Class 10 Science
Chapter 9 Heredity and Evolution
Introduction
→ Genetics deals with the study of Heredity and Variation.
→ The transmission of characters/traits from one generation to the next generation is called Heredity.
→ The differences in the characters/traits between the parent and offspring is called Variation.
Types of Variations
→ Variation are of two types:
(i) Somatic Variation
(ii) Gametic Variation
• Somatic Variation
→ It takes place in the body cell.
→ It is neither inherited nor transmitted.
→ It is also known as acquired traits.
→ Examples: cutting of tails in dogs, boring of pinna etc.
• Gametic Variation
→ Takes place in the gametes/Reproductive cells.
→ Inherited as well as transmitted.
→ Also known as inherited traits.
→ Example: human height, skin colour.
Accumulation of Variation during Reproduction
→ Variation occurs during reproduction whether organisms multiply sexually or asexually.
Variations in Asexual Reproduction
→ Variations are fewer.
→ Occurs due to small inaccuracies in DNA copying(Mutation).
Variations in Sexual Reproduction
→ Variations are large.
→ Occurs due to crossing over, separation of chromosomes, mutation.
Importance of Variation
→ Depending upon the nature of variations different individuals would have different kinds of advantage.
Example, Bacteria that can withstand heat will survive better in a heat wave.
→ Main advantage of variation to species is that it increases the chances of its survival in a changing environment.
→ Free ear lobes and attached ear lobes are two variants found in human populations.
Mendel and His Work on Inheritance
→ Gregor Johann Mendel (1822 & 1884) started his experiments on plant breeding and hybridisation. He proposed the laws of inheritance in living organisms.
→ Mendel was known as Father of Genetics.
→ Plant selected by Mendel: Pisum sativum (garden pea). He used a number of contrasting characters for garden pea
→ First-generation or F1 progeny are no ‘medium-height’ plants. All plants were tall.
→ Second-generation or F2 are progeny (descendant) of the F1 tall plants are not all tall.
→ Both the tallness and shortness traits were inherited in the F1 plants, but only the tallness trait was expressed. Thus, two copies of the trait are inherited in each sexually reproducing organism.
→ These two may be identical or may be different depending on the parentage.
Pure or homozygous condition
(TT, tt) : Both are dominant traits, Both are recessive alleles
Hetrozygous condition (Hybrid)
Tt : One is dominant, one ris ecessive trait
→ Phenotypic ratio: 3 : 1 (Three tall and one short)
→ Genotypic ratio : 1 : 2 : 1 (TT-one, Tt-two, tt-one)
Phenotype means Physical appearance either they are Tall or Short.Genotype means Genetic make up that are TT, Tt or tt.
Observations of Monohybrid Cross
(i) All F1 progeny were tall, no medium height plant. (Half way characteristic)
(ii) F2 progeny ¼ were short, ¾ were tall.(iii) Phenotypic ratio F2 – 3 : 1 (3 tall : 1 short)
Conclusions
→ TT and Tt both are tall plants while tt is a short plant.
→A single copy of T is enough to make the plant tall, while both copies have to be ‘t’ for the plant to be short.
→ Characters/traits like ‘T’ are called dominant trait (because it express itself) and ‘t’ are recessive trait (because it remains suppressed).
Dihybrid Cross
A cross between two plants having two pairs of contrasting characters is called dihybrid cross.
• Parent → Round green × Wrinkled yellow
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Phenotypic Ratio
Round, yellow : 9
Round, green : 3
Wrinkled, yellow : 3
Wrinkled, green : 1
Observations
(i) When RRyy was crossed with rrYY in F1 generation all were Rr Yy round and yellow seeds.
(ii) Self pollination of F1 plants gave parental phenotype and two mixtures (recombinants round yellow and wrinkled green) seeds plants in the ratio of 9 : 3 : 3 : 1.
Conclusions
→ Round and yellow seeds are Dominant characters.
→ Occurrence of new phenotype combinations show that genes for round and yellow seeds are inherited independently of each other.
How do these traits get expressed
→ Cellular DNA is the information source for making proteins in the cell.
→ A section of DNA that provides information for one protein is called the gene for that protein.
→ Plant height can thus depend on the amount of a particular plant hormone. The amount of the plant hormone made will depend on the efficiency of the process for making it.
