Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Classification of Enteric Progenitors in Zebrafish During Development
Document related concepts
Transcript
Classification of Enteric Progenitors in Zebrafish During Development William Montagne Eisen Lab August 17, 2012 Enteric Nervous System (ENS) Background • ENS is the largest part of the Peripheral Nervous System • Intrinsic innervation of the intestinal tract • Modulates gut function • Functions autonomously from Central nervous system • Composed of different subtypes of neurons and glial cells zebrafish Wallace et al. (2005) ENS Cell Origin • Entirely derived from one population of cells. • Enteric progenitors migrate to the foregut. • Continue to migrate and proliferate to populate the entire digestive tract. Enteric Progenitor Markers • Progenitors express specific marker genes (sox10, phox2b and ret) • Key roles in migration, survival and proliferation • In mouse Ascl1 is present in enteric progenitors but not analyzed in zebrafish Aims • Are there distinct subpopulations of enteric progenitors? • Is ascl1a an enteric progenitor marker in zebrafish? • Do the subpopulations change spatially and/or temporally? Methods • • • • • RNA probe synthesis Tissue sectioning Immunohistochemistry Fluorescent in situ Hybridization Fluorescent Microscopy Tg (phox2b:GFP) Aims • Are there distinct subpopulations of enteric progenitors? • Is ascl1a an enteric progenitor marker in zebrafish? • Do subpopulations change spatially and/or temporally? 1. 1. Section phox2b:GFP 2. Stain for marker/GFP 3. Focus on Progenitors around the gut 2. 3. phox2b Colocalization with GFP phox2b Colocalization with GFP 100 phox2b GFP phox2b GFP 90 80 Percent of Progenitors 70 60 50 40 30 20 10 0 phox2b+/GFP+ phox2b+/GFP- phox2b-/GFP+ n=2 Distinct progenitor subpopulations sox10 Colocalization with GFP 70 60 Percent of Progenitors 50 sox10 GFP 40 30 20 sox10 GFP 10 0 sox10+/GFP+ sox10+/GFP- sox10-/GFP+ n=2 Distinct Progenitor Subpopulations ret Colocalization with GFP 80 70 Percent of Progenitors 60 50 40 ret GFP 30 20 10 0 ret+/GFP+ ret+/GFP- ret-/GFP+ n=2 ret GFP Aims • Are there distinct subpopulations of enteric progenitors? • Is ascl1a an enteric progenitor marker in zebrafish? • Do subpopulations change spatially and/or temporally? ascl1a Colocalization with GFP ascl1a Colocalization with GFP 70 60 ascl1a GFP Percent of Progenitors 50 ascl1a 40 30 20 10 0 ascl1a+/GFP+ ascl1a+/GFP- ascl1a-/GFP+ n=2 GFP Colocalization Summary 100 90 80 Percent of Progenitors 70 60 50 40 30 20 10 n=2 0 phox2b+/GFP+ sox10+/GFP+ ret+/GFP+ ascl1a+/GFP+ Aims • Is ascl1a an enteric progenitor marker in zebrafish? • Are there distinct subpopulations of enteric progenitors? • Do subpopulations change spatially and/or temporally? Spatial differences in marker gene expression? Mid-region Rostral Caudal Spatial differences in marker gene expression? Colocalization with GFP 100 90 80 Percent of Progenitors 70 60 Rostral 50 Mid Caudal 40 30 20 10 0 n=2 phox2b+/GFP+ ascl1a+/GFP+ sox10+/GFP+ ret+/GFP+ Summary • ascl1a expressed in enteric progenitors in zebrafish. • Based on marker expression, distinct subpopulations of ENS progenitors exist. • Spatial differences for ascl1a+/GFP+ and ret+/GFP+ subpopulations along the gut Future Directions • Double FISH with the different progenitor markers • FISH at different time points during ENS development • Lineage tracing to investigate functional importance of subpopulations ret+/phox2b+ Neurons sox10+/phox2b+ Neurons Thank You Judith Eisen Julia Ganz Eisen Lab SPUR Program Peter O’Day SPUR Interns NIH zebrafish facility Histology Questions?
