1. Genetics Gregor Mendel– the “father” of genetics A genetic characteristic generally has two (or more) possible varieties– known as traits. Ex. Plant height: long or short. Flower color: purple or white

2. Along every chromosome, each specific location contains a specific gene for a specific characteristic. Different varieties of each gene are called alleles. Genes exist in pairs, like chromosomes. For every characteristic, you have two genes that determine how that characteristic will appear.

3. The dominant allele of the gene almost always completely masks the recessive allele of the gene. Genotype: the combination of genes that the organism has Phenotype: the actual appearance of the organism Heterozygous: when the two alleles are different Homozygous: when the two alleles are the same

4. If the pea plant is purple, purple is dominant over white in flower color. Could be PP (homozygous dominant) or Pp (heterozygous). If the pea plant is white, it must be pp (Homozygous recessive).

7. Exceptions to “normal” scenarios of inheritance Incomplete dominance: in the heterozygous genotype, the dominant allele does not completely mask the recessive Co-dominance: in the heterozygous genotype, two alleles are visible in the phenotype at the same time Epistasis: one gene modifies the appearance of another gene

8. Incomplete dominance

9. Codominance

11. Sex-linked traits The gene is usually located on the x- chromosome. Sex-linked traits are most common in males. Usually passed from mother to son. Female carriers get one gene from either mother or father. Examples: Colorblindness, hemophilia, Duchenne Muscular Dystrophy

13. Alternative Patterns of Heredity ( in addition to incomplete dominance, codominance, and multiple alleles) Epistasis– a gene at one locus alters the expression of a separate gene Pleiotropy– a gene with multiple phenotypic effects Polygenic inheritance– an additive effect of two or more genes on a single phenotype

14. epistasis Fur pigment color B= black (complete) b= brown Pigment deposition gene C= pigment deposited c= pigment NOT deposited The pigment deposition gene is epistatic to the pigment color gene.

15. Pleiotropy Cystic fibrosis– one gene codes for a defective protein in certain cell membranes; causes multiple effects: thicker & stickier mucus membranes, poor nutrient absorption, chronic bronchitis, recurrent bacterial infections Sickle-cell disease– one gene for a single amino acid is altered in the hemoglobin molecule; causes multiple effects: blood clots, physical weakness, pain, organ damage, paralysis, lowered blood oxygen, brain damage

16. Polygenic inheritance (simplified) 3 pairs of genes determine skin color and the combination of those genes determine the phenotype. The more dominant genes, the darker the skin.

17. Sample question: describe the pattern of inheritance of Huntington’s disease. Dominant, autosomal, lethal (presents at relatively older age, so inheritance is possible in younger generations) Any child born to a parent with Huntington’s has a 50% chance of inheriting the gene