Abstract
BackgroundThe gene networks underlying closure of the optic fissure during vertebrate eye development are not well-understood. We use a novel clustering method based on nonlinear dimension reduction with data labeling to analyze microarray data from laser capture microdissected (LCM) cells at the site and developmental stages (days 10.5 to 12.5) of optic fissure closure.ResultsOur nonlinear methods created clusters of genes that mapped onto more specific biological processes and functions related to eye development as defined by Gene Ontology at lower false discovery rates than conventional linear cluster algorithms. Our new methods build on the advantages of LCM to isolate pure phenotypic populations within complex tissues in order to identify systems biology relationships among critical gene products expressed at lower copy number.ConclusionsThe combination of LCM of embryonic organs, gene expression microarrays, and nonlinear dimension reduction with labeling is a potentially useful approach to extract subtle spatial and temporal co-variations within the gene regulatory networks that specify mammalian organogenesis and organ function. Our results motivate further analysis of nonlinear dimension reduction with labeling within other microarray data sets from LCM dissected tissues or other cell specific samples to determine the more general utility of our method for uncovering more specific biological functional relationships.
Highlights
The gene networks underlying closure of the optic fissure during vertebrate eye development are not well-understood
Our proposed analysis relies on Laplacian Eigenmaps [13,14], a geometrical data transformation that provides a new representation of gene expressions still covering essential geometrical behaviors
We identify step 2 with the following supervised procedure: 2.B a) Identifying highly connected genes: Apply an R package for weighted correlation network analysis (WGCNA) [12] to identify genes that are highly connected within the gene regulatory network and that act as hubs
Summary
The gene networks underlying closure of the optic fissure during vertebrate eye development are not well-understood. We use a novel clustering method based on nonlinear dimension reduction with data labeling to analyze microarray data from laser capture microdissected (LCM) cells at the site and developmental stages (days 10.5 to 12.5) of optic fissure closure. The present paper focuses on refinements in the analysis of a temporal series of microarray data obtained from microdissected sites of retinal fissure closure in normal mouse embryos. This data was previously analyzed [8] to identify a putative repressive transcription factor, nlz (zinc finger protein 503), which, when its expression was blocked in zebrafish embryos, led to incomplete optic fissure closure, a coloboma model. The present paper is dedicated to develop a novel pipeline for the analysis of microarray gene expression data that complements standard approaches and provides a list of candidate genes guiding further experimental analysis of genetic variations
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