1 / 31

Cytogenetics: Chromosome Mutations, Aberrations & Evolution

Cytogenetics: Chromosome Mutations, Aberrations & Evolution. Chromosomes. Prokaryote Eukaryote. Eukaryotic chromosomes. Human karyotype. Why do we care?. Many diseases and birth defects are a direct result of missing, broken, or extra chromosomes. Down Syndrome Cri du chat Syndrome

omer
Download Presentation

Cytogenetics: Chromosome Mutations, Aberrations & Evolution

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Cytogenetics: Chromosome Mutations, Aberrations & Evolution

  2. Chromosomes Prokaryote Eukaryote

  3. Eukaryotic chromosomes

  4. Human karyotype

  5. Why do we care? Many diseases and birth defects are a direct result of missing, broken, or extra chromosomes. • Down Syndrome • Cri du chat Syndrome • Patau Syndrome

  6. Mutations at the level of the homologous pair • EUPLOIDY: "true" ploidy, meaning two members of each homologous pair. • ANEUPLOIDY: "not true" ploidy, meaning more or fewer members than two of each homologous pair. • MONOSOMY - one homolog; partner is missing • TRISOMY - three homologs • NULLISOMY- one entire homologous pair is missing.

  7. Monosomy and Trisomy

  8. Down Syndrome

  9. How does it happen? Nondisjunction Each chrom. has two chromatids

  10. Trisomy: Patau Syndrome • 1/20,000 births • severe mental retardation • heart and organ defects • polydactyly • death by the age of one year

  11. Structural Changes • Deletions (deficiencies) • Duplications • Inversions • Translocations

  12. Deletions (deficiencies) w

  13. How can chromosomes break? Ionizing radiation (production of free radicals, which act like little atomic "cannon balls", blasting through strands of DNA or c'somes. Chemical insult. Why do they rejoin? Break points of chromosomes are highly reactive ("sticky"), whereas normal ends of c'somes are capped by telomeres, which do not readily bond to other molecules.

  14. Breaks that occur ______ __________________ __________________ will affect both newly formed chromatids, & all daughter cells arising from them. • Breaks that occur ______ ____________________ ____________________ may affect only one chromatid. (Thereafter, only the progeny carrying the broken chromatid will be affected.)

  15. _________________ _________________ Mental retardation Slow motor skill development Low birth weight and slow growth Small head (microcephaly) Partial webbing of fingers or toes Wide-set eyes (hypertelorism) High-pitched cry Cri-du-chat Syndrome

  16. Structural Changes • Deletions (deficiencies) • Duplications • Inversions • Translocations

  17. Duplication

  18. Duplications

  19. Bar eye: caused by duplication

  20. ______________ ______________ ______________ ______________ Duplications: source of evolutionary novelty? Duplication is a source of new genes over evolutionary time: e.g., gene families like globins and MHC genes

  21. Structural Changes • Deletions (deficiencies) • Duplications • Inversions • Translocations

  22. Inversions

More Related