Presentation is loading. Please wait.

Presentation is loading. Please wait.

PV92 PCR/Informatics Kit Population Genetics and Informatics.

Published byGeorgina Harrington Modified over 8 years ago

Similar presentations

Presentation on theme: "PV92 PCR/Informatics Kit Population Genetics and Informatics."— Presentation transcript:

1 PV92 PCR/Informatics Kit Population Genetics and Informatics

2 To estimate frequency of Alu within a population: Amplify Alu insert from representative sample population Amplify Alu insert from representative sample population Calculate the expected allelic and genotypic frequencies Calculate the expected allelic and genotypic frequencies Perform Chi-squared Test Perform Chi-squared Test

3 Alu and Population Genetics Hardy-Weinberg Equilibrium p 2 + 2pq + q 2 = 1 +/+ = p 2 +/- = 2pq -/- = q 2 pp pq qq pq p p q q

4 Calculating Observed Genotypic Frequencies Genotype (p2)(2pq)(q2)Total (N) Genotype +/+ (p2) +/- (2pq) -/- (q2) Total (N) # of people 25 5 8 38 Observed frequency 0.65 0.13 0.21 1.00 Calculation: = +/+ genotypic frequency= # with genotype total number of people (N) =25/38 = 25/38 =.65

5 Calculating Allelic Frequencies Frequency of p = number of p alleles = 55 = 0.72 Frequency of p = number of p alleles = 55 = 0.72 total alleles 76 total alleles 76 Number of p alleles = Number of p alleles = +/+= 25 with two + alleles= 50 + alleles +/+= 25 with two + alleles= 50 + alleles +/-= 5 with one + alleles= 5 + alleles +/-= 5 with one + alleles= 5 + alleles Total= 55 + alleles Total= 55 + alleles Total number of alleles = 2N = 2(38) = 76 Total number of alleles = 2N = 2(38) = 76

6 Using Hardy-Weinberg Determine p 2, 2pq, and q 2 values= Determine p 2, 2pq, and q 2 values= Expected genotypic frequencies p = 0.72, so q = 0.28 since p + q = 1 p 2 +2pq+ q 2 = 1 p = 0.72, so q = 0.28 since p + q = 1 p 2 +2pq+ q 2 = 1 (0.72) 2 + 2 (0.72)(0.28)+ (0.28) 2 = 1 (0.72) 2 + 2 (0.72)(0.28)+ (0.28) 2 = 1 0.52+0.40+ 0.08= 1 0.52+0.40+ 0.08= 1 p2 = 0.52 p2 = 0.52 2pq = 0.40 2pq = 0.40 q2 = 0.08 q2 = 0.08

7 Calculate Expected Number of Genotypes Expected number of genotype = Genotypic frequency x population number (N) GenotypeExpected number +/+ 0.52 x 38 = 20 +/ - 0.40 x 38 = 15 - / - 0.08 x 38 = 3 - / - 0.08 x 38 = 3

8 Chi Squared Test Observed Expected (O-E)2 E E +/+ 25 201.25 +/- 5 156.66 -/- 8 38.33 Total 16.21 Total 16.21 X2 Critical Value (from statistics table) = 5.9 13.21 is above 5.9 so the ratio is not accepted.

9 Allele Server Cold Spring Harbor Lab DNA Learning Center

10 http:// vector.cshl.org Click on Resources

11 Click on Bioservers

12 Enter the Allele Server

13 Allele Server Click on Manage Groups

14 Select Type of Data Select Group

15 Your Group Scroll down to “Your Group”

16 Click on Add Group

17 Fill Out Form

18 Click on Edit Group

19 Fill out Completely

20 Click on Individuals Tab

21 Add Each Student With Information Add as much info as you can Add as much info as you can Genotype ( +/+, +/-, -/- ) Genotype ( +/+, +/-, -/- ) Gender Gender Personal Info Personal Info

22 Click on Done Done

23 Select Your Group Select and then press OK

24 Click to Analyze Click Here Then Click Here

25 Then Look at the Terse and Verbose Tabs

26 Extensions Add each class separately and compare each to see if each is different from each other. Add each class separately and compare each to see if each is different from each other. Compare your group to other existing groups. Compare your group to other existing groups. Have students do manual calculations first and then compare to the computer generated version. Have students do manual calculations first and then compare to the computer generated version.

