• Models of Investigation
• 41 min
  1. Antifungal innate immunity in C. elegans

  • Dr. Jonathan Ewbank
• 44 min
  2. The anti-microbial defense of Drosophila: a paradigm for innate immunity

  • Prof. Jules Hoffmann
• 38 min
  3. Phagocytosis in the fruit fly, Drosophila melanogaster

  • Dr. Lynda Stuart
• 62 min
  4. Innate immune sensing and response

  • Prof. Bruce Beutler
• 61 min
  5. Macrophages and systems biology

  • Prof. David Hume
• Cell Types and Recruitment
• 71 min
  6. Leukocyte recruitment in vivo

  • Prof. Paul Kubes
• 51 min
  7. Chemokines and inflammation: a critical assessment of therapeutic targets

  • Dr. David Greaves
• 42 min
  8. Eosinophils

  • Prof. Tim Williams
• 63 min
  9. Dendritic cells: linking innate to different forms of adaptive immunity

  • Prof. Ralph Steinman
• 25 min
  10. Plasmacytoid dendritic cells: sensing nucleic acids in viral infection and autoimmunity

  • Prof. Yong-Jun Liu
• 61 min
  11. Innate-like lymphocytes 1

  • Prof. Adrian Hayday
• 41 min
  12. Innate-like lymphocytes 2

  • Prof. Adrian Hayday
• Recognition and Signaling
• 50 min
  13. Colony stimulating factor-1 regulation of macrophages in development and disease

  • Prof. E. Richard Stanley
• 42 min
  14. Fc receptors: linking innate and acquired immunity

  • Prof. Ken G C Smith
• 39 min
  15. Phagocytosis

  • Prof. Joel Swanson
• 44 min
  16. Clearance of apoptotic cells and the control of inflammation

  • Prof. Sir John Savill
• 38 min
  17. Signaling by innate immune receptors

  • Prof. Michael Karin
• 41 min
  18. Nuclear receptors at the crossroads of inflammation and atherosclerosis

  • Prof. Christopher Glass
• Modulation of Effector Responses
• 22 min
  19. Humoral innate immunity and the acute phase response 1

  • Prof. Alberto Mantovani
• 42 min
  20. Humoral innate immunity and the acute phase response 2

  • Prof. Alberto Mantovani
• 54 min
  21. Cytokines regulating the innate response

  • Prof. Anne O’Garra
• 39 min
  22. Arginase and nitric oxide

  • Dr. Peter Murray
• 38 min
  23. Novel lipid mediators in resolution of inflammation

  • Prof. Charles Serhan
• 69 min
  24. Resolvins activate inflammation-resolution programs: a systems approach to resolution

  • Prof. Charles Serhan
• 42 min
  25. Cationic peptides in innate immunity

  • Dr. Dawn Bowdish
• 27 min
  26. Iron metabolism and innate immunity

  • Prof. Tomas Ganz
• Pathogen-Host Interactions
• 46 min
  27. Innate recognition of viruses

  • Prof. Caetano Reis e Sousa
• 50 min
  28. Type I interferons in innate immunity to viral infections

  • Prof. Christine Biron
• 56 min
  29. HIV-1 and immunopathogenesis: innate immunity

  • Prof. Luis Montaner
• 53 min
  30. Understanding and combating tuberculosis

  • Prof. David Russell
• 34 min
  31. The taste of a fungus: recognition of Candida by the innate immune system

  • Prof. Neil Gow
• 51 min
  32. Innate immunity and malaria

  • Prof. Douglas Golenbock
• Health and Disease
• 39 min
  33. Innate immunity in children

  • Prof. David Speert
• 59 min
  34. From bench to bedside: evolution of anti-TNFalpha therapy in rheumatoid arthritis

  • Prof. Sir Ravinder Maini
• 33 min
  35. NOD-like receptors in innate immunity and inflammatory disease

  • Prof. Gabriel Nunez
• 38 min
  36. Paneth cells in innate immunity and inflammatory bowel disease

  • Prof. Satish Keshav
• 36 min
  37. Innate immunity in the brain in health and disease

  • Prof. V. Hugh Perry
• 54 min
  38. The fate of monocytes in atherosclerosis

  • Prof. Gwendolyn Randolph
• 49 min
  39. Macrophages, a cellular toolbox used by tumors to promote progression and metastasis

