𧬠What is Genetics?
Genetics is a branch of biology that studies how traits are passed from one generation to the next and why there is variation among individuals of the same species[1].
Core Concepts of Genetics:
1. Heredity: Transmission of traits (characters) from parents to offspring.
2. Variation: Differences in traits between individuals of the same species.
Historical Note: The term "Genetics" was coined by William Bateson in 1905[1].
PYQ Corner - Genetics Basics
- Who developed Punnett Square? (CBSE 2007)[2]
- Why do certain genes tend to be inherited together in a cell at the time of cell division? (CBSE 2008)[2]
- What is sex chromosome complement of male bird? (CBSE)[2]
π¨βπ¬ Gregor Mendel - The Father of Genetics
Gregor Johann Mendel, an Austrian monk, laid the foundation of modern genetics through his experiments on pea plants (Pisum sativum) from 1856β1863[1].
His Work:
β’ Published as "Experiments in Plant Hybridisation" in 1865
β’ Rediscovered in 1900 by de Vries, Correns, and Tschermak
Why Pea Plants (Pisum sativum)?
Mendel chose pea plants for the following reasons[1]:
- Short life cycle β Fast growth and quick reproduction
- Large number of seeds per plant
- Distinct contrasting traits (e.g., tall vs. dwarf)
- Self-pollinating nature (ensures purity), yet can be cross-pollinated manually
- Availability of many true breeding varieties
PYQ Corner - Mendel's Work
- Mention the advantages of selecting a pea plant for the experiment by Mendel[8]
- Mendel published his work on inheritance of characters in 1865, but it remained unrecognised till 1900. Give three reasons for the delay in accepting his work (CBSE 2014)[2]
Mendel's Seven Characters in Pea Plant
| Character | Dominant Trait | Recessive Trait |
|---|---|---|
| Stem Height | Tall | Dwarf |
| Seed Shape | Round | Wrinkled |
| Seed Color | Yellow | Green |
| Pod Shape | Inflated | Constricted |
| Pod Color | Green | Yellow |
| Flower Position | Axial | Terminal |
| Flower Color | Violet | White |
π Basic Genetic Terms
| Term | Definition | Example |
|---|---|---|
| Gene | Unit of inheritance, a segment of DNA that codes for a trait | Gene for plant height |
| Allele | Alternate forms of a gene | T (tall) and t (dwarf) |
| Homozygous | Identical alleles | TT or tt |
| Heterozygous | Different alleles | Tt |
| Genotype | Genetic makeup | TT, Tt, tt |
| Phenotype | Observable trait | Tall or Dwarf |
PYQ Corner - Basic Terms
- Differentiate between Dominance and Recessive; Homozygous and Heterozygous; Monohybrid and Dihybrid[8]
- Define the respective pattern of inheritance where F1 phenotype: (i) does not resemble either of the two parents and is in between the two (ii) resembles only one of the two parents (CBSE 2012)[2]
βοΈ Mendel's Laws of Inheritance
1. Law of Dominance
In heterozygotes, only one trait (dominant) is expressed[1].
Key Points:
β’ Characters are controlled by discrete units called factors
β’ Factors occur in pairs
β’ In a dissimilar pair, one member dominates (dominant) the other (recessive)
2. Law of Segregation
Alleles separate during gamete formation. Each gamete receives only one allele of each gene[1].
3. Law of Independent Assortment
Genes for different traits segregate independently during gamete formation[1].
PYQ Corner - Mendel's Laws
- State the law of independent assortment. Using Punnett square, demonstrate the law of independent assortment in a dihybrid cross involving two heterozygous parents (CBSE 2010)[2]
- Name and state the law that can be derived from this cross and not from a dihybrid cross (CBSE 2012)[2]
π¬ Mendel's Monohybrid Cross
A cross between parents differing in one character (e.g., Tall vs Dwarf)[1].
