PUBLICATION
Pre-gastrula expression of zebrafish extraembryonic genes
- Authors
- Hong, S.K., Levin, C.S., Brown, J.L., Wan, H., Sherman, B.T., Huang, D.W., Lempicki, R.A., and Feldman, B.
- ID
- ZDB-PUB-100504-6
- Date
- 2010
- Source
- BMC Developmental Biology 10: 42 (Journal)
- Registered Authors
- Feldman, Benjamin, Hong, Sung-Kook, Wan, Haiyan
- Keywords
- none
- Datasets
- GEO:GSE8654
- MeSH Terms
-
- Animals
- Egg Yolk/metabolism
- Embryo, Nonmammalian/metabolism*
- Extraembryonic Membranes/metabolism*
- Gene Expression Profiling*
- Oligonucleotide Array Sequence Analysis
- Zebrafish/embryology*
- PubMed
- 20423468 Full text @ BMC Dev. Biol.
Citation
Hong, S.K., Levin, C.S., Brown, J.L., Wan, H., Sherman, B.T., Huang, D.W., Lempicki, R.A., and Feldman, B. (2010) Pre-gastrula expression of zebrafish extraembryonic genes. BMC Developmental Biology. 10:42.
Abstract
BACKGROUND: Many species form extraembryonic tissues during embryogenesis, such as the placenta of humans and other viviparous mammals. Extraembryonic tissues have various roles in protecting, nourishing and patterning embryos. Prior to gastrulation in zebrafish, the yolk syncytial layer - an extraembryonic nuclear syncytium - produces signals that induce mesoderm and endoderm formation. Mesoderm and endoderm precursor cells are situated in the embryonic margin, an external ring of cells along the embryo-yolk interface. The yolk syncytial layer initially forms below the margin, in a domain called the external yolk syncytial layer (E-YSL). RESULTS: We hypothesize that key components of the yolk syncytial layer's mesoderm and endoderm inducing activity are expressed as mRNAs in the E-YSL. To identify genes expressed in the E-YSL, we used microarrays to compare the transcription profiles of intact pre-gastrula embryos with pre-gastrula embryonic cells that we had separated from the yolk and yolk syncytial layer. This identified a cohort of genes with enriched expression in intact embryos. Here we describe our whole mount in situ hybridization analysis of sixty-eight of them. This includes ten genes with E-YSL expression (camsap1l1, gata3, znf503, hnf1ba, slc26a1, slc40a1, gata6, gpr137bb, otop1 and cebpa), four genes with expression in the enveloping layer (EVL), a superficial epithelium that protects the embryo (zgc:136817, zgc:152778, slc14a2 and elovl6l), three EVL genes whose expression is transiently confined to the animal pole (elovl6l, zgc:136359 and clica), and six genes with transient maternal expression (mtf1, wu:fj59f04, mospd2, rftn2, arrdc1a and pho). We also assessed the requirement of Nodal signaling for the expression of selected genes in the E-YSL, EVL and margin. Margin expression was Nodal dependent for all genes we tested, including the concentrated margin expression of an EVL gene: zgc:110712. All other instances of EVL and E-YSL expression that we tested were Nodal independent. CONCLUSIONS: We have devised an effective strategy for enriching and identifying genes expressed in the E-YSL of pre-gastrula embryos. To our surprise, maternal genes and genes expressed in the EVL were also enriched by this strategy. A number of these genes are promising candidates for future functional studies on early embryonic patterning.
Genes / Markers
Expression
Phenotype
Mutations / Transgenics
Human Disease / Model
Sequence Targeting Reagents
Fish
Orthology
Engineered Foreign Genes
Mapping