• Introduction
• 63 min
  1. Drosophila genetics - the first 25 years

  • Prof. Dan Lindsley
• Establishment of the Primary Body Axes
• 28 min
  2. Homeotic genes in Drosophila's bithorax complex - The legacy of Ed Lewis

  • Prof. Francois Karch
• 30 min
  3. Limb development: how Drosophila genetics can be used to understand pattern formation

  • Prof. Konrad Basler
• Cell Type Specification and Organ Systems
• 63 min
  4. From germ cell specification to gonad formation

  • Prof. Ruth Lehmann
• 37 min
  5. Drosophila stem cells

  • Prof. Michael Buszczak
• 46 min
  6. Legacy of drosophila genetics: female germline stem cells

  • Prof. Michael Buszczak
• 34 min
  7. Intestinal stem cell-mediated repair in Drosophila 1

  • Prof. Tony Ip
• 30 min
  8. Intestinal stem cell-mediated repair in Drosophila 2

  • Prof. Tony Ip
• 43 min
  9. The miracle of morphogenesis, cell adhesion, polarity and cytoskeletal regulation

  • Prof. Mark Peifer
• 34 min
  10. Axon guidance in Drosophila

  • Prof. John Thomas
• 35 min
  11. Development and physiology of the heart

  • Prof. Rolf Bodmer
• 37 min
  12. Identification of host defenses in the Drosophila gut using genome-scale RNAi

  • Prof. Dominique Ferrandon
• Genome Organization and Function
• 53 min
  13. The genetic analysis of meiosis in Drosophila melanogaster females

  • Prof. R. Scott Hawley
• 46 min
  14. Genome scale analysis of cellular processes using RNAi

  • Dr. Amy Kiger
• 36 min
  15. Dorsal-ventral patterning of the Drosophila embryo

  • Prof. Mike Levine
• 34 min
  16. Bone morphogenetic protein (BMP) signaling in drosophila: from germline to early embryogenesis

  • Dr. Helena Araujo
• 27 min
  17. Genome-wide pooled CRISPR screen in arthropod cells

  • Prof. Norbert Perrimon
• Behavior
• 40 min
  18. The development of the peripheral nervous system in the fruitfly Drosophila

  • Prof. Hugo Bellen
• 54 min
  19. Genetics of chemosensory transduction: taste and smell

  • Dr. Leslie Vosshall
• 72 min
  20. Cracking the case of circadian rhythms by Drosophila genetics

  • Prof. Jeffrey C. Hall
• 46 min
  21. Sleep in Drosophila

  • Dr. Ralph Greenspan
• 91 min
  22. Drosophila's contribution to the genetics of learning and memory

  • Prof. Tim Tully
• 34 min
  23. Drosophila as a model for drug addiction

  • Prof. Ulrike Heberlein
• Mechanism of Human Disease
• 65 min
  24. Cross-genomic analysis of human disease genes

  • Prof. Ethan Bier
• 56 min
  25. Human neurodegenerative disease: insights from Drosophila genetics

  • Prof. Nancy Bonini
• 21 min
  26. Metastasis of Drosophila tumors

  • Prof. Allen Shearn
• 
  27. Rac-enhanced CAR immunotherapy: RaceCAR

  • Prof. Denise Montell
• 34 min
  28. Control of tissue growth: elucidation of the Hippo signaling pathway

  • Dr. Duojia Pan
• Evolution of Adaptive Novelties
• 56 min
  29. The evolution of morphological novelty

  • Prof. Nipam Patel
• 36 min
  30. The genetic architecture of complex traits: lessons from Drosophila

  • Prof. Trudy Mackay
• Archived Lectures *These may not cover the latest advances in the field
• 25 min
  31. Using gene expression information to provide insights into patterning and differentiation

  • Prof. Angelike Stathopoulos
• 49 min
  32. Regulation of gastrulation in Drosophila

  • Prof. Dr. Maria Leptin
• 31 min
  33. microRNA function in stem cells

  • Prof. Hannele Ruohola-Baker

Printable Handouts

PDF

Navigable Slide Index

1. Introduction
2. Short range interaction with surrounding cells
3. DSS induces injury in mammals, lethality in flies
4. DSS feeding increases enteroblast number
5. Tissue injury caused by DSS
6. Hippo/Yorki tumor suppressor pathway (1)
7. Hippo/Yorki tumor suppressor pathway (2)
8. Hippo/Yorki pathway mediates ISC proliferation
9. Bleomycin as a tissue damaging agent
10. Bleomycin damaging mechanism
11. Enterocytes damage can stimulate ISC division
12. Enterocytes regulate ISC proliferation
13. Long range interactions
14. Insulin receptor activation to midgut proliferation
15. Activated insulin receptor expression
16. InR pathway mutants suppress stem cell division
17. Systemic and local insulin regulate ISC division
18. ISC regulation and tissue repair - summary
19. Acknowledgments

Topics Covered

• The adult Drosophila midgut contains tissue specific intestinal stem cells (ISCs)
• ISCs are the only dividing cells in the midgut and are responsible for maintaining midgut homeostasis and regeneration
• The ISC division gives rise to a renewed stem cell and an enteroblast, which can differentiate into secretory enteroendocrine cells or absorptive enterocytes
• Intrinsic factors such as Tuberous Sclerosis Complex and Myc coordinate the growth and division of ISCs
• Extrinsic factors such as Epidermal Growth Factor from surrounding cells and the interaction with basement membrane also regulate the rate of ISC division
• Insulin secreted from CNS function as a long-range growth factor to control ISC activity and therefore intestinal tissue homeostasis

Links

Series:

• The Legacy of Drosophila Genetics

Categories:

• Cell Biology

Therapeutic Areas:

• Gastroenterology & Nephrology

Talk Citation

Publication History

• Published on January 5, 2014
• Reviewed on September 25, 2017

Financial Disclosures

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