Comprehensive characterization of the <Emphasis Type="Italic">cis</Emphasis>-regulatory code responsible for the spatio-temporal expression of <Emphasis Type="Italic">olSix3.2</Emphasis>in the developing medaka forebrain

Background  

Embryonic development is coordinated by sets of cis-regulatory elements that are collectively responsible for the precise spatio-temporal organization of regulatory gene networks. There is little information on how these elements, which are often associated with highly conserved noncoding sequences, are combined to generate precise gene expression patterns in vertebrates. To address this issue, we have focused on Six3, an important regulator of vertebrate forebrain development.     

The limits of subfunctionalization

Background  

The duplication-degeneration-complementation (DDC) model has been proposed as an explanation for the unexpectedly high retention of duplicate genes. The hypothesis proposes that, following gene duplication, the two gene copies degenerate to perform complementary functions that jointly match that of the single ancestral gene, a process also known as subfunctionalization. We distinguish between subfunctionalization at the regulatory level and at the product level (e.g within temporal or spatial expression domains).     

Retention of a Duplicate Gene Through Changes in Subcellular Targeting: An Electron Transport Protein Homologue Localizes to the Golgi

Cytochrome c oxidase (COX), the terminal enzyme complex of the electron transport chain, contains 13 subunits, 3 encoded by mitochondrial DNA and 10 by nuclear. Several of the nuclear subunits, including subunit VIIa, are known to have two tissue- and development-specific isoforms in mammals. A recently identified third member of the gene family, COX7AR, encodes a protein previously thought to function in mitochondria. However, observation of fluorescent pCOX7AR C-terminal fusion proteins in HeLa cells showed that pCOX7AR is localized to the Golgi apparatus. Sequence analyses indicate that the duplication of COX7AR occurred prior to the origin of the Euteleostomi (bony vertebrates) and that pCOX7AR is more highly conserved than the two other isoforms. These results indicate that, after gene duplication and modification of the mitochondrial targeting signal, pCOX7AR was evolutionarily altered to a new and apparently important function in the Golgi. These results also suggest that predictions of function from homology can be misleading and show that specialization and modification of subcellular localization are similar to cis-element subfunctionalization. In cis-element subfunctionalization, complementary null mutations occur to the cis-elements of the descendents of a gene duplication, causing both descendent genes to be obligate. In the process described in this paper, which could be termed subcellular subfunctionalization, complementary null mutations can occur to the subcellular localization signals of the descendants of a gene duplication, causing both descendent genes to be similarly obligate. Noncomplementary null mutations could also uncover an alternate localization, which is the more likely case for pCOX7AR.     

Functional conservation of a forebrain enhancer from the elephant shark (<Emphasis Type="Italic">Callorhinchus milii</Emphasis>) in zebrafish and mice

Background  

The phylogenetic position of the elephant shark (Callorhinchus milii ) is particularly relevant to study the evolution of genes and gene regulation in vertebrates. Here we examine the evolution of Dlx homeobox gene regulation during vertebrate embryonic development with a particular focus on the forebrain. We first identified the elephant shark sequence orthologous to the URE2 cis -regulatory element of the mouse Dlx1/Dlx2 locus (herein named CmURE2). We then conducted a comparative study of the sequence and enhancer activity of CmURE2 with that of orthologous regulatory sequences from zebrafish and mouse.     

Development of a novel data mining tool to find <Emphasis Type="Italic">cis</Emphasis>-elements in rice gene promoter regions

Background  

Information on more than 35 000 full-length Oryza sativa cDNAs, together with associated microarray gene expression data collected under various treatment conditions, has made it feasible to identify motifs that are conserved in gene promoters and may act as cis-regulatory elements with key roles under the various conditions.     

Selective maintenance of Drosophila tandemly arranged duplicated genes during evolution

Background

The physical organization and chromosomal localization of genes within genomes is known to play an important role in their function. Most genes arise by duplication and move along the genome by random shuffling of DNA segments. Higher order structuring of the genome occurs in eukaryotes, where groups of physically linked genes are co-expressed. However, the contribution of gene duplication to gene order has not been analyzed in detail, as it is believed that co-expression due to recent duplicates would obscure other domains of co-expression.

Results

We have catalogued ordered duplicated genes in Drosophila melanogaster, and found that one in five of all genes is organized as tandem arrays. Furthermore, among arrays that have been spatially conserved over longer periods than would be expected on the basis of random shuffling, a disproportionate number contain genes encoding developmental regulators. Using in situ gene expression data for more than half of the Drosophila genome, we find that genes in these conserved clusters are co-expressed to a much higher extent than other duplicated genes.

Conclusions

These results reveal the existence of functional constraints in insects that retain copies of genes encoding developmental and regulatory proteins as neighbors, allowing their co-expression. This co-expression may be the result of shared cis-regulatory elements or a shared need for a specific chromatin structure. Our results highlight the association between genome architecture and the gene regulatory networks involved in the construction of the body plan.     

Singular value decomposition-based regression identifies activation of endogenous signaling pathways in vivo

Background

The physical organization and chromosomal localization of genes within genomes is known to play an important role in their function. Most genes arise by duplication and move along the genome by random shuffling of DNA segments. Higher order structuring of the genome occurs in eukaryotes, where groups of physically linked genes are co-expressed. However, the contribution of gene duplication to gene order has not been analyzed in detail, as it is believed that co-expression due to recent duplicates would obscure other domains of co-expression.

Results

We have catalogued ordered duplicated genes in Drosophila melanogaster, and found that one in five of all genes is organized as tandem arrays. Furthermore, among arrays that have been spatially conserved over longer periods than would be expected on the basis of random shuffling, a disproportionate number contain genes encoding developmental regulators. Using in situ gene expression data for more than half of the Drosophila genome, we find that genes in these conserved clusters are co-expressed to a much higher extent than other duplicated genes.

Conclusions

These results reveal the existence of functional constraints in insects that retain copies of genes encoding developmental and regulatory proteins as neighbors, allowing their co-expression. This co-expression may be the result of shared cis-regulatory elements or a shared need for a specific chromatin structure. Our results highlight the association between genome architecture and the gene regulatory networks involved in the construction of the body plan.