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Genetics

Genetics. Dr. Joseph de Nanassy Associate Professor, uOttawa Chief of Pathology, CHEO jdenanassy@cheo.on.ca 737-7600 x 2897. Objectives. Develop a basic understanding of the genetic apparatus Comprehend definitions of major genetic abnormalities

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Genetics

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  1. Genetics Dr. Joseph de Nanassy Associate Professor, uOttawa Chief of Pathology, CHEO jdenanassy@cheo.on.ca 737-7600 x 2897

  2. Objectives • Develop a basic understanding of the genetic apparatus • Comprehend definitions of major genetic abnormalities • Correlate molecular abnormalities and genetic defects

  3. Outline I. Definitions Genetic code Chromosomes, Genes, Cell Division Molecular mechanisms II. Abnormal fetal development Malformations, deformations, dysplasias, disruptions III. Perinatal pathology Birth defects Metabolic disorders

  4. The Cell

  5. Nucleus • DNA: arranged in chromosomes (network of granules = nuclear chromatin) • RNA: spherical intranuclear structure(s) - nucleolus / nucleoli

  6. Genetic Code • A series of messages contained in the chromosomes • This code regulates cell functions by way of directing the synthesis of cell proteins • The code corresponds to the structure of the DNA • The code is transmitted to new cells during cell division

  7. DNA structure

  8. DNA replication

  9. mRNA and tRNA

  10. Chromosomes ☺ Exist in pairs – homologous: 22a + 1s ☺ Composed of double coils of DNA ☺ Basic unit: nucleotide phosphate group deoxyribose sugar base: purine (A, G) pyrimidine (T, C)

  11. Genes ☺ Basic units of inheritance ☺ Segments of the DNA chain ☺ Beads on a (chromosome) string ☺ Determine cell properties, both structure and functions unique to the cell

  12. Genome ☺ Sum total of all genes contained in a cell’s chromosomes ☺ Identical in all cells ☺ Not all genes are expressed in all cells ☺ Not all genes are active all the time ☺ May code for enzymes or other functional proteins, structural proteins, regulators of other genes

  13. Gene Product ☺ A protein specified by a gene ☺ Transcribed into mRNA ☺ Translated through tRNA and cytoplasmic ribosomes into protein

  14. Human Genome ☺ 3 billion pairs of DNA nucleotides ☺ 50,000 – 100,000 genes ☺ Genes = 10% of human genome ☺ Exons: parts of the DNA chain that code for specific proteins ☺ Introns: the parts in-between the exons ☺ Both exons and introns are transcribed but only the exons are translated (introns are removed from mRNA before leaving nucleus)

  15. Sex chromosomes ☺ Genetic sex = composition of X and Y ☺ Large X: many genes, many activities ☺ Small Y: almost entirely male sexual diff. ☺ Female: XX, male XY ☺ One X randomly inactivated and nonfunctional after first week of embryonic development ☺ Same inactivated X in descendant cells

  16. Lyon hypothesis

  17. Barr body

  18. Y chromosome ☺ Stains with some fluorescent dyes - bright fluorescent spot in the nucleus ☺ Normal female: sex chromatin body but no fluorescent spot ☺ Normal male: fluorescent spot but no sex chromatin body

  19. Cell Division ☺ Mitosis: somatic cells (PMAT) Daughter cells have the same number of chromosomes as the parent cell. ☺ Meiosis: gametogenesis (1st and 2nd div) Number of chromosomes reduced by half.

  20. Chromatids ☺ Paired chromosomes Before mitosis, the DNA chains duplicate to form new chromosome material. The duplicated chromosomes lie side by side = chromatid. Mitosis = the process by which chromatids separate into chromosomes.

  21. Mitosis ☺ Interphase: DNA duplication to form chromatids just before mitosis ☺ Prophase: centriole migration, mitotic spindle ☺ Metaphase: chromosomes line up in centre, chromatids still joined at centromere ☺ Anaphase: chromatids separate into chromosomes ☺ Telophase: new nuclear membranes form, cytoplasm divides

  22. Mitosis

  23. Meiosis ☺ First meiotic division: duplication of chromosomes to form chromatids ☺ Prophase of meiosis: homologous chromosomes lie side by side over entire length = synapse. Interchange of segments of homologous chromosomes = crossover. 2 Xs side by side just like the autosomes. X and Y end to end – no crossover.

