Presentation is loading. Please wait.

Presentation is loading. Please wait.

Population Genetics Microevolution, Natural Selection & The Hardy Weinberg Equation Packet #27 Chapter #11 11/20/2018 8:15 PM.

Published byLiani Irawan Modified over 5 years ago

Similar presentations

Presentation on theme: "Population Genetics Microevolution, Natural Selection & The Hardy Weinberg Equation Packet #27 Chapter #11 11/20/2018 8:15 PM."— Presentation transcript:

1 Population Genetics Microevolution, Natural Selection & The Hardy Weinberg Equation
Packet #27 Chapter #11 11/20/2018 8:15 PM

2 Population Genetics The study of genetic variability within the population and of the forces that act on it. Gene Pool Consists of all alleles, of all genes, present within a freely interbreeding population. Can be calculated, mathematically, using various frequencies Genotype frequency Phenotype frequency Allele frequency 11/20/2018 8:15 PM

3 Important Vocabulary Allele Genotype frequency Phenotype frequency
Different form of a particular gene Genotype frequency The proportion of a particular genotype in the population. Phenotype frequency The proportion of a particular phenotype in a population. Allele frequency The proportion of a specific allele in a population. 11/20/2018 8:15 PM

4 Hardy-Weinberg Godfrey Hardy Wilhelm Weinberg
British mathematician Wilhelm Weinberg German physician In 1908, both individuals independently reported a mathematical model that describes allele frequencies in a population at any given time. The Hardy-Weinberg Equation 11/20/2018 8:15 PM

5 The Hardy-Weinberg Equation
11/20/2018 8:15 PM

6 Variables Letters are used to represent specific variables. p q
Represents the frequency of the dominant allele Ranges from 0 to 1 q Represents the frequency of the recessive allele 11/20/2018 8:15 PM

7 Hardy-Weinberg Equation
Binomial Equation (p + q)2 p2 + 2pq + q2 p2 = frequency of homozygous dominant individuals q2 = frequency of homozygous recessive individuals 2pq = frequency of hetereozygous individuals For a population segregating two alleles at a particular time, in which p represents the dominant allele and q represents the recessive allele, the total frequency of all alleles will always equal to 1. p + q = 1.0 Any sexually reproducing population in which the allele frequencies conform to this equation is at genetic equilibrium. 11/20/2018 8:15 PM

8 Examples See Course Website 11/20/2018 8:15 PM

9 Assumptions for the Hardy-Weinberg Equation
Random mating of all genotypes No net mutations Large population size due to statistical constraints No migration (gene flow) No exchange of alleles with other populations No natural selection 11/20/2018 8:15 PM

10 Microevolution 11/20/2018 8:15 PM

11 Microevolution Change in a population’s allele, or genotype, frequencies over successive generations Occurs when a population does not meet all of the assumptions of the Hardy-Weinberg principle The small changes are referred to as microevolution. 11/20/2018 8:15 PM

12 Microevolution II There are five micro-evolutionary forces: -
Non-random mating Mutations Genetic drift Bottleneck effect Founder effect Gene flow Natural selection Stabilizing selection Directional selection Disruptive selection Microevolution Non-Random Mating Mutations Genetic Drift Gene Flow Natural Selection 11/20/2018 8:15 PM

13 Non-Random Mating Microevolution 11/20/2018 8:15 PM

14 Non-random Mating Assortative Mating
Individuals select mates on the basis of phenotype—indirectly selecting a corresponding genotype. This may lead to interbreeding Leads to an increased homozygous allele composition May lead to interbreeding depression and lowered “fitness” in the population Commonly seen in plants Fitness Ability to pass on genes to the next generation 11/20/2018 8:15 PM

15 Mutations Microevolution 11/20/2018 8:15 PM

16 Mutations Unpredictable changes in DNA resulting in the production of new alleles Introduces variation Cause small deviations from Hardy-Weinberg equilibrium Mutations in somatic cells are not heritable Mutations in alleles found in sex cells allow those changes to be passed to the offspring 11/20/2018 8:15 PM

17 Genetic Drift Microevolution 11/20/2018 8:15 PM

18 Genetic Drift Random events that change allele frequencies in small populations Small populations are more prone to lose alleles present in low frequencies 11/20/2018 8:15 PM

19 Bottleneck Effect Rapid and severe declines in population size due to an adverse environmental factor Results in an increase in different allele frequencies 11/20/2018 8:15 PM

20 Bottleneck Effect Example
Examples Northern elephant seals Cheetah American bison Wollemi Pine 11/20/2018 8:15 PM

21 Founder Effect Occurs when a small population colonizes a new area.
Common in island populations Finnish population exhibits much less allelic variation than the general European population Amish population in Pennsylvania has a significant number of individuals with the allele composition for a form of dwarfism. 11/20/2018 8:15 PM

22 Gene Flow Microevolution 11/20/2018 8:15 PM

23 Gene Flow The movement of alleles caused by a migration of individuals between populations Migration of breeding individuals introduces new allelic frequencies to a population Tends to counteract natural selection and genetic drift Causes populations to become more genetically similar Humans have experienced an increase in gene flow in the last few hundred years. 11/20/2018 8:15 PM