  • Prof. Jeffrey Pollard
• Archived Lectures *These may not cover the latest advances in the field
• 73 min
  40. Monocyte/macrophages in innate immunity

  • Prof. Emeritus Siamon Gordon
• 32 min
  41. Innate immunity in C. elegans

  • Dr. Jonathan Ewbank
• 51 min
  42. Antigen processing and presentation: modulation by innate immune signals

  • Prof. Colin Watts
• 39 min
  43. NLR genes: infection, inflammation and vaccines

  • Prof. Jenny Ting
• 63 min
  44. Manipulation of innate immune response: lessons from shigella

  • Prof. Philippe Sansonetti
• 35 min
  45. Innate immunity of the lung and adaptation to air breathing at birth

  • Prof. Jeffrey Whitsett

Printable Handouts

PDF

Navigable Slide Index

1. Introduction
2. Short introductory video
3. Conservation of homeostatic mechanisms
4. Why study host-pathogen interactions?
5. Natural habitat of C. elegans
6. Worldwide distribution of C. elegans
7. Characteristics of natural isolates
8. Relationship between nematodes and pathogens
9. Infectious diseases of lower animals and plants
10. Describing diseases of nematodes by fungi
11. Interaction between nematodes and fungi
12. Fungal pathogens of nematodes
13. Infection of C. elegans by the fungus D. coniospora
14. New tools on the fungal side
15. Phylogeny of nematophagous fungi
16. No common mechanism among fungi
17. Countering host defenses: saposins
18. SapA is expressed on spores and at hyphal tips
19. Genes differentially regulated after fungal infection
20. C. elegans-specific genes induced by Drechmeria
21. NLPs, CNCs, FIPs and FIPRs in Caenorhabditis
22. nlp clusters in 3 Caenorhabditis species
23. Expression of nlp cluster in C. elegans
24. nlp-29p::GFP as a reporter of immune response
25. Induction of nlp-29p::GFP
26. D. coniospora penetrates the cuticle
27. Physical injury of C. elegans (1)
28. Physical injury of C. elegans (2)
29. Wounding causes rapid calcium transients
30. The peni, hipi and nipi mutants
31. Multiple snf-12 alleles
32. A STAT protein as a SNF-12 interactor
33. SNF-12 moves towards wound sites
34. Controlling the response of C. elegans to infection
35. RNAi by feeding (1)
36. RNAi by feeding (2)
37. Automated RNAi screen - process
38. Automated RNAi screen
39. A genome-wide RNAi screen results
40. Clone selection
41. Glycan changes sensitivity to pathogen
42. Glycan balance
43. Decreased infectional genes expression clones
44. Pathways controlling C. elegans fungi response
45. dcar-1 required for response to injury and infection
46. Potential DCAR-1 ligands (1)
47. Potential DCAR-1 ligands (2)
48. HPLA increases upon infection
49. HPLA is a derivative of tyrosine
50. HPLA acts as a DAMP via DCAR-1
51. VHP-1 is a negative-regulator of p38
52. Ectopic expression of nlp-29p::GFP
53. Ospf: a phosphthreonine lyase
54. Ospf: a phosphthreonine lyase pathway
55. Akirin in Drosophila
56. Akirin and the NuRD complex
57. nlp genes pathway
58. Global functional analysis
59. Functional analysis of nlp-29
60. Mitochondrial unfolded protein response
61. Conservation of foundling genes
62. An orphan foundling gene
63. Conclusions
64. Thanks to our collaborators
65. Acknowledgments

Topics Covered

• Ecology of C. elegans
• Historical background to host-parasite studies with nematodes
• D. coniospora, a natural pathogen of C. elegans
• Fungal infection and injury induce antimicrobial peptide genes
• Genetics to understand the control of antimicrobial peptide gene expression
• The importance of the nematode surface coat
• Signal transduction pathways that control antimicrobial peptide gene expression

Links

Series:

• Innate Immunity

Categories:

• Immunology

Therapeutic Areas:

• Immunology & Inflammation

Talk Citation

Publication History

• Published on February 28, 2018

Financial Disclosures

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