Download ppt "PV92 PCR/Informatics Kit Population Genetics and Informatics."

Similar presentations

PV92 PCR Informatics Kit: Where did you get those GENES?

PV92 PCR Informatics Kit: Where did you get those GENES?
PV92 PCR/Informatics Kit

PV92 PCR/Informatics Kit
Lab 10: Mutation, Selection and Drift

Lab 10: Mutation, Selection and Drift
Lab 10: Mutation, Selection and Drift. Goals 1.Effect of mutation on allele frequency. 2.Effect of mutation and selection on allele frequency. 3.Effect.

Lab 10: Mutation, Selection and Drift. Goals 1.Effect of mutation on allele frequency. 2.Effect of mutation and selection on allele frequency. 3.Effect.
Lab 3 : Exact tests and Measuring of Genetic Variation.

Lab 3 : Exact tests and Measuring of Genetic Variation.
Lab 3 : Exact tests and Measuring Genetic Variation.

Lab 3 : Exact tests and Measuring Genetic Variation.
Chi square.  Non-parametric test that’s useful when your sample violates the assumptions about normality required by other tests ◦ All other tests we’ve.

Chi square.  Non-parametric test that’s useful when your sample violates the assumptions about normality required by other tests ◦ All other tests we’ve.
Module 12 Human DNA Fingerprinting and Population Genetics p 2 + 2pq + q 2 = 1.

Module 12 Human DNA Fingerprinting and Population Genetics p 2 + 2pq + q 2 = 1.
 Place: New York State  Population: 10,000,000  Character of the disease: caused by the recessive allele and the recessive homozygous genotype is 100%

 Place: New York State  Population: 10,000,000  Character of the disease: caused by the recessive allele and the recessive homozygous genotype is 100%
BIOE 109 Summer 2009 Lecture 5- Part I Hardy- Weinberg Equilibrium.

BIOE 109 Summer 2009 Lecture 5- Part I Hardy- Weinberg Equilibrium.
Population Genetics A.The Hardy-Weinberg principle B.Factors that can change allele frequencies.

Population Genetics A.The Hardy-Weinberg principle B.Factors that can change allele frequencies.
PSY 340 Statistics for the Social Sciences Chi-Squared Test of Independence Statistics for the Social Sciences Psychology 340 Spring 2010.

PSY 340 Statistics for the Social Sciences Chi-Squared Test of Independence Statistics for the Social Sciences Psychology 340 Spring 2010.
Review of Mendelian Genetics and Population Genetics Prep for lab tomorrow: Chapter 5.

Review of Mendelian Genetics and Population Genetics Prep for lab tomorrow: Chapter 5.
Corn Genetics & Chi- Square Goodness of Fit Test

Corn Genetics & Chi- Square Goodness of Fit Test
PoPuLaTiOn GeNeTiCs. PoPuLaTiOn GeNeTiCs ( Heredity was not understood during Darwin’s time) Definition - science of genetic changes in populations. Populations.

PoPuLaTiOn GeNeTiCs. PoPuLaTiOn GeNeTiCs ( Heredity was not understood during Darwin’s time) Definition - science of genetic changes in populations. Populations.
A second example of Chi Square Imagine that the managers of a particular factory are interested in whether each line in their assembly process is equally.

A second example of Chi Square Imagine that the managers of a particular factory are interested in whether each line in their assembly process is equally.
Naked mole rats are a burrowing rodent

Naked mole rats are a burrowing rodent
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 Unit 4 AP Biology.

Population Genetics Unit 4 AP Biology.
Taylor Pruett AP biology 3 rd block.  British mathematician Godfery H. Hardy and German physician Wilhelm Weinberg.

Taylor Pruett AP biology 3 rd block.  British mathematician Godfery H. Hardy and German physician Wilhelm Weinberg.

Similar presentations

Ads by Google