• Introduction to Protein Folding and Misfolding
• 69 min
  1. Protein folding and misfolding: from theory to therapy

  • Prof. Christopher Dobson
• Stability and Kinetics of Protein Folding
• 55 min
  2. Mechanisms of protein folding reactions

  • Prof. Thomas Kiefhaber
• Protein Folding Theory
• 53 min
  3. Mapping disordered proteins with single-molecule FRET

  • Dr. Hagen Hofmann
• Protein Folding Simulations
• 36 min
  4. Protein folding

  • Prof. Eugene Shakhnovich
• 42 min
  5. Simulating protein folding with full atomistic detail

  • Prof. Vijay Pande
• 58 min
  6. Molecular dynamics simulations of protein dynamics, unfolding and misfolding

  • Prof. Valerie Daggett
• Protein Folding Inside the Cell: Chaperones
• 42 min
  7. Protein folding Inside the cell: macromolecular crowding and protein aggregation

  • Prof. Emeritus R. John Ellis
• 34 min
  8. Chaperone mechanisms in cellular protein folding

  • Prof. Dr. F. Ulrich Hartl
• 60 min
  9. Quality control of proteins mislocalized to the cytosol

  • Dr. Ramanujan Hegde
• Protein Misfolding and Disease
• 44 min
  10. Protein aggregation, metals and oxidative stress in neurodegenerative diseases

  • Prof. David Allsop
• Protein Design
• 33 min
  11. Designing proteins with life sustaining activities 1

  • Prof. Michael Hecht
• 24 min
  12. Designing proteins with life sustaining activities 2

  • Prof. Michael Hecht
• 48 min
  13. Folding and design of helical repeat proteins

  • Prof. Lynne Regan
• 44 min
  14. Design and engineering of zinc-finger domains

  • Prof. Jacqui Matthews
• 47 min
  15. Prediction and design of protein structures and interactions

  • Prof. David Baker
• Amyloid Fibrils: Structure, Formation and Nanotechnology
• 39 min
  16. Amyloid fibrils as functional nanomaterials

  • Prof. Juliet Gerrard
• 37 min
  17. Functional amyloid fibrils from fungi and viruses

  • Prof. Margaret Sunde
• Intrinsically disordered Proteins
• 40 min
  18. Fuzzy protein theory for disordered proteins

  • Prof. Monika Fuxreiter
• Intersection of RNA, translation and protein aggregation.
• 47 min
  19. Expanding roles of RNA-binding proteins in neurodegenerative diseases

  • Prof. Aaron D. Gitler
• Proteostasis
• 49 min
  20. Adapting proteostasis to ameliorate aggregation-associated amyloid diseases

  • Dr. Jeffery W. Kelly
• Archived Lectures *These may not cover the latest advances in the field
• 60 min
  21. Amyloidosis: disease caused by amyloid

  • Prof. Mark Pepys
• 34 min
  22. Protein folding and dynamics from single molecule spectroscopy

  • Prof. Dr. Benjamin Schuler
• 41 min
  23. Prion diseases

  • Prof. Fred Cohen
• 31 min
  24. Basic studies of protein folding and stability: the folding of related protein families

  • Dr. Jane Clarke
• 38 min
  25. Titin I27: a protein with a complex folding landscape

  • Dr. Jane Clarke
• 49 min
  26. Novel proteins from designed combinatorial libraries

  • Prof. Michael Hecht
• 47 min
  27. Fast folding dynamics of small proteins: placing limits on diffusional limits

  • Dr. Stephen Hagen
• 35 min
  28. The sequence determinants of amyloid fibril formation

