population genetics Flashcards
population genetics
- The study of genetic variation within populations
- Via the frequency of genes and alleles
- There is huge variation within populations at the nucleotide level
what is a population
- A group of individuals of the same species living in a specific region at the same time
- In this context species refers to individuals who interbreed and produce viable offspring
factors affecting population size
- Birth
- Death
- Immigration
- Emigration
population genetics and evolution
- Mendelian principles are used to understand the genetic composition of a population
- The set of genes is a population is called the gene pool
- A population evolves via changes in the gene pool
measuring genetic variation
How to measure the numbers of genotype and alleles in a population
- Need to be able to tell the difference of the phenotype level
- Differences maybe in coding or non-coding DNA eg polymorphisms used for forensics
calculation genetic frequencies
- For large populations where it is not possible to sample all individuals, a representative sample is usually taken
- The frequency of a genotype or an individual allele can be calculated
- To calculate a genotypic frequency we add up the number of individuals possessing the genotype and divide by the total number of individuals in the population (N)
genotypic frequencies
- For a locus with 3 possible genotypes, AA, Aa and aa, the frequency of each genotype (f) is:
- f(AA)= number of AA individuals/N
- f(Aa)= number of Aa individuals/N
- f(aa)= number of aa individuals/N
- The sum of all the genotypic frequencies always equals 1
what is a frequency
A frequency is a proportion or percentage usually expressed as a decimal fraction
- Eg if 20% of a population has allele A, the frequency of allele A is 0.2
allelic frequencies
- It is the alleles that are passed from generation to generation within a population rather than the genotypes therefore it is important to be able calculate allele frequencies as well
- Can be determined from the genotype frequency
- p= F(A)= f(AA)+ ½ f(Aa)
- q= F(a)= f(aa)+ ½ f (Aa)
- If a locus only has two alleles the frequencies are usually represented by p and q. p+q = 1
allelic frequencies can also be determined by counting observed alleles
- And then calculating the frequency
- Frequency of an allele= number of copies of the allele number of copies of all alleles at locus
blood group examples of allelic frequencies
- 298 MM, 489 MN, 213 NN So for each genotype there are: - 298 MM = 596 M alleles - 489 MN = 489 M alleles + 489 N alleles - 213 NN = 426 N alleles - Add these figures as below to get the frequencies: f(M) = 596 + 489 = 1085 / 2000 = 0.542 f(N) = 489 + 426 = 915 / 2000 = 0.458
mendelian laws- the law of segregation
- States that allele pair separate during gamete formation and randomly unite at fertilisation. Allows formation of heterozygotes and homozygotes
mendelian laws- the laws of independent assortment
- States hereditary factors assort independently during gamete formation
the relationship between genotype and allele frequencies
- The hardy Weingberg law is a mathematical representation of the relationship between genotype and allele frequencies in an ideal population
- Key to forensic genetics
