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Population Genetics and Multifactorial Inheritance 2002 • • • • • • • Consanguinity Genetic drift Founder effect Selection Mutation rate Polymorphism Balanced polymorphism • Hardy-Weinberg Equilibrium Hardy-Weinberg Equilibrium • Explains why, In a large population with random mating: • 1. Allele frequencies do not change from generation to generation • 2. Genotype frequencies are determined by allele frequencies at that locus 1 2 Note error in “AA offspring” footer ! 3 Allele frequencies in X-linked disorders • Males are hemizygous for the X-chromosome: therefore frequency of affected males = frequency of the mutant allele, q • For rare XLR disorders, frequency of heterozygous carrier females is twice the frequency of affected males, or 2q • Frequency of homozygous females is very low, q_ Applications of HWE • Determination of allele frequency and heterozygote carrier frequency in a population for which the frequency of the trait is known 4 Hemophilia A and Parahemophilia • Hemophilia A: – XLR – Frequency 1/5000 – Female carriers 1/2500 • Parahemophilia – Rare AR – Frequency 1/1,000,000 – Heterozygote carrier frequency 1/500 Factors that alter gene frequency • • • • Small populations/ Non-random mating Selection Mutation Migration and gene flow 5 Coefficient of relationship • • • • Parent-child Siblings Uncle-niece First cousins First First Second Third _ _ _ 1/8 Selected Michigan Marriage Laws (Amended 1956) SEC 3. No man shall marry his mother, grandmother, daughter, granddaughter, stepmother, grandfather’s wife, son’s wife, grandson’s wife…..or cousin of the first degree. 6 Genetic Drift/ Founder Effect Single (few) founder mutations • Finns (“located on the edge of the populated world”) – Indo-European immigration 2000 years ago – Population of 50,000 in 12th century, 5 million today • Ashkenazim – Migration to Rhineland in 9th century, to Eastern Europe in 14th century – Population 10-20,000 in Poland in 16th century, 11M worldwide today – Repeated “bottlenecks” (pogroms) • Amish 7 Factors that alter gene frequency • • • • Small populations/ Non-random mating Selection Mutation Migration and gene flow Selection • Biological fitness (f) • Positive and negative selection • Selection on AD, AR, XLR 8 Factors that alter gene frequency • • • • Small populations/ Non-random mating Selection Mutation Migration and gene flow Mutation • Effect of gene size • Effect of paternal age • Balance between introduction of new mutant alleles by mutation and removal by negative selection 9 Factors that alter gene frequency • • • • Small populations/ Non-random mating Selection Mutation Migration and gene flow Migration and gene flow • Tracking human migrations • Cohanim • Lemba 10 Polymorphism • The occurrence of two or more genetically determined alternative phenotypes in a population at such a frequency that the rarest could not be maintained by recurrent mutation alone • Practically---a genetic locus is considered polymorphic if one or more of the rare alleles has(have) a frequency of at least 0.01. • Examples: MHC, SNPs, SSRs Balanced polymorphism • Balance of positive and negative selection Malaria and genetic disorders of red blood cells 11 Multifactorial Inheritance Complex Common Diseases 12 Evidence for Genetic Factors in Common Complex Diseases • Familial aggregation • Twin studies • Mendelian forms of disease Familial Aggregation 13 Increased risk to relatives: _R • _S – IDDM – NIDDM 10-15 4 • _1 – Schizophrenia – Autism 10 ~100 MD (and MD2B): A chronic condition with significant physical, mental, emotional, and financial consequences • A a first degree relative (sib,parent) • B a second degree relative (aunt,uncle, grandparent • C More than one 1st and/or 2nd degree relative • D No affected 1st or 2nd degree relatives 14 Evidence for Genetic Factors in Common Complex Diseases • Familial aggregation • Twin studies • Mendelian forms of disease Twin Studies 15 Twin studies in infectious disease • • • • Tuberculosis (USA) Leprosy (India) Poliomyelitis (USA) Hepatitis B (Taiwan) • • • • MZ DZ 62% 52% 36% 35% 18% 22% 6% 4% Evidence for Genetic Factors in Common Complex Diseases • Familial aggregation • Twin studies • Mendelian forms of disease 16 Diabetes Mellitus Maturity onset diabetes of the young (MODY) Association and Linkage • ASSOCIATION of a specific allele at a genetic locus with disease in a population – Candidate gene • LINKAGE. Co-segregation in families of a marker locus, regardless of specific allele, with disease. 17 Implications • Identification of genetic markers of liability to common complex disease. • Environmental triggers have greatest impact on genetically predisposed. • Identification of susceptible individuals aids identification of environmental triggers. • Medical intervention can be focused on those at greatest risk. Threshold Model 18 Predictions from Threshold Model • Recurrence risks are average • Risk increases with # of affected relatives • Risk increases with severity of malformation • Differential risk increases as frequency decreases • Sex differences 19 20 Affected Sib Pair 21