24 Natural Selection Microevolution 11/20/2018 8:15 PM

25 Natural Selection Natural selection results in changes in allele composition that lead to adaptation and is based on differential reproduction Natural selection does not act directly on an organism’s genotype but acts on the phenotype. The phenotype represents an interaction between the environment and all the alleles in the organism’s genotype. Natural selection weeds out those individuals whose phenotypes are less adapted to environmental changes Allowing the better adapted organisms to survive and pass their alleles to future generations Natural selection acts indirectly on the genotype. 11/20/2018 8:15 PM

26 Natural Selection There are three types of natural selection: -
Stabilizing selection Directional selection Disruptive selection 11/20/2018 8:15 PM

27 Natural Selection Stabilizing Selection
Favors intermediate phenotypes Results in reduced variation in a population Classic example is human birth weight Remember that natural selection acts on the phenotypes. 11/20/2018 8:15 PM

28 Natural Selection Directional Selection
Favors one phenotype over another Favors one extreme of the normal distribution over the other phenotypes. Remember that natural selection acts on the phenotypes. 11/20/2018 8:15 PM

29 Natural Selection Disruptive Selection
Favors phenotypic extremes Selects for two or more different phenotypes May result in splitting of a population into 2 or more separate species. Remember that natural selection acts on the phenotypes. 11/20/2018 8:15 PM

30 Review 11/20/2018 8:15 PM

Download ppt "Population Genetics Microevolution, Natural Selection & The Hardy Weinberg Equation Packet #27 Chapter #11 11/20/2018 8:15 PM."

Similar presentations

Micro Evolution -Evolution on the smallest scale

Micro Evolution -Evolution on the smallest scale
Evolutionary Change in Populations

Evolutionary Change in Populations
EVOLUTION OF POPULATIONS

EVOLUTION OF POPULATIONS
Essentials of Biology Sylvia S. Mader

Essentials of Biology Sylvia S. Mader
Chapter 18 Chapter 18 The Evolution of Populations.

Chapter 18 Chapter 18 The Evolution of Populations.
Population Genetics: Populations change in genetic characteristics over time Ways to measure change: Allele frequency change (B and b) Genotype frequency.

Population Genetics: Populations change in genetic characteristics over time Ways to measure change: Allele frequency change (B and b) Genotype frequency.
PROCESS OF EVOLUTION I (Genetic Context). Since the Time of Darwin  Darwin did not explain how variation originates or passed on  The genetic principles.

PROCESS OF EVOLUTION I (Genetic Context). Since the Time of Darwin  Darwin did not explain how variation originates or passed on  The genetic principles.
Population Genetics Packet #29. Population Genetics The study of genetic variability within the population and of the forces that act on it.

Population Genetics Packet #29. Population Genetics The study of genetic variability within the population and of the forces that act on it.
Hardy-Weinberg The Hardy-Weinberg theorem (p2+2pq+q2 = 1) describes gene frequencies in a stable population that are well adapted to the environment. It.

Hardy-Weinberg The Hardy-Weinberg theorem (p2+2pq+q2 = 1) describes gene frequencies in a stable population that are well adapted to the environment. It.
Evolution of Populations

Evolution of Populations
Warm-up- hand this in for credit

Warm-up- hand this in for credit
Review of Natural Selection Types. Effects of Selection See Fig. 23.12 Coat color.

Review of Natural Selection Types. Effects of Selection See Fig Coat color.
HARDY-WEINBERG CALCULATIONS Evolution & Homeostasis 2012.

HARDY-WEINBERG CALCULATIONS Evolution & Homeostasis 2012.
1 1 Population Genetics. 2 2 The Gene Pool Members of a species can interbreed & produce fertile offspring Species have a shared gene pool Gene pool –

1 1 Population Genetics. 2 2 The Gene Pool Members of a species can interbreed & produce fertile offspring Species have a shared gene pool Gene pool –
Population Genetics youtube. com/watch

Population Genetics youtube. com/watch
POPULATION GENETICS 1. Outcomes 4. Discuss the application of population genetics to the study of evolution. 4.1 Describe the concepts of the deme and.

POPULATION GENETICS 1. Outcomes 4. Discuss the application of population genetics to the study of evolution. 4.1 Describe the concepts of the deme and.
The Evolution of Populations Chapter 21. Microevolution Evolutionary changes within a population  Changes in allele frequencies in a population over.

The Evolution of Populations Chapter 21. Microevolution Evolutionary changes within a population  Changes in allele frequencies in a population over.
PACKET #59 CHAPTER #23 Microevolution 10/31/2015 4:20 PM 1.

PACKET #59 CHAPTER #23 Microevolution 10/31/2015 4:20 PM 1.
Objective: Chapter 23. Population geneticists measure polymorphisms in a population by determining the amount of heterozygosity at the gene and molecular.

Objective: Chapter 23. Population geneticists measure polymorphisms in a population by determining the amount of heterozygosity at the gene and molecular.
1 1 Population Genetics _aIocyHc Bozeman..7:39min. _aIocyHc

1 1 Population Genetics _aIocyHc Bozeman..7:39min. _aIocyHc

Similar presentations

Ads by Google