Measuring Evolution of Populations Image from: https://s-media-cache-ak0.pinimg.com/236x/0a/c4/6c/0ac46cac37e5afb70010f25beedec39e.jpg
CONDITIONS FOR HARDY WEINBERG EQUILIBRIUM http://pngimg.com/upload/hands_PNG905.png
Populations & gene pools _________ = group of interbreeding individuals ___________is collection of alleles in the population remember difference between alleles & genes! allele ___________ is how common is that allele in the population how many A vs. a in whole population
Hardy-Weinberg equilibrium POPULATION IN HW EQUILIBRIUM = IDEAL IT MEANS NO EVOLUTION IS HAPPENING Allele frequencies stay the same Rare in real populations Way to tell if evolution is happening in a population G.H. Hardy (the English mathematician) and W. Weinberg (the German physician) independently worked out the mathematical basis of population genetics in 1908. Their formula predicts the expected genotype frequencies using the allele frequencies in a diploid Mendelian population. They were concerned with questions like "what happens to the frequencies of alleles in a population over time?" and "would you expect to see alleles disappear or become more frequent over time?" G.H. Hardy mathematician W. Weinberg physician
The Hardy-Weinberg Equation p2 + 2pq + q2 = 1 _____ = the frequency of homozygous dominant genotype (T T) ______ = the frequency of heterozygous genotype (T t) ______ = the frequency of homozygous recessive genotype (t t)
The Hardy-Weinberg Equation p + q = 1 _____ = the frequency of dominant ALLELE in population (T) ______ = the frequency of recessive ALLELE in population (t) BOZEMAN BIOLOGY Hardy Weinberg equation
T t T p + q = 1 t ALLELES in population T = _____ t = _____
T t T t T t T T T t t t Homozygous dominant = ______ Homozygous recessive = ______ Heterozygous = _____
T t T t p2 + 2pq + q2 = 1 = _____ = _________ = ______ GENOTYPES in population Homozygous dominant = ________ Homozygous recessive = ________ Heterozygous = __________ = _____ = ______ = _________
In a population of pigs color is determined by one gene In a population of pigs color is determined by one gene. If the black allele (b) is recessive and the white allele (B) is dominant, what is the frequency of the black allele in this population? p + q = 1 p2 + 2pq + q2 = 1 ALWAYS START WITH HOMOZYGOUS RECESSIVE (bb) = q2 GENOTYPE OF Black pigs = ______ White pigs = ______ or ______ BOZEMAN BIOLOGY SOLVING HARDY WEINBERG PROBLEMS
In a population of pigs color is determined by one gene In a population of pigs color is determined by one gene. If the black allele (b) is recessive and the white allele (B) is dominant, what is the frequency of the black allele in this population? p + q = 1 p2 + 2pq + q2 = 1 Black pigs = ______ = _____ = _____ SO bb . . . q2 = ______
p + q = 1 p2 + 2pq + q2 = 1 b = ______ (q) B = ______ (p) bb = ________ (q2) Bb = _______ (2pq) BB = _______ (p2) If q2 = 0.25 q = _____ = _______ p + q = 1 OR 1 – q = p p = 1- 0.5 = _____ If p = ____ then p2 = ______ = ______
p + q = 1 p2 + 2pq + q2 = 1 b = ______ (q) b = ______ (p) bb = ________ (q2) Bb = _______ (2pq) BB = _______ (p2) If you know this : can you figure out 2pq? p2 + 2pq + q2 = 1 ____ + 2pq + ____ = 1 2pq = 1 – 0.5 = _____
p + q = 1 p2 + 2pq + q2 = 1 b = ______ (q) B = _____ (p) bb = ________ (q2) Bb = _______ (2pq) BB = _______ (p2) You can answer ?’s now What is the frequency of the white allele (B) in population? B = ___ = _____ = ____ What percent of the population is HOMOZYGOUS DOMINANT? BB = ____ = _____ = _____
In a population of fruit flies, 36% have red eyes and the remainder have sepia eyes. The sepia (r) eye trait is recessive to red (R) eyes. Calculate the frequencies in this population. p + q = 1 p2 + 2pq + q2 = 1 ALWAYS START WITH HOMOZYGOUS RECESSIVE (rr) = q2 GENOTYPE OF Red eyes = ______ or _____ sepia eyes = ______
In a population of fruit flies, 64 % have red eyes and the remainder have sepia eyes. The sepia (r) eye trait is recessive to red (R) eyes. Calculate the frequencies in this population. p + q = 1 p2 + 2pq + q2 = 1 If red eyes = ______= _____ ? % have sepia eyes = _____ = r r = q2
p + q = 1 p2 + 2pq + q2 = 1 r = ______ (q) R = ______ (p) rr = ________ (q2) Rr = _______ (2pq) RR = _______ (p2) If q2 = 0.36 q = _____ = _______ p + q = 1 OR 1 – q = p p = 1- 0.6 = _____ If p = ____ then p2 = ______ = ______
p + q = 1 p2 + 2pq + q2 = 1 r = ______ (q) R = ______ (p) rr = ________ (q2) Rr = ______ (2pq) RR = _______ (p2) If you know this : can you figure out 2pq? p2 + 2pq + q2 = 1 ____ + 2pq + ____ = 1 2pq = 1 – 0.52 = _____
p + q = 1 p2 + 2pq + q2 = 1 r = ______ (q) R = ______ (p) rr = ________ (q2) Rr = _______ (2pq) RR = _______ (p2) You can answer ?’s now What is the frequency of the sepia allele (r) in population? r = ___ = _____ = ____ What percent of the population is HETEROZYGOUS? Rr = ____ = _____ = _____
Using Hardy-Weinberg equation p2=.36 2pq=.48 q2=.16 Assuming H-W equilibrium BB Bb bb p2=.20 p2=.74 2pq=.64 2pq=.10 q2=.16 q2=.16 Sampled data Sampled data 1: Hybrids are in some way weaker. Immigration in from an external population that is predomiantly homozygous B Non-random mating... white cats tend to mate with white cats and black cats tend to mate with black cats. Sampled data 2: Heterozygote advantage. What’s preventing this population from being in equilibrium. bb Bb BB Change in allele frequency = EVOLUTION happened