Chp 20 Generation to generation change in allele frequency Genes and populations Chp 20 Generation to generation change in allele frequency

Evolution Populations of living things slowly adapt and change over time Does not explain origin of the very first living thing

Evolution theory is a way to show the connection of all life forms

Evolution also explains the variety within a kind

Carolus Linnaeus 1707-1778 Father of modern taxonomy (classification) Binomial nomenclature genus species Canis Lupus

James Hutton - 1788 Gradualism – Profound change is the product of slow, continuous processes “The present is the key to the past” Ex. Mountains grow slowly now so they always grew slowly!

Jean Baptiste Lamarck 1744-1829 Evolution through acquired traits Based on fossils, relics or impressions of dead organisms Sedimentary rock, ice, tar, amber

Charles Darwin 1809-1882 Evolution by natural selection Also cited fossil evidence Anticipated that intermediates would be found Travelled extensively to observe diversity of life Published “origin of species” In 1859

Evolutionary theories Lamarck VS Darwin

Lamarck - Inheritance by acquired characteristics Individual organisms change. Ex Giraffes – stretched their necks to get food and passed longer necks on to offspring

Darwin – Natural selection .Survival of the fittest. The ones best naturally adapted to survive, have more offspring and pass on the traits to those offspring

Darwin’s version of giraffes Some giraffes were born with longer necks and better able to get food. These ones survived and passed longer necks to their offspring

Population Genetics Studies the genetic variations within a population Characters left: 1000 Preview or Show next comments | View all 0 comments

Species A group of organisms capable of breeding to produce fertile offspring

Different species can not reproduce and have offspring that can reproduce

Variations When different species members have differences in characteristics Ex. Dogs – one species but many varieties

Population A localized group of individuals of the same species

Gene pool All of the genes in a population

Why does the dominant trait take over? Hardy and Weinberg stated the genes in a population will remain stable if under certain conditions

Assumptions of Hardy Weinberg There are no mutations. No genes transferred (No immigration or emigration) Mating is random. The population should be large. No selection is occurring

Hardy-Weinberg theorem An equation used to identify a non-evolving population. Looks at the frequency of each allele HARDY WEINBERG EQUILIBRIUM = There is no change in gene frequency in a population p2 + 2 pq + q2= 1

Mendel genetics – Apply to alleles in one gametes of one pair Mate two individuals heterozygous (Bb) for a trait. 25% offspring are homozygous for the dominant allele (BB) 50% are heterozygous like their parents (Bb) and 25% are homozygous for the recessive allele (bb) and express the recessive phenotype

populations have random alleles The frequency of two alleles in an entire population of organisms is unlikely to be exactly the same. Ex. population of hamsters: A) 80% of all the gametes in the population carry a dominant allele for black coat (B) and B) 20% carry the recessive allele for gray coat (b).

hamsters MENDEL monohybrid cross Results of random union of the two gametes produced by two individuals, each heterozygous for a given trait. As a result of meiosis, half the gametes produced by each parent with carry allele B; the other half allele b.   RANDOM POP Results of random union of the gametes produced by an entire population with a gene pool containing 80% B and 20% b. 0.5 B 0.5 b 0.8 B 0.2 b 0.25 BB 0.25 Bb 0.64 BB 0.16 Bb 0.25 bb 0.04 bb

Allele frequency P = frequency of dominant allele q = frequency of recessive allele Brown eyes vs blue eyes Brown (B) = P Blue (b) = q

Mind your Ps and Qs From old English pubs, be careful how many pints and quarts you consume Also from old typesetters, not mixing up ps and qs

Total frequency of alleles in population = 1 THEREFORE p + q = 1 (dom + res = 1) q =1 – p (res = 1 – dom) p = 1 – q (dom = 1 – res) Ex. R = red r = white there are 20% white flowers in a field q freq =.2 (20%) white then p freq = 1 - .2 = .8 (80%) red

Allele frequency of a dominant and recessive trait Similar to punett square

Ex. Frequency alleles of Red (R) and white (r) flowers p2 + 2 pq + q2 = 1 Frequency freq freq of RR of Rr rr genotype genotype genotype

p2 + 2 pq + q2 = 1 Given: 4% of the population = white flowers (rr) What is the frequency of r? (q) What is the frequency of R? (p) What % of pop. = Rr? q2 = .04 so q = .2 so p = .8 4% rr 2(.8)(.2) = .32 Rr = 32% Rr 64% RR

NOT Hardy Weinberg equilibrium Change of allele frequency in 3 generations

5 agents of evolutionary change Things that CHANGE equilibrium of gene pool

1) Mutation Change in DNA code Mutagen

Mutations The origin of new alleles

2) Gene Flow Migration – Individuals move from one population to next Bring genes into new population

3) Non-Random Mating Self fertilization Inter breeding

4) Genetic drift A change in frequency due to chance

Bottleneck effect Genetic drift due to a reduction in population size Ex skittles

Tsunami bottle neck

Founder effect Genetic drift due to formation of a new colony with organisms with distinctly different phenotypes

5) Natural selection Darwin’s idea Survival of the fittest The environment influences who passes on their DNA

Fitness - ability to pass on traits to offspring The individuals in a population that are most fit are the ones that survive Attract mates better Catch prey better Hide better from predators

Polymorphism – When there are two or more forms of one character aids natural selection by increasing possible phenotypes

Geographic Variation Differences in gene pools between populations Can aid natural selection

Cline A graded change in a trait over a geographical area

Heterozygote advantage When it is advantageous to be heterozygous Ex Sickle cell anemia

Types of Natural Selection

Directional selection One extreme is better Ex. length of an anteaters tongue

Diversifying selection Opposite extremes are favored Ex. White shell or Dark shell

Stabilizing selection The average is best Ex. Field mouse size

Types of natural selection

Sexual selection Picking a mate based on secondary sexual characteristics EX. Tail of peacock

Sexual dimorphism Difference in appearance between males and females Males tend to be more colorful

Males tend to be shorter Ex. Praying mantis

Diamond back terrapins Males smaller

Or just weird to us humans

More sexual dimorphism

Intrasexual selection Competition between individuals of same sex Ex. Rams, elephant seals

Fight for Harem

Inter sexual selection (mate Choice) One sex is choosy about selecting mates Ex Bower bird makes fancy bower to attract mate