Notes from NEET topper
Gregor Mendel, an Austrian scientist, conducted groundbreaking experiments with pea plants in the mid-19th century that laid the foundation for our understanding of genetics. His experiments are known as Mendel’s pea plant experiments and are considered the cornerstone of modern genetics. Here’s a basic introduction to Mendel’s experiments with pea plants:
1. Choice of Pea Plants:
Mendel chose the garden pea plant, Pisum sativum, for his experiments. He selected this plant because it had distinct, easily observable traits and could be easily cross-fertilized.
2. Traits and Varieties:
Mendel studied seven distinct traits of pea plants, including flower color (purple or white), seed color (yellow or green), seed texture (smooth or wrinkled), and others.
Each trait had two contrasting varieties, which made it ideal for his experiments.
3. Controlled Cross-Fertilization:
Mendel conducted controlled cross-fertilization (crossbreeding) of pea plants. He ensured that he controlled which plants were allowed to cross-pollinate to accurately track inheritance patterns.
4. Generation Labels:
Mendel labeled generations of plants with specific terms:
P Generation (Parental Generation): The initial generation of plants he started with, each having a different trait (e.g., purebred purple-flowered and purebred white-flowered plants).
F1 Generation (First Filial Generation): The offspring of the P generation resulting from controlled cross-fertilization. F2 Generation (Second Filial Generation): The offspring of the F1 generation when self-fertilized or cross-fertilized with other F1 plants.
5. Law of Segregation:
Mendel’s first law, the Law of Segregation, states that alleles (gene variants) segregate or separate during gamete formation. Each individual inherits one allele from each parent . This law explains why traits reappear in the F2 generation.
6. Law of Independent Assortment:
Mendel’s second law, the Law of Independent Assortment, states that different genes segregate independently of each other during gamete formation. This law explains how traits from different genes are inherited.
7. Ratios and Predictions:
Mendel carefully observed and counted the traits in each generation.
He noted that certain ratios, such as 3:1 (dominant to recessive) for a single trait, were consistently observed in the F2 generation.
8. Conclusion:
Mendel’s experiments provided strong evidence for the existence of hereditary factors (later known as genes) and their patterns of inheritance. His laws laid the groundwork for our understanding of genetics, including concepts like dominant and recessive alleles, genotype and phenotype, and Punnett squares.