• Cellular DNA (Information source)
→ For synthesis of Proteins (Enzyme)
→ Works efficiently → More Hormone
→ produced Tallness of plant
Therefore, genes control characteristics/traits.
Sex Determination
Determination of sex of an offspring is known as Sex Determination.
Factors responsible for Sex Determination
→ Environmental and Genetic factors are responsible for sex determination.
• Environmental
→ In some animals, the temperature at which the fertilized eggs are kept decides the gender. Example: Turtle
• Genetic
In some animals like humans gender or individual is determined by a pair of chromosomes called sex chromosome.
XX – Female
XY – Male
Sex Chromosomes
→ In human beings, there are 23 pairs of chromosome.
→ Out of these 22 chromosomes pairs are called autosomes and the last pair of chromosome that help in deciding gender of that individual is called sex chromosome.
XX – Female
XY – Male
→ This shows that half the children will be boys and half will be girls. All children will inherit an X chromosome from their mother regardless whether they are boys or girls.
→ Thus, sex of children will be determined by what they inherit from their father, and not from their mother.
Evolution
Evolution is the sequence of gradual changes which takes place in the primitive organisms, over millions of years, in which new species are produced.
Variations that resulted in formation of new species occurred basically due to errors in DNA copying as well as due to sexual reproduction.
An Illustration to show variations in a population:
Situation I (Group of red and green beetles)
Colour variation arises during reproduction
All beetles red except one that is green
→ Crows feed on red beetle→ No. of beetles reducesOne beetle green→ Progeny beetles green→ Crows could not feed on green beetles as they got camouflaged (hide) in green bushes→ Number of green bettles increases
Conclusion
→ Green beetles got the survival advantage or they were naturally selected as they were not visible in green bushes.
→ This natural selection is exerted by crows resulting in adaptations in the beetles to fit better in their environment.
Situation II (Group of red and blue beetles)
Reproduction in group of red beetles → All beetles are red except one that is blue → Number of red beetles increases as they reproduces → One blue beetle reproduces and no. of blue beetles also increases → Crows can see both blue and red beetles and can eat them → Number reduces but still red beetles are more and blue ones are few → Suddenly elephant comes and stamps on the bushes → Now beetles left are mostly blue
Conclusion
→ Blue beetles did not get survivals advantage. Elephant suddenly caused major havoc in beetles population otherwise their number would have been considerably large.
→ From this we can conclude that accidents can change the frequency of some genes even if they do not get survival advantage. This is called genetic drift and it leads to variation.
Situation III (Group of red beetles and Bushes)
Group of red beetles → Habitat of beetles (bushes) suffer from plant disease → Average weight of beetles decreases due to poor nourishment → Number of beetles kept on reducing → Later plant disease gets eliminated → Number and average weight of beetles increases again
Conclusion
No genetic change has occurred in the population of beetle. The population gets affected for a short duration only due to environmental changes.
Acquired and Inherited Traits
Ways by which Speciation takes place
Speciation takes place when variation is combined with geographical isolation.
(i) Gene flow: Occurs between population that are partly but not completely separated.
(ii) Genetic drift: It is the random change in the frequency of alleles (gene pair) in a population over successive generations.
Genetic drift takes place due to:
→ Severe changes in the DNA
→ Change in number of chromosomes
(iii) Natural selection: The process by which nature selects and consolidate those organisms which are more suitable adapted and possesses favourable variations.
(iv) Geographical isolation: It is caused by mountain ranges, rivers etc. Geographical isolation leads to reproductive isolation due to which there is no flow of genes between separated groups of population.
Evolution and Classification
Both evolution and classification are interlinked.
→ Classification of species is reflection of their evolutionary relationship.
→ The more characteristic two species have in common the more closely they are related.
→ The more closely they are related, the more recently they have a common ancestor.
→ Similarities among organisms allow us to group them together and to study their characteristic.
Evidences of Evolution
(i) Homologous Organs (Morphological and anatomical evidences).
→ These are the organs that have same basic structural plan and origin but different functions.
→ Homologous organs provides evidence for evolution by telling us that they are derived from the same ancestor.
example: forelimb of horse (running), winds of bat (flying), paw of a cat (walk/scratch/attack)
(iii) Fossils: (Paleontological evidences)
(i) From wild cabbage many varieties like broccoli, cauliflower, red cabbage, kale, cabbage and kohlrabi were obtained by artificial selection.
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