Mendel, Gregor Johann, was a German scientist who is widely regarded as the “Father and Founder of Genetics.” Between 1856 and 1863, Mendel conducted a large number of experiments on the pea plant (Pisum sativum). He looked into the results of the experiments and came up with a slew of observations. As a result, the laws of inheritance, also known as Mendel’s laws of inheritance, were established.
Experiments on the Pea Plant by Gregor Mendel
Mendel chose the pea plant after conducting extensive research for a variety of reasons, including:
- The pea plants were simple to grow and keep up with.
- It has a large number of characters who are clearly distinct and contrasting.
- Because the pea plant is an annual plant, it is possible to study many generations of the plant in a relatively short period of time.
- Peas are naturally self-pollinating, but they can also be pollinated by other plants.
Mendel designed his experiments so that he could only observe one pair of contrasting characters at a time, which allowed him to collect a lot of data. He began his experiments by using purebred lines to create characters that were diametrically opposed to one another.
He crossed two pure lines that had contrasting characteristics, and the offspring that resulted were referred to as the F1 generation (also called the first filial generation). The F1 generations were then self-pollinated, resulting in the formation of the F2 generation, which was the second filial generation’s offspring.
Mendel’s Experiments Produced the Following Results
Look at the results of Gregor Mendel’s experiments, in which he crossed two different varieties of tall pea plants with two different varieties of short pea plants.
Mendel noticed that all of the plants in the F1 generation were exceptionally tall. There were no dwarf plants to be found.
Mendel observed that three of the offspring were tall, whereas one was dwarf in the second generation (F2).
When Mendel investigated other characters, he discovered results that were similar.
Mendel observed that the characters of only one parent appeared in the F1 generation, whereas the characters of the other parent appeared in the F2 generation, as well.
It is known as dominant traits for characters that first appear in the F1 generation, while recessive traits are used to refer to characters that appear for the first time in the F2 generation.
Results
The genes that are passed down from one generation to the next are found in pairs in each individual. Alleles are the pairs of genes that make up a person.
When both alleles are the same, the condition is referred to as homozygous. Heterozygotes are individuals who have two alleles that are different from one another.
Capital letters are used to describe dominant characters, whereas small letters are used to describe recessive characters. For example, the dominant genes for tallness in a pea plant are denoted by the letters TT, while the recessive genes are denoted by the letters tt. In the case of heterozygous genes, the letters Tt are used to indicate that the plant appears tall due to the presence of a recessive gene that may manifest itself in future generations.
Although the phenotype of a plant is defined as its outward appearance, its genetic makeup is referred to as the genotype of the plant. As a result, a plant with Tt genes appears tall phenotypically, but it is actually carrying a recessive gene.
It is possible for either of the alleles to fuse with that of the other parent during the gametogenesis stage (when the chromosomes are half in the gametes), which results in the formation of a zygote with 50 percent chance.
Mendel proposed three laws as a result of his observations and experiments.
Law of Dominance
When there is a heterozygous condition, this law states that the allele whose characteristics are expressed over the other allele is referred to as the dominant allele, while those characteristics that are expressed over the other allele are referred to as dominant characters. The dominant characters in the F1 generation are the characters who first appear in the series. The recessive characters first appear in the second generation of characters.
Law of Segregation
In accordance with this law, when two traits are combined to form a hybrid pair, the two characters do not mix with one another and are completely independent of one another. During the meiotic division of the chromosome, each gamete receives one of the two alleles.
Mendel’s law of segregations supports the phenotypic ratio of 3:1, which means that the homozygous dominant and heterozygous offspring show dominant traits, while the homozygous recessive offspring show the recessive trait, as demonstrated by the example above.
Law of Independent Assortment
Essentially, this means that at the time of gamete formation, the two genes segregate independently of one another and of the other traits present in the population. Independent assortment emphasises that there are distinct genes for distinctive traits and characteristics, with each gene having its own influence and sorting process that is distinct from that of the other genes.
It also states that at the time of gamete and zygote formation, the genes are passed on in an independent manner from the parents to the offspring, according to this law.
Conclusion
Genome research began in 1861 with the discovery by Gregor Johann Mendel, the father and founder of genetics, of the mystery of genetics. It was during his many experiments with pea plants that he was able to observe the pattern of inheritance from one generation to the next generation. Mendel’s investigation resulted in the discovery of three laws of inheritance, which are now known as Mendel’s Laws of Inheritance, which are named after him. The three laws of inheritance established by Mendel are the Law of Dominance, the Law of Segregation, and the Law of Independent Assortment. These laws were established as a result of experiments conducted on pea plants with a variety of different characteristics. Mendel began his research with a monohybrid cross as a starting point.