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- Models of Investigation
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1. Antifungal innate immunity in C. elegans
- Dr. Jonathan Ewbank
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2. The anti-microbial defense of Drosophila: a paradigm for innate immunity
- Prof. Jules Hoffmann
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3. Phagocytosis in the fruit fly, Drosophila melanogaster
- Dr. Lynda Stuart
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4. Innate immune sensing and response
- Prof. Bruce Beutler
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5. Macrophages and systems biology
- Prof. David Hume
- Cell Types and Recruitment
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6. Leukocyte recruitment in vivo
- Prof. Paul Kubes
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8. Eosinophils
- Prof. Tim Williams
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9. Dendritic cells: linking innate to different forms of adaptive immunity
- Prof. Ralph Steinman
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11. Innate-like lymphocytes 1
- Prof. Adrian Hayday
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12. Innate-like lymphocytes 2
- Prof. Adrian Hayday
- Recognition and Signaling
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13. Colony stimulating factor-1 regulation of macrophages in development and disease
- Prof. E. Richard Stanley
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14. Fc receptors: linking innate and acquired immunity
- Prof. Ken G C Smith
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15. Phagocytosis
- Prof. Joel Swanson
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16. Clearance of apoptotic cells and the control of inflammation
- Prof. Sir John Savill
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17. Signaling by innate immune receptors
- Prof. Michael Karin
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18. Nuclear receptors at the crossroads of inflammation and atherosclerosis
- Prof. Christopher Glass
- Modulation of Effector Responses
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19. Humoral innate immunity and the acute phase response 1
- Prof. Alberto Mantovani
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20. Humoral innate immunity and the acute phase response 2
- Prof. Alberto Mantovani
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21. Cytokines regulating the innate response
- Prof. Anne O’Garra
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22. Arginase and nitric oxide
- Dr. Peter Murray
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23. Novel lipid mediators in resolution of inflammation
- Prof. Charles Serhan
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25. Cationic peptides in innate immunity
- Dr. Dawn Bowdish
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26. Iron metabolism and innate immunity
- Prof. Tomas Ganz
- Pathogen-Host Interactions
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27. Innate recognition of viruses
- Prof. Caetano Reis e Sousa
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28. Type I interferons in innate immunity to viral infections
- Prof. Christine Biron
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29. HIV-1 and immunopathogenesis: innate immunity
- Prof. Luis Montaner
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30. Understanding and combating tuberculosis
- Prof. David Russell
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32. Innate immunity and malaria
- Prof. Douglas Golenbock
- Health and Disease
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33. Innate immunity in children
- Prof. David Speert
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34. From bench to bedside: evolution of anti-TNFalpha therapy in rheumatoid arthritis
- Prof. Sir Ravinder Maini
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35. NOD-like receptors in innate immunity and inflammatory disease
- Prof. Gabriel Nunez
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36. Paneth cells in innate immunity and inflammatory bowel disease
- Prof. Satish Keshav
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37. Innate immunity in the brain in health and disease
- Prof. V. Hugh Perry
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38. The fate of monocytes in atherosclerosis
- Prof. Gwendolyn Randolph
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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
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40. Monocyte/macrophages in innate immunity
- Prof. Emeritus Siamon Gordon
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41. Innate immunity in C. elegans
- Dr. Jonathan Ewbank
