement during meiosis.

Ø  The behavior of chromosomes was parallel to the behavior of genes and used chromosome movement to explain Mendel’s laws.

Ø  Sutton united the knowledge of chromosomal segregation with Mendelian principles and called it the chromosomal theory of inheritance.

  • Chromosome and genes are present in pairs in diploid cells.
  • Homologous chromosomes separate during gamete formation (meiosis)
  • Fertilization restores the chromosome number to diploid condition.
  • The chromosomal theory of inheritance claims that, it is the chromosomes that segregate and assort independently.

Experimental verification of chromosomal theory:

Ø  Experimental verification of chromosomal theory of inheritance by Thomas Hunt Morgan and his colleagues.

Ø  Morgan worked with tiny fruit flies, Drosophila melanogaster.

Why Drosophila?

Ø  Suitable for genetic studies.

Ø  Grown on simple synthetic medium in the laboratory.

Ø  They complete their life cycle in about two weeks.

Ø  A single mating could produce a large number of progeny flies.

Ø  Clear differentiation of male and female flies

Ø  Have many types of hereditary variations that can be seen with low power microscopes.

5.3.3 Linkage and Recombination:

Ø  Morgan hybridized yellow bodied, white eyed females to brown-bodied, red eyed male and intercrossed their F1 progeny.

Ø  He observed that the two genes did not segregate independently of each other and the F2 ratio deviated very significantly from 9:3:3:1 ratio (expected when the two genes are independent).

Ø  When two genes in a dihybrid cross were situated on the same chromosome, the proportion of parental gene combinations was much higher than the non-parental type.

Ø  Morgan attributed this due to the physical association or linkage of the two genes and coined the term linkage.

Ø  Linage: physical association of genes on a chromosome.

Ø  Recombination: the generation of non-parental gene combinations.

Ø  Morgan found that even when genes were grouped on the same chromosome, some genes were very tightly linked (showed very low recombination) while others were loosely linked (showed higher recombination).

Ø  The genes white and yellow were very tightly linked and showed 1.3 percent recombination.

Ø  The genes white and miniature wing showed 37.2 percent recombination, hence loosely linked.

Ø  Alfred Sturtevant used the frequency of recombination between gene pairs on the same chromosome as a measure of the distance between genes and ‘mapped’ their position on the chromosome.

5.4 POLYGENIC INHERITANCE:

Ø  Human have no distinct tall or short instead a whole range of possible heights.

Ø  Such traits are generally controlled by three or more genes and are thus called polygenic trait.

Ø  Besides the involvement of multiple genes polygenic inheritance also takes into account the influence of environment.

Ø  Human skin color is another classic example of polygenic inheritance.

Ø  In a polygenic trait the phenotype reflects the contribution of each allele i.e. the effect of each allele is additive.

Ø  Assume that three genes A, B, C control the skin colour in human.

Ø  Dominant forms A, B; AND C responsible for dark skin colour and the recessive forms a, b, c for light color of the skin.

Ø  Genotype with dominant alleles (AABBCC) will have darkest skin color.

Ø  Genotype with recessive alleles (aabbcc) will have lightest skin colour.

Ø  Other combinations always with intermediate colour.

5.5 PLEIOTROPY:

Ø  A single gene can exhibit multiple phenotypic expression, such gene is called pleiotropic gene.

Ø  The mechanism of pleiotropy in most cases is the effect of a gene on metabolic pathways which contributes towards different phenotypes.

Ø  Phenylketonuria a disease in human is an example of pleiotropy.

Ø  This disease is caused due to mutation in the gene that code for the enzyme phenyl alanine hydroxylase.

Ø  Phenotypic expression characterized by:-

  • Mental retardation
  • Reduction in hairs.
  • Reduction in skin pigmentation.

5.6 SEX DETERMINATION:

Ø  Henking (1891) traced specific nuclear structure during spermatogenesis of some insects.

Ø  50 % of the sperm received these specific structures, whereas 50% sperm did not receive it.

