Subject:
Applied Science, Life Science, Biology
Material Type:
Module
Level:
Community College / Lower Division, College / Upper Division
Provider:
Rice University
Tags:
Allele, Blending Inheritance, Characteristic, Classical Genetics, Codominance, Continuous Variation, Dihybrid, Discontinuous Variation, Dominant, Dominant Allele, Dominant Lethal, Dominant Phenotype, Epistasis, Epistatic Effect, F1, F2, First Filial Generation, Forked-line Method, Gamete Genotype, Garden Pea, Garden Pea Hybridization, Gene, Gene Cross, Genetics, Genotype, Gregor Mendel, Haploid, Hemizygous, Heredity, Heterozygous, Homozygous, Hybridization, Incomplete Dominance, Independent Assortment, Law of Dominance, Law of Independent Assortment, Law of Segregation, Laws of Inheritance, Laws of Probability, Lethality, Linkage, Meiosis, Mendel, Mendelian Cross, Mendelian Genetics, Model System, Monohybrid, Monohybrid Cross, Multihybrid Fertilization, Multiple Alleles, Mutant, P1, Parental Generation, Peas, Pedigree Analysis, Phenotype, Polygenic Inheritance, Probability, Probability Method, Product Rule, Punnett Square, Recessive, Recessive Allele, Recessive Gene, Recessive Lethal, Reciprocal Cross, Recombination, Second Filial Generation, Segregation of Alleles, Sex Linkage, Sex Linked Trait, Sum Rule, Test Cross, Trait, Trait-blending Hypothesis, Unit Factor, Wild Type, X-linkage, X-linked Trait
License:
Creative Commons Attribution-NonCommercial 4.0
Language:
English
Introduction

Introduction

Section 1

Photo shows pea-plant flower, with purple petals that fold back on themselves.
Experimenting with thousands of garden peas, Mendel uncovered the fundamentals of genetics. (credit: modification of work by Jerry Kirkhart)

Genetics is the study of heredity. Johann Gregor Mendel set the framework for genetics long before chromosomes or genes had been identified, at a time when meiosis was not well understood. Mendel selected a simple biological system and conducted methodical, quantitative analyses using large sample sizes. Because of Mendel’s work, the fundamental principles of heredity were revealed. We now know that genes, carried on chromosomes, are the basic functional units of heredity with the capability to be replicated, expressed, or mutated. Today, the postulates put forth by Mendel form the basis of classical, or Mendelian, genetics. Not all genes are transmitted from parents to offspring according to Mendelian genetics, but Mendel’s experiments serve as an excellent starting point for thinking about inheritance.