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43. NLR genes: infection, inflammation and vaccines
- Prof. Jenny Ting
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44. Manipulation of innate immune response: lessons from shigella
- Prof. Philippe Sansonetti
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45. Innate immunity of the lung and adaptation to air breathing at birth
- Prof. Jeffrey Whitsett
Printable Handouts
Navigable Slide Index
- Introduction
- Eosinophils - background
- Eosinophils in disease
- Bronchial challenge with allergen
- Eosinophils in asthma and allergy
- Eosinophil products
- Eosinophils in inflammation and tissue damage
- Eosinophils in tissue remodelling
- IL-5
- IL-5 knockout mouse
- IL-5 antibody treatment in man
- Eosinophil deletion in the mouse
- Th2 lymphocytes regulate eosinophils
- Eosinophils regulate Th2 lymphocytes
- Eosinophil trafficking: adhesion molecules
- VLA-4
- Eosinophil trafficking: chemoattractant
- Detection of eosinophil chemoattractants
- Chemokine nomenclature
- Eosinophil trafficking
- The eotaxins
- The eotaxin receptor
- Characteristics of CCR3
- Comparison of chemotactic effects of eotaxins
- Eoataxin production in the lung
- Eosinophil recruitment in allergic inflammation
- Eotaxin and eosinophil after allergen challenge
- Eosinophils levels in eotaxin deficient mice
- Eotaxin expression in asthma
- Eotaxin in sputum from asthmatic airways
- Eotaxin-1 levels in nasal polyps
- Mechanisms of pulmonary eosinophilia
- Eotaxin inactivated by hookworms proteases
- Effects of eotaxin on the bone marrow
- Eosinophil release induced by eotaxin and IL-5
- Movement of eosinophils after alergen challenge
- Eosinophil recruitment (lung) and release (BM)
- Regulation of eosinophil chemokine signaling
- Eosinophil and neutrophil shape change
- Some have a second eosinophil receptor - CCR1
- Expression levels of CCR1 in MPR / MHR donors
- Eosinophils express receptors CCR3 and CCR1
- Eoataxin receptor antagonists
- Small molecule antagonists of CCR3
- UCB35625 inhibits eosinophil shape change
- UCB35625 is a poor inhibitor of binding
- Small agonists / antagonists of CCR3 in research
- Antibody to eotaxin-1 in allergic rhinitis
- Summary
- Acknowledgements
Topics Covered
- White blood cell containing granules staining pink with eosin and a bilobed nucleus
- Specialised for defence against worm infection
- Accumulate in high numbers in lungs of allergic asthmatic patients
- Also involved in hay fever, allergic eczema etc
- Induce tissue damage and organ dysfunction when inappropriately activated
- Interleukin-5 (IL-5) important for eosinophil production in bone marrow
- Anti-IL-5 antibodies suppress circulating eosinophil numbers
- Eotaxin is a chemoattractant protein involved in recruiting eosinophils to the lung
- Small molecule antagonists have been developed to block the Eotaxin receptor, CCR3, as potential therapeutic compounds
Talk Citation
Williams, T. (2020, May 1). Eosinophils [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 21, 2024, from https://doi.org/10.69645/JEOJ7055.Export Citation (RIS)
Publication History
Financial Disclosures
- Prof. Tim Williams has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
A selection of talks on Immunology
Transcript
Please wait while the transcript is being prepared...
0:00
This is a lecture on eosinophils,
given by Tim Williams of Imperial College,
London.
0:08
Eosinophils are granulocytes with
typically a bilobed nucleus and
granules that stain pink with eosin.
They constitute normally about 1 to
4% of the white cells in the blood,
and can be considerably higher in
allergy and worm parasite infection.
They're produced in the bone marrow, and
the marrow contains precursors and
a reserve of releasable mature cells.
As well as in the blood, eosinophils
also found normally in the GI tract.
0:40
Under disease conditions, eosinophils are
found in response to helminth infection,
in allergic asthma and
also intrinsic asthma.
They're found in the skin in allergic
eczema, and they're also found in
gastrointestinal disorders, for
instance in eosinophilic eosophagitis.
They're found in certain viral
infections and in certain tumors, for
example solid tumors of epithelial origin.
1:09
Individuals will asthma have high
numbers of eosinophils in their lungs.
If you take somebody who's sensitized
to a particular allergen and
challenge them with an aerosol of that
allergen, you have an immediate reaction,
bronchoconstriction reaction.
And this is associated with the activation
of mast cells via IgE fixed to their
surfaces, and the release of mediators
such as histamine and leukotrienes.
After a delay off some two to four hours,
you have a more protracted
bronchoconstriction.
And this is associated with the activation
of T cells, Th2 lymphocytes,
and the accumulation of high
numbers of eosinophils.