Project description:Analysis of gene expression differences in relationship to dominance rank in female rhesus macaques. RNA obtained from 4 cell populations (helper T cells, cytotoxic T cells, monocytes, and B cells) from isolated peripheral blood mononuclear cells sampled from 5 adult female rhesus macaques across 5 different social groups and 5 different dominance ranks [dominance ranks : 1 = high, 5 = low]

Project description:These data are a component of a larger study investigating differences in gene regulation in relationship to rhesus macaque dominance rank. These data compare DNA methylation levels between individuals of different rank on a genome-wide scale using bisulfite sequencing DNA from peripheral blood mononuclear cells sampled from 3 high ranking individuals and 3 low ranking individuals (all adult female rhesus macaques)

Project description:This SuperSeries is composed of the following subset Series: GSE33090: Dramatic effects of social behavior on gene regulation in rhesus macaques [Individual_expression] GSE34127: Dramatic effects of social behavior on gene regulation in rhesus macaques [Cell type_expression] GSE34128: Dramatic effects of social behavior on gene regulation in rhesus macaques [Bisulfite_seq] Refer to individual Series

Project description:Analysis of gene expression differences in relationship to dominance rank in female rhesus macaques.

Project description:Analysis of gene expression differences in relationship to dominance rank in female rhesus macaques.

Project description:We have quantified gene expression in five tissues (brain, heart, kidney, liver and testis) from humans, chimpanzees and rhesus macaques using the Illumina NlaIII Digital Gene Expression (DGE) protocol. This dataset extends a previous microarray study by Khaitovich et al. (Khaitovich et al. 2005) with the rhesus macaque outgroup and complements other previously generated tissue transcriptome profiles from primates (Enard et al. 2002; Khaitovich et al. 2006; Somel et al. 2009; Babbitt et al. 2010; Blekhman et al. 2010; Wetterbom et al. 2010). contributor: Max Planck Institute for Evolutionary Anthropology, Deutscher Platz 6, D-04103 Leipzig, Germany Samples were obtained from brain (pre-frontal cortex), heart, kidney, liver, and testis tissues of male humans, chimpanzees and rhesus macaques. Illumina NlaIII DGE libraries for all samples were generated in tissue batches, randomizing species in library preparation and sequencing. Human samples originate from different, probably unrelated, individuals for each tissue. For chimpanzees and rhesus macaques the libraries for all tissues come from the same set of individuals and among these are individuals related at the half- and full-sibling level. Due to limited access to samples, the analysis could not be limited to individuals of similar age. Human individuals vary between 5 and 88 years of age, chimpanzees between 6 years and 35 years of age and rhesus macaques between 3 and 9 years of age.

Project description:Gene expression changes determine functional differentiation during development and are associated with functional decline during aging. While developmental changes are tightly regulated, regulation of aging changes is not well established. To assess the regulatory basis of age-related changes and investigate the mechanism of regulatory transition between development and aging, we measured mRNA and microRNA expression patterns in brains (superior frontal gyrus) of humans and rhesus macaques over the entire species’ lifespan. We find that in both species, developmental and aging changes overlap in the course of lifetime with many changes found at the late age initiating in early childhood. Human post-mortem brain samples from the superior frontal gyrus region of the prefrontal cortex were collected. The age ranges of the indibiual in human covered its whole life span fom newborn to death. RNA extracted from the dissected tissue was hybridized to Affymetrix® Human Gene 1.0 ST arrays. Rhesus macaque post-mortem brain samples from the superior frontal gyrus region of the prefrontal cortex were collected. The age ranges of the indibiual in rhesus macaque covered the whole life span fom newborn to death. RNA extracted from the dissected tissue was hybridized to Affymetrix® Human Gene 1.0 ST arrays.

Project description:Small RNA including microRNA (miRNA) and Piwi-interacting RNA (piRNA) play important roles in germline maintenance and maturation in wide variety of species. Relatively little however is known about role played by miRNA in male germline maturation in humans and closely related primate species. Here we focused on rhesus macaques as a model species closely related to humans to study small RNA expression in testis samples throughout postnatal development and maturation. We observe clear transition in miRNA and piRNA expression resulting in the overall increase of piRNA expression levels and corresponding decrease in miRNA expression. Unexpectedly, this transition takes place at approximately one year of age – far earlier then rhesus macaque sexual maturation occurring at 4-5 years of age. Notably, contradictory to the overall trend of expression decline, a group of 29 miRNA showed marked expression increase in macaque testis at approximately five years of age – the time interval associated with sexual maturation. Keywords: miRNA piRNA Age Series Rhesus macaque post-mortem testicle samples were collected. The age ranges of the indibiual in rhesus macaque covered the whole life span fom newborn to death.

Project description:These data are a component of a larger study investigating differences in gene regulation in relationship to rhesus macaque dominance rank. These data compare DNA methylation levels between individuals of different rank on a genome-wide scale using bisulfite sequencing

Project description:In development, timing is of the utmost importance, and the timing of various developmental processes are often changed during evolution. During human evolution sexual maturation has been delayed relative to other primates and this may have played a critical role for both the increase of human brain size and the rise of human-specific cognitive traits . We measured the timing of gene expression changes in the brains of humans, chimpanzees, and rhesus macaques throughout postnatal development. Human, chimpanzee and rhesus macaque post-mortem brain samples from the dorsolateral prefrontal cortex region were collected. The caudate nucleus region was additionally sampled for humans. The age ranges of the individuals in all three species covered the respective species' postnatal maturation period from infancy to young adulthood. RNA extracted from the dissected tissue was hybridized to Affymetrix® U133-plus2.0 GeneChip® arrays.