  • Prof. Fabrizio Chiti

Printable Handouts

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Navigable Slide Index

1. Introduction
2. Protein aggregates (Neurodegenerative diseases)
3. Amyotrophic Lateral Sclerosis (ALS)
4. Aggregated protein(s) in ALS
5. Ubiquitinated TDP-43 in FLD and ALS
6. TDP-43 mutations linked to ALS
7. What are the cellular pathways affected?
8. Which biological model to choose?
9. TDP-43 aggregation and toxicity in yeast cells
10. Yeast screens to define TDP-43 toxicity in ALS
11. Yeast screen for modifiers of TDP-43 toxicity
12. Comparing hits from TDP-43 and alpha-synuclein
13. 41 verified TDP-43 suppressors and enhancers
14. PBP1 overexpression enhances TDP-43 toxicity
15. PBP1 deletion suppresses TDP-43 toxicity
16. Ataxin-2 is a polyglutamine disease gene (1)
17. Ataxin-2 modulates TDP-43 toxicity (1)
18. Ataxin-2 modulates TDP-43 toxicity (2)
19. Perturbed ataxin-2 localization in motor neurons
20. Ataxin-2 is a polyglutamine disease gene (2)
21. The ataxin-2 gene
22. Ataxin-2 and ALS?
23. Are polyQ repeats in ataxin-2 linked to ALS?
24. Intermediate-length ataxin-2 polyQ expansions
25. Ataxin-2 is an ALS disease gene
26. Stress granules in ALS pathogenesis (1)
27. Ataxin-2 reduction & stress granule maturation
28. Ataxin-2 and TDP-43 in ALS
29. Lowering ataxin-2 levels
30. Reducing ataxin-2 levels extends survival
31. Reducing ataxin-2 improves motor performance
32. Lowering ataxin-2 eliminates TDP-43 pathology
33. Antisense oligonucleotides (ASOs) & ataxin-2
34. Ataxin-2 ASO treatment extends survival
35. Pathological inclusions in ALS and FTD
36. Towards ataxin-2 as an ALS therapeutic target
37. Other genes from yeast screen
38. Another RNA-binding protein linked to ALS
39. FUS aggregation and toxicity in yeast
40. Rethinking ALS: The FUS about TDP-43
41. More TDP-43 and FUS-like genes
42. 35 RNA-binding proteins aggregate and are toxic
43. Mammalian prions
44. Yeast prions
45. FUS and TDP-43 prion-like domains
46. Prion-like domains (1)
47. Prion-like domains (2)
48. Just the tip of the iceberg
49. Expanding the RNA-binding protein landscape
50. Stress granules in ALS pathogenesis (2)
51. Stress granules in ALS pathogenesis (3)
52. Can we use yeast to study other ALS genes too?
53. Genome wide association studies
54. Manhattan plot
55. Published GWAS through 07/2012
56. GWAS links 9p21 to ALS (1)
57. GWAS links 9p21 to ALS (2)
58. GWAS links 9p21 to ALS (3)
59. GWAS links 9p21 to ALS (4)
60. How do GGGGCC expansions cause FTLD/ALS?
61. RAN translation in Huntington disease
62. C9orf72 sense and antisense transcripts
63. RAN translation in yeast
64. Toxicity of RNA & dipeptide repeat proteins (1)
65. Arginine-rich C9orf72 dipeptides: toxic in yeast
66. C9orf72 dipeptides: toxic in Drosophila
67. Yeast screens of C9orf72 dipeptide toxicity
68. C9orf72 mutation impairs nuclear transport
69. Toxicity of RNA & dipeptide repeat proteins (2)
70. Nucleo-cytoplasmic transport impairments in ALS
71. Acknowledgments

Topics Covered

• Amyotrophic lateral sclerosis (ALS)
• Genetic causes of ALS
• Role of RNA-binding proteins and stress granules in ALS pathogenesis
• Emerging class of RNA-binding proteins with prion-like domains in neurodegenerative disease
• Mechanisms by which C9ORF72 mutations cause ALS

Links

Series:

• ALS and Other Motor Neuron Disorders
• Protein Folding, Aggregation and Design

Categories:

• Biochemistry
• Clinical Practice
• Neuroscience

Therapeutic Areas:

• Neurology

Talk Citation

Publication History

• Published on November 30, 2017

Financial Disclosures

• Prof. Aaron D. Gitler has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.