• 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
• Intrinsically disordered Proteins
• 40 min
  17. Fuzzy protein theory for disordered proteins

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

  • Prof. Aaron D. Gitler
• Proteostasis
• 49 min
  19. 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
  20. Amyloidosis: disease caused by amyloid

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

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

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

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

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

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

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

  • Prof. Fabrizio Chiti

Printable Handouts

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Navigable Slide Index

1. Introduction
2. Overview
3. Introduction to zinc finger domains
4. The zinc finger (ZnF)
5. Classical/Krüppel/CCHH ZnFs (1)
6. Classical/Krüppel/CCHH ZnFs (2)
7. Many other types of ZnF
8. GATA/CCCC ZnF
9. Zinc ribbon
10. LIM domains
11. RING and PHD ZnF
12. CYS2 and FYVE domains
13. Retinoic acid receptor DNA-binding domain
14. TAZ-domain
15. Zn-hook
16. ZnF function
17. Designer zinc-fingers
18. Zinc-less fingers?
19. Zinc-less fingers (1)
20. Zinc-less fingers (2)
21. Zinc-less fingers (3)
22. Adding in Zn(II) (1)
23. Adding in Zn(II) (2)
24. New ZnF folds?
25. The CHANCE domain
26. Minimal folding domains (1)
27. Minimal folding domains (2)
28. Minimal folding domains (3)
29. Minimal folding domains (4)
30. Generate new binding faces
31. ZnF tolerance to mutation: CCHH
32. ZnF scaffolds? (1)
33. Zinc fingers and DNA-binding
34. DNA-protein binding
35. ZnF DNA-binding
36. Krüppel-like DNA-binding (1)
37. Krüppel-like DNA-binding (2)
38. Krüppel-like DNA-binding (3)
39. Designer ZnF: DNA binders - polydactyl approach
40. DNA targeting
41. Base-pair recognition (1)
42. Phage display (1)
43. Phage display (2)
44. Phage display (3)
45. Phage display (4)
46. Phage display (5)
47. Phage display (6)
48. Phage display (7)
49. Base-pair recognition (2)
50. Base-pair recognition (3)
51. Base-pair recognition (4)
52. Base-pair recognition (5)
53. Base-pair recognition (6)
54. Overcoming target-site overlap (1)
55. Overcoming target-site overlap (2)
56. OPEN technology
57. Additional approaches (1)
58. Additional approaches (2)
59. Additional approaches (3)
60. Artificial transcription factors
61. ZnF nucleases (1)
62. ZnF nucleases (2)
63. Designer ZnF: protein binders
64. Specific protein binders
65. ZnF scaffolds? (2)
66. ZnF loops add variation
67. Loop-length variation in PHDs (1)
68. Loop-length variation in PHDs (2)
69. Mi2-PHD
70. Loop-length variation in PHDs (3)
71. ZnF Binding Scaffolds? (1)
72. ZnF Binding Scaffolds? (2)
73. ZnF design/engineering
74. Summary

Topics Covered

• Introduction to zinc finger domains
• Designer zinc-fingers: de novo design and engineering
• Zinc-fingers and DNA binding
• Designer zinc-fingers: DNA-binders
• polydactyl approach
• Designer zinc-fingers: protein-binders

Links

Series:

• Protein Folding, Aggregation and Design

Categories:

• Biochemistry
• Cell Biology
• Methods

Talk Citation

Publication History

• Published on October 1, 2007
• Updated on April 30, 2017

Financial Disclosures

• Prof. Jacqui Matthews has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.