Zebrafish Development PDF

Summary

This document details the key aspects of zebrafish development, including cell rearrangements during gastrulation, mechanisms specifying endoderm and mesoderm, and how the anterior-posterior axis is specified in the brain. The document presents diagrams and figures to illustrate these stages and processes. The figures and diagrams provide a visual representation of the different developmental stages in zebrafish, while the text describes the molecular mechanisms and cellular processes at play.

Full Transcript

Source: Kimmel et al. 1995
Figure 11.35 Discoidal meroblastic cleavage in a zebrafish egg
 EVL – Epithelial; will be sloughed off
Deep cells – will form the embryo
YSL – will direct cell movements during gastrulation
Microtubules – will move maternally deposited determinants
 Maternal determinants establish DV axis in zebrafish in a manner similar to Xenopus

Dorsalizing activity
(e.g., inhibitors of β-catenin degradation)

β-catenin localization to
presumptive dorsal pole

Activation of squint

Kimelman Nature Reviews Genetics 7, 360–372 (May 2006) | doi:10.1038/nri1837
 Xenopus and zebrafish use similar mechanisms to specify endoderm and mesoderm

Frog Xnr Zebrafish squint
and cyclops

Induction of Induction of
mesoderm mesoderm

Kimelman Nature Reviews Genetics 7, 360–372 (May 2006) | doi:10.1038/nri1837

How would you determine if squint and Xnr are related?
 Note the location of
β-catenin: YSL nuclei.

These are the zebrafish “equivalents” of Xnr

These are the zebrafish
“equivalents” BMP and
Wnt inhibitors
Xenopus and zebrafish establish their DV axis and
organizer using similar molecular mechanisms

Koppen and Heisenberg, 2005
Cell movements during gastrulation

E-Cadherin (Attaches EVL to Deep Cells)

Epiboly

4.5 - 5 hpf
Figure 4.7 E-cadherin is required for epiboly in zebrafish

No E-cad ½ E-cad
 Source of mesoderm & endoderm in fish

Germ Ring

Delamination & Ingression
Involution

6 hpf

Involution
 FISH FISH

FISH
FROG

Formation of a dorsal (low) - ventral (high) BMP
signaling gradient is thought to pattern the
neuroectoderm and mesoderm along the DV axis. Koppen and Heisenberg, 2005
 Specifying Endomesoderm: The Frog

Endoderm

Bottom line: In frogs (and Sox17 ?
probably fish) endodermal
factors specify the mesoderm
VegT Xnr Brachyury Mesoderm
(Nodal) &
Eomesodermin

MODEL FOR MESODERM SPECIFICATION IN FROG:
 Mechanical Forces Activate Mesoderm Specifiers in the fish

e.g., latrunculin
A, nocodazole

Brachyury
(aka notail)

No Brachyury Brachyury
(No notail) (Notail)
Casanova (sox32) and sox17 are endodermal markers

Gilbert 9 ed. Fig. 7.43 Pezeron et al., 2008
 In fish, Endodermal cell migration proceeds by way of a Nodal &
Casanova-dependent random walk over the surface of the yolk: the
experiments
I. Enhancer trap screen identifies a locus involved in endoderm specification
 Endodermal cell migration proceeds by way of a Nodal &
Casanova-dependent random walk over the surface of the yolk: the
experiments
II. Activate GFP+/cas+ and RFP+/cas- embryos with Nodal ligands (e.g., Squint)

III. Perform genetic mosaic analysis
AP axis formation in zebrafish

Notail
Notail is the zebrafish equivalent of mammalian brachyury and Xenopus Xbra

112 MYrs
Human

Mouse
450 MYrs
Zebrafish
Recap of cell rearrangements during zebrafish gastrulation

Involution and ingression
 Anterior-posterior axis specification: All about the brain

Cyp26: retinoic acid hydroxylase.
Breaks down RA in the anterior end

cyp26
cyp26

cyp26 FGF, Wnt

Wnt and Fgf
repress expression Cyp26 Otx2
of anterior genes