  24. Meiosis ☺ Metaphase: paired chromosomes arrange in middle of cell ☺ Anaphase: homologous chromosomes migrate to opposite poles of the cell; each chromosome is composed of two chromatids, the chromatids are not separated ☺ Telophase: two new daughter cells form; each contains half the chromosome number = reduction of chromosomes by half; interchange of genetic material occurred during synapse

  25. Meiosis ☺ Second meiotic division = mitotic division 2 chromatids separate, 2 new daughter cells are formed with half the normal number of chromosomes

  26. Meiosis

  27. Gametogenesis ☺ Gonads: testes, ovaries; contain ☺ Precursor cells or germ cells; mature into ☺ Gametes: sperm, ova; in gametogenesis ☺ Spermatogenesis, oogenesis

  28. Gametogenesis

  29. Primary follicles

  30. Oogenesis vs. spermatogenesis ☺ One ovum (+ 3 polar bodies) vs. four spermatozoa ☺ Oocytes formed before birth vs. continuous spermatogenesis (‘fresh’ sperm) Prolonged prophase of first meiotic division until ovulation – more frequent congenital abnormalities in ova of older women (longer exposure to potentially harmful environmental influences until meiotic division resumes at ovulation)

  31. Chromosome Analysis

  32. Karyotype

  33. Genes and Inheritance ☺ Locus: specific site of a gene on the chromosome. Since the chromosomes exist in pairs, genes are also paired. ☺ Alleles: alternate forms of a gene can occupy the same locus (homo, hetero) ☺ Recessive gene: expressed only when homozygous ☺ Dominant gene: homo or hetero or co- ☺ Sex-linked gene: X, recessive, hemi

  34. Gene Imprinting ☺ Genes occur in pairs on homologous chromosomes, one from each parent ☺ Different effects of gene whether ♀ or ♂ ☺ Genes modified during gametogenesis ☺ Gene imprinting: additional methyl groups added to DNA molecules ☺ Basic structure identical; in some diseases different expression (behaviour) depending on parent of origin: hereditary disease as a result of imprinting

  35. Genetic Engineering ☺ Insertion of a gene encoding a desired product (e.g. insulin) into a bacterium ☺ Bacterial gene spliced enzymatically, recombinant DNA inserted into plasmid (circular DNA segment in bacterium), dividing bacterial population produces desired protein

  36. Gene Therapy ☺ Normal gene inserted into defective cell ☺ Compensates for the missing or dysfunctional gene, in somatic cells only ☺ Can be inserted into mature cell (ly) ☺ Can be inserted into stem cell (bone marrow) ☺ Used to treat e.g. ADA deficiency, CF, …

  37. Congenital / Hereditary Diseases ☺ Congenital: present at birth ☺ Hereditary (genetic): result of chromosome abnormality or defective gene

  38. Causes of malformations • Chromosomal abnormalities • Gene abnormalities • Intrauterine injury (e.g. drugs, radiation, infection, environmental, etc) • Environmental effect on genetically predisposed embryo

  39. Chromosomal abnormalities ☺ Nondisjunction: failure of homologous chromosomes in germ cells to separate from one another during 1st or 2nd meiotic division ☺ Sex chromosomes or autosomes ☺ Extra chromosome: trisomy (24 or 47) Absent chromosome: monosomy (22 or 45)

  40. Nondisjunction in meiosis

  41. ☺ Chromosome Deletion: Broken piece of chromosome is lost from cell ☺ Translocation: Not lost, just misplaced and attached to another chromosome - reciprocal: between two nonhomologous chromosomes (no loss or gain of genetic material - no loss of cell function) - in germ cells: deficient or excess chromosome material – abnormal zygote

  42. Translocation in gametes

  43. Sex chromosome abnormalities

  44. Turner syndrome

  45. Klinefelter syndrome

  46. Autosomal abnormalities ☺ Loss: aborted embryo ☺ Deletion: congenital anomalies ☺ Trisomy: syndromic, e.g. 21, 13, 18

  47. Trisomy 21 (Down)

  48. T21 causes • Nondisjunction during gametogenesis (95%) • Translocation (few) • Nondisjunction in zygote (rare)

  49. Translocation T21

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