Inheritance and Genetics
Subject: Biology
Topic: 10
Cambridge Code: 0610 / 0970 / 5090
Basic Genetics Terms
Gene - Section of DNA coding for protein
Allele - Alternative form of gene
- Dominant (A) - Expressed when present
- Recessive (a) - Only expressed homozygous
Genotype - Genetic makeup (AA, Aa, aa)
Phenotype - Visible characteristics
Homozygous - Two identical alleles (AA, aa)
Heterozygous - Two different alleles (Aa)
Mendel's First Law
Law of Segregation - Alleles separate during gamete formation
Monohybrid Cross
Cross involving ONE trait
Example: Pea plant height
- P: Tall (AA) × Short (aa)
- Gametes: A × a
- F₁: All Aa (tall)
- F₁ × F₁: Aa × Aa
- F₂: 1 AA : 2 Aa : 1 aa
- Phenotypic ratio: 3:1 (Tall:Short)
- Genotypic ratio: 1:2:1
Punnett Square
| A | a | |
|---|---|---|
| A | AA | Aa |
| a | Aa | aa |
Result: 3 tall : 1 short
Mendel's Second Law
Law of Independent Assortment - Alleles of different genes segregate independently
Dihybrid Cross
Cross involving TWO traits
Example:
- Seed color (Yellow Y, Green y)
- Seed shape (Round R, Wrinkled r)
P: YYRR (Yellow round) × yyrr (Green wrinkled)
F₁: YyRr (all yellow round)
F₁ × F₁: YyRr × YyRr
F₂ Ratio: 9:3:3:1
- 9 Yellow round
- 3 Yellow wrinkled
- 3 Green round
- 1 Green wrinkled
Inheritance Patterns
Simple Dominance
One allele completely dominates over other
- Aa shows dominant phenotype
- aa shows recessive phenotype
Example: Brown eyes (dominant) vs blue eyes (recessive)
Incomplete Dominance
Neither allele completely dominant
- Heterozygote shows intermediate phenotype
Example: Red flower × White flower → Pink flower (in snapdragons)
Genotype: R^R (red), R^W (pink), W^W (white)
Codominance
Both alleles equally expressed
- Heterozygote shows both phenotypes
Example: ABO blood typing
- I^A I^A or I^A i = Type A
- I^B I^B or I^B i = Type B
- I^A I^B = Type AB (both A and B antigens)
- ii = Type O
Sex-Linked Inheritance
Sex chromosome: X and Y
X-linked traits - Gene on X chromosome
- Males (XY): One copy determines phenotype
- Females (XX): Two copies possible
Example: Colour-Blindness (Red-Green)
- X^B = Normal (dominant)
- X^b = Color-blind (recessive)
Males:
- X^B Y = Normal
- X^b Y = Color-blind
Females:
- X^B X^B = Normal (homozygous)
- X^B X^b = Normal carrier (heterozygous)
- X^b X^b = Color-blind
Cross: Normal female (X^B X^b) × Color-blind male (X^b Y)
Offspring:
- Female: 50% normal, 50% color-blind
- Male: 50% normal, 50% color-blind
Test Cross
Test cross - Individual with dominant phenotype crossed with homozygous recessive
Purpose: Determine if organism is homozygous (AA) or heterozygous (Aa)
Cross: Aa (unknown) × aa
Results:
- If heterozygous: 50% Aa, 50% aa (1:1 ratio)
- If homozygous: 100% Aa (all dominant)
Mutations
Mutation - Change in DNA sequence
Types
Point mutation: Single nucleotide changed
- Silent: No change in protein
- Missense: Different amino acid
- Nonsense: Stop codon created
Insertion/Deletion: DNA segments added/removed
- Causes frameshift
- Usually harmful
Causes
- Spontaneous errors
- UV radiation
- Chemical mutagens
- Ionizing radiation
Effects
- Beneficial: Rare (e.g., antibiotic resistance)
- Neutral: No effect
- Harmful: Reduce fitness (e.g., cystic fibrosis)
Natural Selection
Natural selection - Organisms with favorable traits survive and reproduce
Process
- Variation exists in population
- Organisms with advantageous traits survive
- Survivors reproduce more
- Favorable alleles become more common
- Evolution occurs over generations
Example: Antibiotic Resistance
- Bacteria have genetic variation
- Antibiotics kill susceptible bacteria
- Resistant bacteria survive
- Resistance alleles increase in frequency
- Population becomes resistant
Key Points
- Alleles segregate during meiosis
- Gametes carry one allele per gene
- Fertilization restores diploid number
- Three inheritance patterns possible
- X-linked inheritance differs in males/females
- Mutations alter DNA
- Natural selection acts on phenotypes
Practice Questions
- Complete monohybrid cross Punnett square
- Calculate F₂ ratios from dihybrid cross
- Determine genotypes from phenotypes
- Solve X-linked inheritance problems
- Explain incomplete dominance
- Predict mutation effects
- Describe natural selection
Revision Tips
- Master Punnett squares
- Know dominant vs recessive
- Learn inheritance patterns
- Understand sex-linked traits
- Practice cross problems
- Know mutation types
- Understand natural selection mechanism