Example: Tall (TT) Γ Dwarf (tt)
F1 Generation: All Tall (Tt) - 100%
F2 Generation:
β’ Phenotypic Ratio: 3 Tall : 1 Dwarf
β’ Genotypic Ratio: 1 TT : 2 Tt : 1 tt
PYQ Corner - Monohybrid Cross
- When a tall pea plant was selfed, it produced one-fourth of its progeny as dwarf. Explain with the help of a cross (CBSE 2010)[2]
- Write the possible genotypes Mendel got when he crossed F1 tall pea plants with dwarf pea plants (CBSE 2012)[2]
- Why in a test cross, did Mendel cross a tall pea plant with a dwarf pea plant only? (CBSE 2012)[2]
π¬ Mendel's Dihybrid Cross
A cross between parents differing in two characters[1].
Example: Round Yellow (RRYY) Γ Wrinkled Green (rryy)
F1 Generation: All Round Yellow (RrYy)
F2 Generation:
β’ Phenotypic Ratio: 9:3:3:1
β’ 9 Round Yellow : 3 Round Green : 3 Wrinkled Yellow : 1 Wrinkled Green
PYQ Corner - Dihybrid Cross
- A tall pea plant with yellow seeds (heterozygous for both) is crossed with a dwarf pea plant with green seeds. Using a Punnett square work out the cross to show the phenotypes and genotypes of F1 generation (CBSE 2008)[2]
- In a dihybrid cross, when would the proportion of the parental gene combinations be much higher than non-parental type as experimentally shown by Morgan and his group? (CBSE 2012)[2]
π§ͺ Test Cross
A cross between an individual with unknown genotype and a homozygous recessive individual[1].
Purpose: To determine the genotype of an individual showing dominant phenotype.
PYQ Corner - Test Cross
- How does a test cross help in identifying the genotype of the organism? Explain (CBSE 2010)[2]
- A test cross is performed between a heterozygous and homozygous recessive individual[8]
π Types of Inheritance Beyond Mendel
1. Incomplete Dominance
Neither allele is completely dominant. F1 hybrid shows intermediate phenotype[1].
Example: 4 o'clock plant (Mirabilis jalapa)
Red (RR) Γ White (rr) β Pink (Rr)
F2: 1 Red : 2 Pink : 1 White
2. Co-dominance
Both alleles express themselves fully in heterozygous condition[1].
Example: Human Blood Group AB (I^A I^B)
Both A and B antigens are expressed
3. Multiple Alleles
More than two alleles exist for a gene, but an individual has only two[1].
Example: ABO Blood group system
Alleles: I^A, I^B, i
Genotypes: I^A I^A, I^A I^B, I^B I^B, I^A i, I^B i, ii
Phenotypes: A, AB, B, A, B, O
PYQ Corner - Non-Mendelian Inheritance
- Snapdragon shows incomplete dominance for flower colour. Work out a cross and explain the phenomenon. How is this inheritance different from Mendelian pattern of inheritance? (CBSE 2012)[2]
- Explain the phenomenon of multiple allelism and co-dominance taking ABO blood group as an example (CBSE 2012)[2]
- A woman with blood group O married a man with AB group. Show the possible blood groups of the progeny. List the alleles involved in this inheritance (CBSE 2008)[2]
π¨ Polygenic Inheritance
Trait controlled by many genes. Shows continuous variation[1].
Examples:
β’ Skin colour in humans
β’ Height in humans
β’ Weight in humans
Characteristics:
β’ Quantitative traits
β’ Bell-shaped distribution
β’ Environmental influence
PYQ Corner - Polygenic Inheritance
- What is the pattern of inheritance for polygenic trait?[12]
- Given below are two statements about polygenic inheritance. Identify if they are correct[12]
𧬠Chromosomal Theory of Inheritance
Proposed by Sutton and Boveri (1902)[1].
