• Introduction
• 37 min
  1. Gene structure, expression and regulation: DNA structure and replication

  • Dr. Carole Sargent
• 29 min
  2. Gene structure, expression and regulation: translation and regulation of gene expression

  • Dr. Carole Sargent
• 34 min
  3. Non-Mendelian genetics: the X chromosome

  • Dr. Carole Sargent
• 28 min
  4. Genomics 101: an introduction to sequencing

  • Dr. Giles Yeo
• Human Genetic Disorders
• 38 min
  5. Mechanisms of human genetic disease

  • Prof. Eamonn Maher
• 29 min
  6. Chromosome disorders: chromosomes intro and tool-kit

  • Dr. Simon Holden
• 34 min
  7. Chromosome disorders: the body of chromosomes

  • Dr. Simon Holden
• 45 min
  8. Autosomal dominant inheritance

  • Dr. Simon Holden
• 48 min
  9. Autosomal recessive inheritance

  • Dr. Simon Holden
• 35 min
  10. Mitochondria in health and disease

  • Prof. Eamonn Maher
• 30 min
  11. Microsatellite and trinucleotide repeat expansion diseases

  • Prof. David C. Rubinsztein
• 35 min
  12. Mosaicism

  • Prof. Eamonn Maher
• Genetic Counselling
• 29 min
  13. Genetic testing: prediction vs. risk

  • Dr. Giles Yeo
• 34 min
  14. Challenges in genetic testing

  • Dr. Heather Hanson Pierce
• 43 min
  15. Social and ethical issues in genetic counselling

  • Prof. Emerita Shirley Hodgson
• 24 min
  16. Taking, drawing, and using a family tree

  • Dr. Heather Hanson Pierce
• 22 min
  17. Complex genetic testing case studies

  • Prof. Emerita Shirley Hodgson
• Genetic and Cancer
• 51 min
  18. Why does pain exist, how does it work, what can go wrong and how is it treated?

  • Dr. Ewan St John Smith
• 50 min
  19. A primer on familial cancer genetics

  • Dr. Marc Tischkowitz
• 28 min
  20. Inherited cancer case studies

  • Prof. Emerita Shirley Hodgson
• 27 min
  21. Cancer risk stratification: the role of polygenic risk scores

  • Prof. Paul Pharoah

Printable Handouts

PDF

Navigable Slide Index

1. Introduction
2. Mendelian genetics – a recap
3. Mendelian genetics
4. Mendel's observations
5. Punnett square method
6. Genes, chromosomes and the X
7. Sex limited traits
8. T.H Morgan’s classic experiment
9. The human sex chromosomes
10. Sex chromosomes in humans
11. Aneuploidies
12. X chromosome aneuploidy in the female
13. X chromosome aneuploidy in the male
14. Summary of sex chromosome aneuploidy (SCA)
15. The aneuploidies show
16. Why is SCA tolerated in humans?
17. Adjusting the dose
18. The problem with the seX chromosomes
19. Evidence for X-inactivation
20. Mary Lyon’s experimentation
21. Evidence for X-inactivation
22. Keeping it under control
23. Mapping XIC and the discovery of the X inactive specific transcript (XIST)
24. The X inactivation center contains multiple co-regulated loci
25. Mechanisms elucidated from mouse embryo and mouse stem cell studies establish Xi model
26. Humans are different
27. Human XIST is complemented by XACT (X active specific transcript from Xq23)
28. Propagation is clonal
29. What defines the X?
30. Gene content: sequence of human X chromosome, Nature, 2005
31. Warning! The inactive X is not completely silent
32. Implications of disease
33. Pattern of inactivation in male and female embryos
34. Recessive X-linked disorders: pedigree structure holds the clues
35. Recessive X linked disorders
36. Contiguous gene deletion syndromes
37. X-linked recessive loci with balanced translocation in females
38. X linked dominant traits
39. Dominant X linked disorders
40. Dominant X linked disorders; male lethal
41. Examples of male lethal conditions
42. Disease classes connect back to Mary Lyon’s observations
43. Summary
44. Thank you

Topics Covered

• Non-mendelian genetics
• X linked disorders
• Sex chromosome disorders

Links

Series:

• Introduction to Human Genetics and Genomics

Categories:

• Genetics & Epigenetics

Talk Citation

Publication History

• Published on June 29, 2021

Financial Disclosures

• Dr. Carole Sargent has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.