Ø  Henking gave a name to this structure as the X-body.

Ø  X-body of Henking was later on named as X-chromosome.

5.6.1 Sex-determination of grass hopper:

Ø  Sex-determination in grasshopper is XX-XO type.

Ø  All egg bears one ‘X’ chromosome along with autosomes.

Ø  Some sperms (50%) bear’s one ‘X’ chromosome and 50% do not.

Ø  Egg fertilized with sperm (with ‘X’ chromosome) became female (22+XX).

Ø  Egg fertilized with sperm (without ‘X’ chromosome) became male (22 + X0)

5.6.2 Sex determination in insects and mammals (XX-XY type):

Ø  Bothe male and female has same number of chromosomes.

Ø  Female have autosomes and a pair of X chromosomes. (AA+ XX)

Ø  Male have autosomes and one large ‘X’ chromosome and one very small ‘Y-chromosomes. (AA+XY)

Ø  This is called male heterogammety and female homogamety.

5.6.3 Sex determination in birds:

Ø  Female birds have two different sex chromosomes designated as Z and W.

Ø  Male birds have two similar sex chromosomes and called ZZ.

Ø  Such type of sex determination is called female heterogammety and male homogamety.

5.6.4 Sex determination in Honey bee:

Ø  Sex determination in honey bee based on the number of sets of chromosomes an individual receives.

Ø  An offspring formed from the fertilization of a sperm and an egg developed into either queen (female) or worker (female).

Ø  An unfertilized egg develops as a male (drone), by means of parthenogenesis.

Ø  The male have half the number of chromosome than that of female.

Ø  The female are diploid having 32 chromosomes and males are haploid i.e. having 16 numbers of chromosomes.

Ø  This is called haplodiploid sex determination system.

Ø  Male produce sperms by mitosis, they don not have father   and   thus   cannot   have   sons,   but have grandsons.

5.7 MUTATION:

Ø  Mutation is a phenomenon which results in alteration of DNA sequences and consequently results in changes in the genotype and phenotype of an organism.

Ø  In addition to recombination, mutation is another phenomenon that leads to variation in DNA.

Ø  Loss (deletion) or gain (insertion/duplication) of a segment of DNA results in alteration in chromosomes.

Ø  Since genes are located on the chromosome, alteration in chromosomes results in abnormalities or aberration.

Ø  Chromosomal aberrations are commonly observed in cancerous cells.

Ø  Mutations also arise due to change in a single base pair of DNA. This is known as point mutation. E.g. sickle cell anemia.

Ø  Deletion and insertions of base pairs of DNA causes frame shift mutations.

5.8 GENETIC DISORDERS:

5.8.1 Pedigree Analysis:

Ø  Analysis of traits in several of generations of a family is called the pedigree analysis.

Ø  In the pedigree analysis the inheritance of a particular trait is represented in the family tree over generations.

Ø  Genetic disorders grouped into two categories –

  • Mendelian disorder
  • Chromosomal disorder

5.8.2 Mendelian disorder

5.8.2.1 Autosomal Dominant:

Ø  Affected individuals have at least one affected parent

Ø  The phenotype generally appears every generation

Ø  Two unaffected parents only have unaffected offspring

Ø  Traits are controlled by dominant genes

Ø  Both males and females are equally affected

Ø  Traits do not skip generations

Ø  e.g. polydactyly, tongue rolling ability etc

5.8.2.2 Autosomal recessive:

Ø  Unaffected parents can have affected offspring

Ø  Traits controlled by recessive genes and

Ø  Appear only when homozygous

Ø  Both male and female equally affected

Ø  Traits may skip generations

Ø  3:1 ratio between normal and affected.

Ø  Appearance of affected children from normal parents (heterozygous)

Ø  All children of affected parents are also affected.

Ø  e.g.- Albinism, sickle cell anaemia etc.
Ø  Mendelian disorders are mainly determined by alteration or mutation in the single gene.

