HEREDITY Heredity: the passing of traits from parents to offspring. Trait: Trait: A physical or behavioral characteristic that describes an organism (Ex: height; eye color; endurance)

Importance of Gregor Mendel Austrian botanist monk Austrian botanist monk Mid 1800s Mid 1800s Formed the basic laws of heredity Formed the basic laws of heredity His work laid the foundation to the study of heredity His work laid the foundation to the study of heredity Mendel is referred to as “The Father of Genetics.” Mendel is referred to as “The Father of Genetics.” Genetics = study of genes, heredity, and genetic variation.

Mendel’s Pea Plants Mendel studied garden pea plants. Observed differences in multiple traits over many generations, because pea plants reproduce rapidly, and have many visible traits such as: Plant Height Tall Short Pod color Seed Shape Pod Shape Seed Color GreenYellow Green Yellow RoundWrinkled SmoothPinched

Mendel’s Experiments Noticed that some plants always produced offspring that had a form of a trait exactly like the parent plant (“purebred”) Example: purebred short plants always produced short offspring and purebred tall plants always produced tall offspring. X Purebred Short Parents Purebred Tall Parents X Short Offspring Tall Offspring

Mendel’s First Experiment Mendel crossed purebred plants with opposite forms of a trait. Example: Purebred tall plants were crossed with purebred short plants. Parent Tall P generation Parent Short P generation X Offspring Tall F1 generation Mendel observed that all of the offspring grew to be tall plants. None resembled the short parent. P stands for “parent” and F# stands for “filial” (son).

Mendel’s Second Experiment Mendel then crossed two of the offspring tall plants produced from his first experiment. Tall F1 generation X F2 generation: 3⁄4 Tall & 1⁄4 Short To his surprise, Mendel observed that this generation had a mix of tall and short plants, even though none of the F1 parents were short! Parent Plants Offspring

Mendel’s Law of Segregation Mendel’s first law, the Law of Segregation, has three parts. From his experiments, Mendel concluded that: 1. Traits are handed down through “hereditary factors” in the sperm and egg. 2. Because offspring obtain hereditary factors from both parents, each organism must contain two factors for every trait. 3. The factors in a pair segregate (separate) during the formation of sex cells, and each sperm or egg receives only one member of the pair.

Dominant and Recessive Alleles One factor (gene) in a pair may mask, or hide, the other factor. Example: When he crossed a purebred tall plant with a purebred short plant, all offspring were tall even though all the F1 offspring should have both tall and short factors. (The tallness factor masked the shortness factor.)

Genes: a section of DNA that determines a trait. Alleles: the different forms of a gene. Alleles are abbreviated with a letter. Example: T = allele for “tall” height t = allele for “short” height Every gene has two alleles (1 from mom & 1 from dad). Dominant and Recessive Alleles

Alternative versions of genes (different alleles) result in variations in inherited traits. Example: The gene for flower color in pea plants exists in two versions, one for purple flowers and the other for white flowers Each gene resides at a specific location on a specific chromosome (remember that there are multiple chromosomes) Dominant and Recessive Alleles

If the two alleles for a gene are different, the dominant allele will determine the organism’s appearance and “mask” the other allele. Dominant alleles are shown with a Capital letter. Dominant alleles are “STRONGER.” The recessive allele will only determine the organism’s appearance if both alleles on the gene are recessive. Recessive alleles are shown with a lower-case letter. Recessive alleles are “weaker.” Dominant and Recessive Alleles

Dominant Alleles Mendel observed a variety of dominant alleles in pea plants other than the tall allele. For instance, a plant that is heterozygous for seed color will always have yellow seeds. Green & Yellow AlleleYellow Seed However, a plant that is heterozygous for pod color always displays the green allele. Green & Yellow Allele Green Pod In addition, round seeds are dominant over wrinkled seeds, and smooth pods are dominant over wrinkled pods.

Homozygous Genes We know now that Mendel’s “purebred” plants had two identical alleles for a particular gene. The modern scientific term for “purebred” is homozygous. Homozygous: having the same allele for a particular gene (NN or nn). Example: A homozygous tall plant has two tall alleles (TT) and will only contribute a tall allele (T). A homozygous short plant has two short alleles (tt) and will only contribute a short allele (t).

Heterozygous Genes When the two types of homozygous plants were crossed the offspring received one tall gene and one short gene from the parent plants. All offspring contained both alleles (1 tall allele and 1 short allele). Heterozygous: possessing two different forms of a gene, one inherited by each parent (Nn). Although the offspring have both a tall and a short allele, only the tall allele is expressed (the tall allele is dominant and “masks” the short allele).

Genotype & Phenotype Genotype: the two alleles that an organism has for a trait. (Example: AA, Aa, aa) Phenotype: the physical trait that the organism shows or “expresses”. (Example: Does the butterfly look dark or light in color?)

Law of Independent Assortment Each pair of genes separate independently of each other in the production of sex cells (egg or sperm). Example: Each sex cell will have only 1 allele for every gene (haploid). The plant will donate either a yellow or green seed allele, or a wrinkled or a smooth pod shape. If the plant donates the yellow seed allele it does not mean that it will also donate the wrinkled pod allele. The donation of one allele from each pair is independent of any other pair.

Remember: 1)There are 2 alleles for every gene. 2)Dominant alleles are “stronger” and Capitalized. 3)Recessive alleles are “weaker” and lower-case. 4)Recessive traits will only be shown if both alleles are recessive. What are the possible allele combinations for these 2 plants?