Key Points:
- Genes are located on chromosomes
- Chromosomes occur in pairs
- During meiosis, homologous chromosomes segregate
- Independent assortment explains Mendel's laws
PYQ Corner - Chromosomal Theory
- Who proposed the chromosomal theory of inheritance? (CBSE)[8]
- Define the chromosomal theory of inheritance[11]
π Linkage & Recombination
Linkage
Genes located close together on the same chromosome are inherited together[1].
β’ More linkage = less recombination
β’ Example: Morgan's fruit fly experiments
β’ Linked genes don't follow independent assortment
Recombination
Exchange of genetic material between homologous chromosomes during crossing-over in meiosis[1].
β’ Greater distance = more recombination
β’ Recombination frequency = Map distance
β’ Maximum recombination frequency = 50%
PYQ Corner - Linkage
- During his studies on genes in Drosophila that were sex-linked, T.H. Morgan found F2 population phenotypic ratios deviated from expected 9:3:3:1. Explain the conclusion he arrived at (CBSE 2010)[2]
- Explain the contribution of Alfred Sturtevant in chromosome mapping (CBSE 2012)[2]
ββ Sex Determination
In Humans (XY System):
Male: XY β produces two types of gametes (X and Y)
Female: XX β produces only X gametes
Sex ratio: 1:1 (50% male, 50% female)
Other Systems:
| Species | Female | Male | Type |
|---|---|---|---|
| Birds | ZW | ZZ | ZW system |
| Grasshopper | XX | XO | XO system |
| Honeybee | Diploid | Haploid | Haplodiploidy |
PYQ Corner - Sex Determination
- Explain the sex determination mechanism in humans. How is it different in birds? (CBSE 2010)[2]
- Why are grasshopper and Drosophila said to show male heterogamety? Explain female heterogamety with an example (CBSE 2010)[2]
- Women are often blamed for producing female children. How will you address this issue scientifically? (CBSE 2014)[2]
π₯ Genetic Disorders
A. Mendelian Disorders (Monogenic)
| Disorder | Inheritance | Features |
|---|---|---|
| Haemophilia | X-linked recessive | Delayed blood clotting |
| Colour Blindness | X-linked recessive | Can't differentiate red-green colors |
| Sickle Cell Anaemia | Autosomal recessive | Sickle-shaped RBCs, pain, anaemia |
| Thalassemia | Autosomal recessive | Faulty Hb synthesis |
| Phenylketonuria | Autosomal recessive | Mental retardation, excess phenylalanine |
B. Chromosomal Disorders
| Disorder | Karyotype | Symptoms |
|---|---|---|
| Down's Syndrome | Trisomy 21 (47 chromosomes) | Mental retardation, short height, flat face |
| Turner's Syndrome | XO (45 chromosomes) | Female, sterile, no menstruation |
| Klinefelter's Syndrome | XXY (47 chromosomes) | Male, tall, sterile, feminine features |
PYQ Corner - Genetic Disorders
- Write the genotype of: (i) An individual who is carrier of sickle-cell anaemia gene but apparently unaffected (ii) An individual affected with the disease (CBSE 2010)[2]
- A human being suffering from Down's syndrome shows trisomy of 21st chromosome. Mention the cause of this chromosomal abnormality (CBSE 2010)[2]
- Why is the father never passing on the gene for haemophilia to his sons? Explain (CBSE 2012)[2]
- Explain the causes, inheritance pattern and symptoms of any two mendelian genetic disorders (CBSE 2010)[2]
π Mutation - A Sudden Heritable Change
Types of Mutation:
1. Gene Mutation: Change in DNA sequence within a gene
Example: Sickle Cell Anaemia (GAG β GTG in beta-globin gene)
2. Chromosomal Mutation: Structural or numerical changes in chromosomes
Examples: deletion, duplication, inversion, translocation
PYQ Corner - Mutation
- Name the event during cell division cycle that results in gain or loss of chromosome (CBSE 2011)[2]
- Sickle cell anaemia in humans is a result of point mutation. Explain (CBSE 2011)[2]
π Test Your Knowledge - Enhanced PYQ Edition
Question 1 of 25