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Genetic Theory - Overview of the Human Genome

This overview of the human genome discusses the structure of DNA, genetic transmission, sources of natural variation, types of genetic disease, Mendelian segregation, Hardy-Weinberg equilibrium, genetic markers, linkage, haplotypes, and single-gene disorders.

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Genetic Theory - Overview of the Human Genome

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  1. Genetic Theory - Overview Pak Sham International Twin Workshop Boulder, 2005

  2. The Human Genome • 23 Chromosomes, each containing a DNA molecule (Watson and Crick, 1953) • 3  109 base pairs, completely sequenced (Human Genome Project, 2003) • Approximately 24,000 genes, each coding for a polypeptide chain • Approximately 107 common polymorphisms (variable sites, documented in dbSNP database)

  3. Genetic transmission Somatic cells XY Zygote Germ cells Spermatozoa Somatic cells XX Zygote Germ cells Ova Zygote Fertilization Mitosis Meiosis DIPLOID DIPLOID HAPLOID DIPLOID

  4. Sources of Natural Variation Genetic Differences Environmental Differences Individual Phenotypic Differences

  5. Genetic Variation • Chromosomal anomalies • Insertions / Deletions / Translocations • Variable sequence repeats • microsatellites (e.g. CACACA….) • Single nucleotide polymorphisms (SNPs)

  6. Types of Genetic Disease • Mendelian diseases • e.g. Huntington’s disease, cystic fibrosis • A genetic mutation causes the disease • Environmental variation usually irrelevant • Usually rare • Occurs in isolated pedigrees • Multifactorial diseases • e.g. Coronary heart disease, hypertension, schizophrenia • A genetic variant increases the risk of disease • Environmental variation usually important • Often common • Occurs in general population

  7. Single-Gene Disorders • Human Genome Project completed in 2003 • Human Gene Mutation Database contains 44,090 mutations in 1,714 genes • Gene Test web site lists genetic tests for 1,093 diseases • dbSNP Database Build 123 contains 10,079,771 single nucleotide polymorphisms

  8. Autosomal Dominant Disorders

  9. Autosomal Dominant Disorders Aa aa aa Aa aa Aa aa Aa Aa aa

  10. Autosomal Recessive Disorders

  11. Autosomal Recessive Disorders Aa Aa aa Aa Aa AA

  12. X-linked Dominant Disorders

  13. X-linked Dominant Disorders a Aa A a Aa aa

  14. X-linked Recessive Disorders

  15. X-linked Recessive Disorders A Aa a A AA Aa

  16. Mendelian Segregation

  17. Segregation Ratios • First discovered by Gregor Mendel in his experiments on the garden pea (published in 1866 and rediscovered in 1900) • Form the basis of Mendel’s first law: “law of segregation” • Defined as the ratio of affected to normal individuals among the offspring of a particular type of mating.

  18. Mendel’s Experiments AA aa Pure Lines F1 Aa Aa Intercross Aa Aa aa AA 3:1 Segregation Ratio

  19. Mendel’s Experiments F1 Pure line Aa aa Back cross Aa aa 1:1 Segregation ratio

  20. Segregation Ratios

  21. Segregation Ratios

  22. Segregation Ratios

  23. Segregation Ratios

  24. Segregation Ratios

  25. Hardy-Weinberg Law

  26. Parental Frequencies

  27. Mating Type Frequencies(Random Mating)

  28. Offspring Segregation Ratios

  29. Offspring Genotype Frequencies

  30. Offspring Allele Frequencies

  31. Hardy-Weinberg Equilibrium In a large population under random mating: • Allele frequencies in the offspring, denoted asp and q, are the same as those in the parental generation. • Genotype frequencies in the offspring will follow the ratios p2:2pq:q2, regardless of the genotype frequencies in the parents.

  32. Hardy-Weinberg Equilibrium

  33. Hardy-Weinberg Disequilibrium

  34. Genetic Linkage

  35. Genetic Markers • Classical • Mendelian Disorders • Blood groups • HLA Antigens • Molecular genetic • Microsatellites (e.g. CACACA… ) • Single-nucleotide polymorphisms (e.g. C/T)

  36. High-Throughput Genotyping • Extreme multiplexing (multiple markers) • DNA Pooling (multiple samples) Maximum throughput of SEQUENOM system at the HKU Genome Research Centre is 100,000 genotypes / day, at a cost of US$ 0.2 per genotype Cost of genotyping set to decrease further – eventually enabling whole-genome association studies to be done.

  37. Linkage = Co-segregation A3A4 A1A2 A1A3 A2A4 A2A3 Marker allele A1 cosegregates with dominant disease A1A2 A1A4 A3A4 A3A2

  38. Crossing-over in meiosis

  39. Recombination Likely gametes (Non-recombinants) A1 Q1 Parental genotypes A1 Q1 A2 Q2 Unlikely gametes (Recombinants) A1 Q2 A2 Q2 Q1 A2

  40. Recombination fraction Recombination fraction between two loci = Proportion of gametes that are recombinant with respect to the two loci

  41. Double Backcross :Fully Informative Gametes aabb AABB aabb AaBb Aabb AaBb aabb aaBb Non-recombinant Recombinant

  42. Haplotypes

  43. Haplotypes Maternal haplotype Paternal haplotype Genotype

  44. Recombination Parental haplotypes Possible transmitted haplotypes Non-recombinants Single recombinants Double recombinants

  45. Linkage Equilibrium

  46. Linkage Disequilibrium (LD)

  47. Decay of LD Gametes  1- Non-recombinant Recombinant 1-pq-d pq+d pq 1-pq Others AB Others AB Frequency of AB gametes = (1-)(pq+d)+pq = pq+(1-)d

  48. Single-Gene Disorders: Some Historical Landmarks • 1902: First identified single-gene disorder - alkaptonuria • 1956: First identified disease-causing amino acid change: sickle-cell anaemia • 1961: First screening program: phenylketonuria • 1983: First mapped to chromosomal location: Huntington’s disease • 1986: First positionally cloned - chronic granulomatous disease, Duchenne muscular dystrophy • 1987: First autosomal recessive disease cloned –cystic fibrosis

  49. Types of Genetic Disease • Mendelian diseases • e.g. Huntington’s disease, cystic fibrosis • A genetic mutation causes the disease • Environmental variation usually irrelevant • Usually rare • Occurs in isolated pedigrees • Multifactorial diseases • e.g. Coronary heart disease, hypertension, schizophrenia • A genetic variant increases the risk of disease • Environmental variation usually important • Often common • Occurs in general population

  50. Genetic Study Designs

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