Presentation is loading. Please wait.

Presentation is loading. Please wait.

Review of Mendelian Genetics and Population Genetics Prep for lab tomorrow: Chapter 5.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Review of Mendelian Genetics and Population Genetics Prep for lab tomorrow: Chapter 5."— Presentation transcript:

1 Review of Mendelian Genetics and Population Genetics Prep for lab tomorrow: Chapter 5

2 Autosomal inheritance Hand-clasping

3 X-linked inheritance Red-green color blindness

4 Population genetics Is evolution taking place in a population? Evidence: – 1. Statistical analysis of phenotypic attributes – 2. Change in allele frequencies.

5 Human controlled crosses One gene; two alleles Probability of getting particular genotypes Based on frequencies of alleles Same cross can be depicted as (G + g) x (G + g) = (G + g) 2 = G 2 + 2Gg + g 2 Generalized case: (p + q) 2 = p 2 + 2pq + q 2 Hardy-Weinberg equilibrium formula Allele frequencies  0.5 G; 0.5 g Genotype frequencies  Phenotype frequencies  So evolution can be defined as a change in allele frequencies.

6 In natural populations Alleles segregate into different gametes in the same way, but Individuals free to choose mates If individuals chose mates randomly, then genotypic and phenotypic frequencies depend on allele frequencies.

7 Information from individuals in Lab Section 2, with no individuals added from Regis population.. Hand clasping: 15 dominant (L on R) : 3 recessive (R on L) N = 18 15/18 individuals are either C/C or C/c0.83 3/18 individuals ARE c/c0.17 Is the population sampled in genetic equilibrium? Need to know the frequencies of C and c. Then plug the frequencies into the Hardy-Weinberg formula Represents one generation of random mating q 2 = frequency of c/c = 0.17 q = square root of q 2 = square root of 0.17 = 0.4123 P + q = 1 p = 1 – q = 1 – 0.4123 = 0.5877 p 2 + 2pq + q 2 = 1 (0.5877) 2 + 2(0.5877)(0.4123) + (0.4123) 2 0.3454 + 0.4846 + 0.1700 = 1 P = 0.3454 + ½(0.4846) = 0.5877 q = 0.1700 + ½ (0.4846) = 0.4123 Have frequencies of C and c changed after one generation of random mating. Observed p and q Expected p and q

Download ppt "Review of Mendelian Genetics and Population Genetics Prep for lab tomorrow: Chapter 5."

Similar presentations

How do we know if a population is evolving?

How do we know if a population is evolving?
Chapter 3: The Modern Synthesis. Hardy-Weinberg equilibrium If no selection and mating is random (i.e., no processes acting to change the distribution.

Chapter 3: The Modern Synthesis. Hardy-Weinberg equilibrium If no selection and mating is random (i.e., no processes acting to change the distribution.
KEY CONCEPT Hardy-Weinberg equilibrium provides a framework for understanding how populations evolve.

KEY CONCEPT Hardy-Weinberg equilibrium provides a framework for understanding how populations evolve.
Hardy-Weinberg Equilibrium

Hardy-Weinberg Equilibrium
 Read Chapter 6 of text  Brachydachtyly displays the classic 3:1 pattern of inheritance (for a cross between heterozygotes) that mendel described.

 Read Chapter 6 of text  Brachydachtyly displays the classic 3:1 pattern of inheritance (for a cross between heterozygotes) that mendel described.
Evolution and Genetic Equilibrium

Evolution and Genetic Equilibrium
 Establishes a benchmark from a non- evolving population in which to measure an evolving population.  Investigates the properties of populations that.

 Establishes a benchmark from a non- evolving population in which to measure an evolving population.  Investigates the properties of populations that.
The Hardy-Weinberg Equilibrium Allele Frequencies in a Population G.H. Hardy English Mathematician Dr. Wilhelm Weinberg German Physician.

The Hardy-Weinberg Equilibrium Allele Frequencies in a Population G.H. Hardy English Mathematician Dr. Wilhelm Weinberg German Physician.
Hardy Weinberg: Population Genetics

Hardy Weinberg: Population Genetics
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.
Hardy Weinberg: Population Genetics

Hardy Weinberg: Population Genetics
 Read Chapter 6 of text  We saw in chapter 5 that a cross between two individuals heterozygous for a dominant allele produces a 3:1 ratio of individuals.

 Read Chapter 6 of text  We saw in chapter 5 that a cross between two individuals heterozygous for a dominant allele produces a 3:1 ratio of individuals.
Chapter 23 Population Genetics © John Wiley & Sons, Inc.

Chapter 23 Population Genetics © John Wiley & Sons, Inc.
The Hardy-Weinberg Equation

The Hardy-Weinberg Equation
Population Genetics and Evolution. Darwin’s Observations (review) Galapagos Islands Many similar species had slight differences Favorable variations allow.

Population Genetics and Evolution. Darwin’s Observations (review) Galapagos Islands Many similar species had slight differences Favorable variations allow.
Population Genetics Learning Objectives

Population Genetics Learning Objectives
The Hardy-Weinberg Theorem describes a nonevolving population

The Hardy-Weinberg Theorem describes a nonevolving population
Do Now: 5/14 (Week 36) Objectives : 1. Define gene pool, phenotype frequency, and genotype frequency. 2. State the Hardy-Weinberg Principle. 3. Describe.

Do Now: 5/14 (Week 36) Objectives : 1. Define gene pool, phenotype frequency, and genotype frequency. 2. State the Hardy-Weinberg Principle. 3. Describe.
Genetic Drift Random change in allele frequency –Just by chance or chance events (migrations, natural disasters, etc) Most effect on smaller populations.

Genetic Drift Random change in allele frequency –Just by chance or chance events (migrations, natural disasters, etc) Most effect on smaller populations.
The Hardy-Weinberg Principles Changing Populations.

The Hardy-Weinberg Principles Changing Populations.

Similar presentations

Ads by Google