1. Define the following terms:  Genetic drift: random change in a gene frequency that is caused by a series of chance occurrences that cause an allele.

Slides:

Advertisements

Similar presentations

Day 5: Causes of Microevolution

Advertisements

How do we know if a population is evolving?

B-SC: Students will demonstrate an understanding of the history of life on Earth.

Allele Frequencies and the Gene Pool

Hardy-Weinberg Equilibrium

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

 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.

Population Genetics.

PREWORK LIST the 5 conditions necessary for the Hardy-Weinberg equation DEFINE: genetic drift, fixation, bottleneck, founder effect, gene flow REVIEW:

Hardy-Weinberg Equation Measuring Evolution of Populations

Evolution and 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.

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.

The Hardy-Weinberg Equation

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

Hardy-Weinberg Equilibrium Honors Biology. Is evolution occurring right now?  How might a scientist tell if evolution is occurring within a population?

Review of Natural Selection Types. Effects of Selection See Fig Coat color.

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.

HARDY-WEINBERG CALCULATIONS Evolution & Homeostasis 2012.

How do we know if a population is evolving?

BIOZONE: due Wed 11/05 BIOZONE: due Wed11/05

SC STANDARD B-5: Students will demonstrate an understanding of biological evolution and the diversity of life.

Evolution of Populations Chapter 16. Gene and Variation Although Mendel and Darwin both worked in the 1800’s, they were not able to share information.

Evolution How Natural Selection Shapes Populations Chapter 17 Miller Levine Honors Biology NNHS 2015.

Ch 16 Evolution of populations

Mechanisms of Evolution Hardy-Weinberg Law.  The Hardy–Weinberg principle states that the genotype frequencies in a population remain constant or are.

Evolution as Genetic Change in Populations. Learning Objectives  Explain how natural selection affects single-gene and polygenic traits.  Describe genetic.

Chapter 17: Evolution of Populations

 A llele frequencies will remain constant unless one or more factors cause the frequencies to change.  If there is no change, there is no evolving.

Evolution of Populations Evolution as Genetic Change.

End Show Slide 1 of 40 Copyright Pearson Prentice Hall 16-2 Evolution as Genetic Change.

Chapter 16 Population Genetics and Speciation. Objectives CLE Explain how genetic variation in a population and changing environmental conditions.

Directional selection When individuals at one end of the curve have a higher fitness than individuals in the middle or at the other end.

Biology 3201 Chapters The Essentials. Micro vs. Macro Evolution Micro Evolution Evolution on a smaller scale. This is evolution within a particular.

A change in allele frequency. Q: How do scientists know when this occurs?  A: They compare it to a non-changing population  = Ideal population (like.

Evolutionary Change in Populations

Hardy-Weinberg Equilibrium Population Genetics and Evolution.

Chapter 16: Evolution of Populations

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

Godfrey Hardy ( ) Wilhelm Weinberg ( ) Hardy-Weinberg Principle p + q = 1 Allele frequencies, assuming 2 alleles, one dominant over the.

Chapter 16 Section Assessments: Due Fri. 5/2 Chapter 16.1 SA: p. 396 (1-5) Chapter 16.2 SA: p. 402 (1-5) Chapter 16.3 SA: p. 410 (1-2) Chapter 16 Assessment:

GENETIC EVOLUTION. Gene Pool All genetic information from a population of a specific species.

POINT > Define Hardy-Weinberg Equilibrium POINT > Use Hardy-Weinberg to determine allele frequencies POINT > Define “heterozygous advantage” POINT > Describe.

Hardy Weinberg Equilibrium. What is Hardy- Weinberg? A population is in Hardy-Weinberg equilibrium if the genotype frequencies are the same in each generation.

Meet My Good Friends Hardy and Weinberg!! Biologists use models to study populations. Biologists use models to study populations. Hardy and Weinberg.

Hardy-Weinberg Equilibrium Honors Biology. Is evolution occurring right now?  How might a scientist tell if evolution is occurring within a population?

Bellwork  Define in your own words  Allele  Homozygous  Heterozygous  Recessive  Dominant.

11.1 Genetic Variation Within Population KEY CONCEPT A population shares a common gene pool.

ALLELE FREQUENCY. ALLELE FREQUENCY HARDY - WEINBERG A population that is not changing genetically is said to be at Hardy–Weinberg equilibrium The assumptions.

Hardy-Weinberg Equilibrium

Evolution of Populations

Evolution and Alleles Reginald Punnett Wilhelm Weinberg G. H. Hardy

Evolution and Populations –Essential Questions p

Hardy-Weinberg Theorem

HARDY WEINBERG.

Evolution Notes March

Population Genetics and Evolution

Natural Selection on Single Gene Traits

Unit 16 Notes: Page 49 Test Date: 5/24/18

GENE POOL All the genes of all members of a particular population.

Hardy Weinberg What the heck is that?.

1. Sexual Selection In order for random mating to occur, all members of the population must have equal.

Lecture: Natural Selection and Genetic Drift and Genetic Equilibrium

LEARNING OBJECTIVE 3. Differentiate between different types of Natural Selection and how they impact Evolution.

Hardy Weinberg.

9.6 Evolution as Genetic Change in Populations

4-Population Genetics Notes

HARDY-WEINBERG & EVOLUTION

Presentation transcript:

1. Define the following terms:  Genetic drift: random change in a gene frequency that is caused by a series of chance occurrences that cause an allele to become more or less common in a population  Gene pool: a stock of different genes in an interbreeding population  Genetic equilibrium: situation in which alleles frequencies in a population remain the same (no evolution occurring) 2. What are the five conditions for Hardy-Weinberg equilibrium? 1. No mutations occur 2. Immigration and emigration do not occur 3. Population is very large 4. Mating is random 5. No natural selection occurs (populations must be isolated)

3. What do each of the variables represent in the Hardy-Weinberg equation? a) P: dominant alleles b) Q: recessive alleles c) q 2 : homozygous recessive d) 2pq: heterozygous e) p 2 : homozygous dominant

4. What occurs in each of the selections below and draw a graph on the side to show this selection a. Disruptive selection: when individuals in the extreme ends of the curve have a higher fitness than the individuals in the middle of the curve (average phenotypes disappear) b. Stabilizing selection: when individuals near the center of the curve are better adapted to the environment (extreme phenotypes disappear) c. Directional selection: when the environment changes and one extreme phenotypes has a higher fitness (one extreme phenotype will disappear)

5. You have sampled a population in which you know that the percentage of the homozygous recessive genotype (aa) is 36%. Using that 36%, calculate the following: a. The percent of the "aa" genotype. b. The frequency of the "a" allele. c. The frequency of the "A" allele. d. The percent of the genotypes "AA" e. The percent of the genotypes "Aa” f. The percent of the dominant phenotype g. The percent of the recessive phenotype

 There are 100 students in a class. Ninety-six did well in the course whereas four blew it totally and received a grade of F. Sorry. In the highly unlikely event that these traits are genetic rather than environmental, if these traits involve dominant and recessive alleles, and if the four (4%) represent the frequency of the homozygous recessive condition, please calculate the following:  The frequency of the recessive allele.  The frequency of the dominant allele.  The frequency of heterozygous individuals.

 The ability to taste PTC is due to a single dominate allele "T". You sampled 215 individuals in biology, and determined that 150 could detect the bitter taste of PTC and 65 could not. Calculate all of the potential frequencies.  q 2  Q  P  p 2  2pq