Ø  Obey the principle of Mendelian inheritance during transmission from one generation to other.

Ø  Can be expressed in pedigree analysis.

Ø  E.g. Haemophilia, colorblindness, Cystic fibrosis, Sickle cell anemia, Phenylketonuria, Thalasemia etc.

5.8.2.3 Hemophilia:

Ø  In this disease a single protein that is a part of the cascade of proteins involved in the clotting of blood is affected. Due to this in an affected individual a simple cut will result in non-stop bleeding.

  • Sex linked recessive disease.
  • The diseases transmitted from unaffected carrier female to some of the male progeny.
  • Female becoming hemophilic is extremely rare because mother of such a female at least carrier and the father should be hemophilic.
  • Affected transmits the disease only to the son not to the daughter.
  • Daughter can receive the disease from both mother and father.

5.8.2.4 Sickle cell anaemia:

Ø  The defect is caused due to substitution of Glutamic acid (Glu) by Valine (Val) at the sixth position of the beta globin chain of the haemoglobin molecule.

Ø  Substitution of amino acid takes place due to the single base substitution at the sixth codon of the beta

Ø  globin gene from GAG to GUG.

Ø  The mutant haemoglobin molecule undergoes polymerization under low oxygen tension causing the change in the shape of the RBC from biconcave disc to elongated sickle like structure.

Ø  This is an autosomes linked recessive trait.

Ø  Transmitted from parents to the offspring when both the parents are carrier for the gene (heterozygous).

Ø  This disease is controlled by single pair of allele, HbA, and HbS.

Ø  There are three possible genotypes (HbA HbA, HbA HbS, and HbSHbS.

Ø  Only homozygous individuals for HbS (HbS HbS) show the diseased phenotype.

Ø  Heterozygous (HbA HbS) individuals appear apparently unaffected but they are carrier of the disease as there is 50 percent probability of transmission of the mutant gene to the progeny.

5.8.2.5 Phenylketonuria:

Ø  Autosomal recessive trait.

Ø  Inborn error of metabolism.

Ø  The affected individual lack one enzyme called phenyl alanine hydroxylase that converts the amino acid phenyl alanine to tyrosine.

Ø  In the absence of the enzyme phenyl alanine accumulated and converted into phenylpyruvic acid and other derivatives.

Ø  Accumulation of these results in mental retardation.

Ø  These derivatives excreted through kidney.

5.8.3 Chromosomal disorders:

Ø  Caused due to absence or excess or abnormal arrangement of one or more chromosome.

Ø  Failure of segregation of chromatids during cell division cycle results in the gain or loss of chromosome(s), called Aneuploidy.

Ø  Failure of cytokinesis after telophase stage of cell division results in an increase in a whole set of chromosome in an organism and this phenomenon is called polyploidy.

Ø  Trisomy: additional copy of a  chromosome  may  be included in an individual (2n+1).

Ø  Monosomy: an individual may lack one of any one pair of chromosomes (2n-1)

5.8.3.1 Down syndrome:

Ø  Caused due to presence of an additional copy of the chromosome number 21 (trisomy of 21).

Ø  This disorder was first described by Langdon Down (1866).

  • Short stature with small round head.
  • Furrowed tongue
  • Partially opened mouth
  • Palm is broad with characteristic palm crease.
  • Physical, psychomotor and mental development is retarded.

5.8.3.2 Klinefelter’s syndrome:

Ø  Caused due to the presence of an additional copy of  X-chromosome resulting into a karyotype of 47, (44+XXY).

  • Overall masculine development.
  • Also develop feminine character (development of breast i.e. Gynaecomastia)
  • Individuals are sterile.

5.8.3.3 Turner’s syndrome:

Ø  Caused due to the absence of one of the X- chromosomes i.e. 45 (44 + X0).

  • Such females are sterile as ovaries are rudimentary.
  • Lack of other secondary sexual characters.

Disclaimer: All contents are originally prepared by Shri K C Meena Ji, Principal, KVS. 

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