Abstract
BackgroundStudying functional divergences between paralogs that originated from genome duplication is a significant topic in investigating molecular evolution. Genes that exhibit basal level cyclic expression patterns including circadian and light responsive genes are important physiological regulators. Temporal shifts in basal gene expression patterns are important factors to be considered when studying genetic functions. However, adequate efforts have not been applied to studying basal gene expression variation on a global scale to establish transcriptional activity baselines for each organ. Furthermore, the investigation of cyclic expression pattern comparisons between genome duplication created paralogs, and potential functional divergence between them has been neglected. To address these questions, we utilized a teleost fish species, Xiphophorus maculatus, and profiled gene expression within 9 organs at 3-h intervals throughout a 24-h diurnal period.ResultsOur results showed 1.3–21.9% of genes in different organs exhibited cyclic expression patterns, with eye showing the highest fraction of cycling genes while gonads yielded the lowest. A majority of the duplicated gene pairs exhibited divergences in their basal level expression patterns wherein only one paralog exhibited an oscillating expression pattern, or both paralogs exhibit oscillating expression patterns, but each gene duplicate showed a different peak expression time, and/or in different organs.ConclusionsThese observations suggest cyclic genes experienced significant sub-, neo-, or non-functionalization following the teleost genome duplication event. In addition, we developed a customized, web-accessible, gene expression browser to facilitate data mining and data visualization for the scientific community.
Highlights
Studying functional divergences between paralogs that originated from genome duplication is a significant topic in investigating molecular evolution
Teleost fishes make up 96% of all extant fish species and exhibit extreme biodiversity that is thought to be a result of the teleost specific whole genome duplication (TGD) event that is estimated to have occurred ≈375 million years ago [1,2,3,4]
Researchers should take the complexity of basal gene expression into consideration when investigating biological effects when studying genetic functions for a few simple reasons: (a) Target gene(s) of interest need to be expressed in target organ(s) in order for functional tests, such as knock-down or knock-outs, to be interpreted; (b) Gene(s) that may functionally compensate a target of interest need to be taken into account; (c) Since basal gene expression is often time-dependent and external stimulus related, a proper time to apply an experimental intervention needs to be determined
Summary
Studying functional divergences between paralogs that originated from genome duplication is a significant topic in investigating molecular evolution. The investigation of cyclic expression pattern comparisons between genome duplication created paralogs, and potential functional divergence between them has been neglected. To address these questions, we utilized a teleost fish species, Xiphophorus maculatus, and profiled gene expression within 9 organs at 3-h intervals throughout a 24-h diurnal period. Teleost fishes make up 96% of all extant fish species and exhibit extreme biodiversity that is thought to be a result of the teleost specific whole genome duplication (TGD) event that is estimated to have occurred ≈375 million years ago [1,2,3,4]. There are many other instances where basal gene expression at first appear to exhibit random patterns, yet later are shown to reflect a dynamic response to an extrinsic temporal stimuli, such as light-dark switching, feeding and other subtle adaptations to environmental conditions [14,15,16,17,18,19]
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