Скачать или смотреть Mendelian Genetics and Inheritance Patterns | Chapter 11 – iGenetics: A Molecular Approach (3rd)

This chapter establishes the fundamental principles of transmission genetics, grounded in the pioneering work of Gregor Mendel and his experiments with the garden pea, Pisum sativum. The text distinguishes between the genotype, which is the genetic constitution of an organism, and the phenotype, the observable traits resulting from the interaction between the genotype and the environment. Through controlled breeding experiments using true-breeding strains, the chapter details the mechanics of monohybrid crosses, leading to the formulation of Mendel's First Law, the Principle of Segregation. This principle explains how the two alleles of a gene separate during gamete formation, resulting in haploid gametes that carry only one allele each. The concepts of dominance and recessiveness are explored, explaining how heterozygous individuals express the dominant phenotype while masking the recessive allele, typically resulting in a 3 to 1 phenotypic ratio in the F2 generation. The text introduces the testcross as a diagnostic tool to determine the genotype of an individual displaying a dominant phenotype by crossing it with a homozygous recessive organism. The discussion expands to dihybrid and trihybrid crosses to illustrate Mendel's Second Law, the Principle of Independent Assortment, which states that alleles for genes on different chromosomes segregate independently, producing characteristic phenotypic ratios such as 9 to 3 to 3 to 1. To predict genetic outcomes, the chapter explains the application of probability rules—specifically the product and sum rules—using Punnett squares and branch diagrams. The biological basis of these traits is connected to molecular genetics, describing how wild-type alleles typically encode functional proteins, while recessive mutations often result in loss of function, and dominant mutations may cause a gain of function. A specific molecular example provided is the seed-shape gene, where the wrinkled phenotype is caused by a transposon insertion affecting the starch-branching enzyme. Furthermore, the chapter outlines statistical methods for genetic analysis, specifically the chi-square goodness-of-fit test, to evaluate whether observed data deviations from expected Mendelian ratios are due to chance or if the null hypothesis should be rejected. Finally, the principles of Mendelian genetics are applied to humans through pedigree analysis, a method used to trace inheritance patterns of traits such as albinism and achondroplasia across generations in the absence of controlled breeding, utilizing standard symbols to map family histories.


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