Disease association and inter-connectivity analysis of human brain specific co-expressed functional modules

BACKGROUND: In the recent studies, it is suggested that the analysis of transcriptomic change of functional modules instead of individual genes would be more effective for system-wide identification of cellular functions. This could also provide a new possibility for the better understanding of difference between human and chimpanzee. RESULTS: In this study, we analyzed to find molecular characteristics of human brain functions from the difference of transcriptome between human and chimpanzee's brain using the functional module-centric co-expression analysis. We performed analysis of brain disease association and systems-level connectivity of species-specific co-expressed functional modules. CONCLUSIONS: Throughout the analyses, we found human-specific functional modules and significant overlap between their genes in known brain disease genes, suggesting that human brain disorder could be mediated by the perturbation of modular activities emerged in human brain specialization. In addition, the human-specific modules having neurobiological functions exhibited higher networking than other functional modules. This finding suggests that the expression of neural functions are more connected than other functions, and the resulting high-order brain functions could be identified as a result of consolidated inter-modular gene activities. Our result also showed that the functional module based transcriptome analysis has a potential to expand molecular understanding of high-order complex functions like cognitive abilities and brain disorders.

Molecular evolution and expression profile of the chemerine encoding gene RARRES2 in baboon and chimpanzee

BACKGROUND: Chemerin, encoded by the retinoic acid receptor responder 2 (RARRES2) gene is an adipocytesecreted protein with autocrine/paracrine functions in adipose tissue, metabolism and inflammation with a recently described function in vascular tone regulation, liver, steatosis, etc. This molecule is believed to represent a critical endocrine signal linking obesity to diabetes. There are no data available regarding evolution of RARRES2 in non-human primates and great apes. Expression profile and orthology in RARRES2 genes are unknown aspects in the biology of this multigene family in primates. Thus; we attempt to describe expression profile and phylogenetic relationship as complementary knowledge in the function of this gene in primates. To do that, we performed A RT-PCR from different tissues obtained during necropsies. Also we tested the hypotheses of positive evolution, purifying selection, and neutrality. And finally a phylogenetic analysis was made between primates RARRES2 protein. RESULTS: RARRES2 transcripts were present in liver, lung, adipose tissue, ovary, pancreas, heart, hypothalamus and pituitary tissues. Expression in kidney and leukocytes were not detectable in either species. It was determined that the studied genes are orthologous. CONCLUSIONS: RARRES2 evolution fits the hypothesis of purifying selection. Expression profiles of the RARRES2 gene are similar in baboons and chimpanzees and are also phylogenetically related.

Recent integrations of mammalian Hmg retropseudogenes.

We propose that select retropseudogenes of the high mobility group nonhistone chromosomal protein genes have recently integrated into mammalian genomes on the basis of the high sequence identity of the copies to the cDNA sequences derived from the original genes. These include the Hmg1 gene family in mice and the Hmgn2 family in humans. We investigated orthologous loci of several strains and species of Mus for presence or absence of apparently young Hmg1 retropseudogenes. Three of four analysed elements were specific to Mus musculus, two of which were not fixed, indicative of recent evolutionary origins. Additionally, we datamined a presumptive subfamily (Hmgz) of mouse Hmg1, but only identified one true element in the GenBank database, which is not consistent with a separate subfamily status. Two of four analysed Hmgn2 retropseudogenes were specific for the human genome, whereas a third was identified in human, chimpanzee and gorilla genomes, and a fourth additionally found in orangutan but absent in African green monkey. Flanking target-site duplications were consistent with LINE integration sites supporting LINE machinery for their mechanism of amplification. The human Hmgn2 retropseudogenes were full length, whereas the mouse Hmg1 elements were either full length or 3'-truncated at specific positions, most plausibly the result of use of alternative polyadenylation sites. The nature of their recent amplification success in relation to other retropseudogenes is unclear, although availability of a large number of transcripts during gametogenesis may be a reason. It is apparent that retropseudogenes continue to shape mammalian genomes, and may provide insight into the process of retrotransposition, as well as offer potential use as phylogenetic markers.

Evolution and the origins of man: clues from complete sequences of hominoid mitochondrial DNA.

Dating the origins of Homo sapiens sapiens is a central problem in human population genetics and anthropology. Do we descend from a single recent ancestral population in Africa, or from multiple ancestral populations in various regions of the world which one million years ago simultaneously began developing into H.s.sapiens? The high substitution rate of mitochondrial DNA (mtDNA) makes this molecule suitable for genealogical and chronological research on closely related hominoid species. We have analyzed the complete mtDNA sequences of three humans (African, European and Japanese) and two African apes (common chimpanzee and gorilla) in an attempt to estimate more accurately the substitution rates and divergence times of hominoid mtDNAs. Nonsynonymous substitutions and substitutions in RNA genes have accumulated at an approximately constant rate. Under the assumption, supported by the fossil record, that the orangutan and African apes diverged 13 million years ago, we have previously obtained 4.7 million years as the divergence time between humans and chimpanzees. Using this date, we calibrated the substitution rates at synonymous sites and in the displacement-loop region as 4.03 and 7.25 x 10(-8)/site/year, respectively. Based on these rates together with the observation that the African sequence presented here is most diverged from all other human sequences, we inferred the age of the last common ancestor of the human mtDNAs as 140,000 +/- 18,000 years. The result strongly supports the recent African origin of modern humans, H.s. sapiens.