Genetics and Evolution

Genetics and Evolution Definitions and concepts from BIOL 102 Lab Manual and Biology by Campbell and Reece, 7th Ed.

Genetics! • Founder – Gregor Mendel • Created the laws of Mendelian inheritance in the 1800s • Studied pea plants in a monastery • Law of Segregation • Individual organisms possess a pair of genes for each trait that is randomly passed to offspring • These offspring then have their own pair of genes which is expressed based on dominance • Law of Independent Assortment • Genes for different traits are passed independently to offspring • Did not know at the time that some genes are linked

Biodiversity Classification Levels • Genes • Discrete unit of hereditary information consisting of a specific nucleotide sequence in DNA • Chromosomes • Strands of DNA tightly coiled around proteins (histones) that carry genes • Functions in the transmission of hereditary information from parent to offspring • Look at pages 56 and 57 in the lab manual • How many pairs of chromosomes in humans? • Locus (Loci) • The location of a gene on a chromosome • Alleles • Alternative versions (variants) of a gene that produce distinguishable phenotypic effects

Phenotype vs. Genotype • Genotype • Alleles an individual has for a genetically controlled locus • Each individual has 2 alleles (1 from each parent) at a particular locus • Capital indicates dominant, lowercase indicates recessive • Phenotype • Physical traits including anything that can be observed or measured empirically in an individual Bb; BB - Heterozygous or Homozygous dominant - Eyes not blue bb - Homozygous recessive - Blue eyes http://naturalsciences.sdsu.edu/ta/classes/lab2.4/trait.jpg

Gene Terms • Gene pool • Total aggregate of genes in a population at a time • Homozygous • Having two identical alleles for a given gene • Heterozygous • Having two different alleles for a given gene • Dominant • Allele that is fully expressed in the phenotype of a heterozygote • Recessive • Allele whose phenotypic effect is not observed in a heterozygote

Genes and the Environment • Which traits are controlled by genetics? • Which traits are controlled by the environment? • Is there an interaction between genes and the environment? Hemoglobin Eye Color 3 Interacting Alleles Pigment Color Blue or Not Blue Height Weight Range controlled by genetics Amount controlled by environment

Genetics • Monogenetic • One gene controls the expression of one trait • Epistasis • Gene interaction in which one gene alters the phenotypic effects of another gene that is independently inherited • e.g. eyecolor • Pleiotropy • The ability of a single gene to have multiple effects • e.g. sickle cell anemia

Examples of Genetically-Controlled Traits (many are presumed to be monogenetic) – No Maury/Springer! • Hitchhiker’s thumb • Widow’s peak • Pinky bend • Tongue rolling • Cleft chin • Eye color (example of epistasis) • Sickle cell trait/anemia (example of pleiotropy)

Exercise • Shake your hands out and clasp your hands with fingers interlaced. Which thumb is on top? • Do it again. Which thumb is on top? • How many are right? • How many are left? • Where does this come from?

Punnett Squares • Diagrams used to predict the likelihood of inheritance of certain traits • Named after geneticist Reginald Punnett • 1910 - Co-founder of the Journal of Genetics • Wrote Mendelism – One of the first public books discussing genetics • Mendelian Punnett Square • Pea colors

Lethal Genes • Lethal White in Horses • Being homozygous recessive is lethal • Manx Cats • Being homozygous dominant is lethal • Homozygous recessive cats tend to have a full tail

Evolution • Evolution • A change in allele frequency in a population over time • Mechanisms of evolution • Mutations • Gene flow • Genetic drift • Non-random mating • Natural selection

Mutations • Occur when a base pair or multiple base pairs in the DNA sequence are changed • The ultimate source of all genetic variation • Must occur in the germ-line or sex cells of the organism in order for a mutation to be manifested within a population

Types of Mutations

Gene Flow (Migration) • The movement of alleles between populations due to immigration/emigration http://evolution.berkeley.edu/evosite/evo101/images/geneflow_beetles.gif

Genetic Drift • Caused by change or random variation in the survival and/or reproductive success of individuals -- changes allele frequency • The Founder Effect • when a few individuals inhabit or colonize a new area • this small group represents a subset of the alleles from the original population http://evolution.berkeley.edu/evosite/evo101/images/beetles_mech3.gif

Non-Random Mating • Change in the allele frequency in a population due to mate-choice or sexual selection • Preference of a certain phenotype in mates can lead to a higher representation in the final than original population http://www.dwm.ks.edu.tw/bio/activelearner/18/images/ch18c2.jpg

http://www.scienceteacherprogram.org/biology/NaturalSelectionIllustration.gifhttp://www.scienceteacherprogram.org/biology/NaturalSelectionIllustration.gif http://evolution.berkeley.edu/evosite/misconceps/images/misconceptions_beavers.gif Natural Selection • Due to varying reproductive success and survival of individuals with a particular phenotype compared to individuals with other phenotypes • Occurs at the individual level

Hardy-Weinberg Law • Method for calculating the allele frequency of a specific gene within a population • Establishes the allele frequency within a population at a specific point in time • Must calculate for later generations and compared over time to determine if a population is in EQUILIBRIUM

Hardy-Weinberg Equilibrium • Assumptions • No mutations affect that allele frequency • There is no gene flow into or out of the population • There is no genetic drift where random events outside of a population could cause a shift in allele frequency • Individuals mate at random • There are no selective pressures on that trait • NONE OF THE MECHANISMS OF EVOLUTION ARE IN EFFECT

Hardy-Weinberg Equilibrium Equation • For a gene with only 2 alleles: • p + q = 1 • p = the frequency of the dominant allele • q = the frequency of the recessive allele • p2 + 2pq + q2 = 1 • p2 = the proportion of homozygous dominantindividuals • q2= the proportion of homozygous recessiveindividuals • 2pq = the proportion of heterozygousindividuals

Time to practice calculations using the Hardy-Weinberg Equilibrium equation and Kitties!!!

Kitty Genetics • Class in 4 groups • Pull up petfinder.com and search kitties! • Group 1: New York, NY • Group 2: San Francisco, CA • Group 3: Columbia, SC • Group 4: Miami, FL • Look at the first 10 cats that have pictures available and write down which trait out of each of the four fur categories fits for each cat

Kitty Monogenetic Traits • Long/Short Hair • LL – Short Hair • Ll – Short Hair • ll – Long Hair • White Fur • WW – White Fur • Ww – White Fur • ww – Some Colored Fur • Spots or Not • SS – Some Spots • Ss – Some Spots • ss – All One Color • Dense Pigment • PP – Black, Brown, or Orange • Pp – Black, Brown, or Orange • pp – Gray, Light Brown, Cream, or White

Genetics and Evolution