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W2753201850 abstract "What is the genetic landscape within the testis of the juvenile rhesus monkey (Macaca mulatta) that underlies the decision of undifferentiated spermatogonia to commit to a pathway of differentiation when puberty is induced prematurely by exogenous LH and FSH stimulation?Forty-eight hours of gonadotrophin stimulation of the juvenile monkey testis resulted in the appearance of differentiating B spermatogonia and the emergence of 1362 up-regulated and 225 down-regulated testicular mRNAs encoding a complex network of proteins ranging from enzymes regulating Leydig cell steroidogenesis to membrane receptors, and from juxtacrine and paracrine factors to transcriptional factors governing spermatogonial stem cell fate.Our understanding of the cell and molecular biology underlying the fate of undifferentiated spermatogonia is based largely on studies of rodents, particularly of mice, but in the case of primates very little is known. The present study represents the first attempt to comprehensively address this question in a highly evolved primate.Global gene expression in the testis from juvenile rhesus monkeys that had been stimulated with recombinant monkey LH and FSH for 48 h (N = 3) or 96 h (N = 4) was compared to that from vehicle treated animals (N = 3). Testicular cell types and testosterone secretion were also monitored.Precocious testicular puberty was initiated in juvenile rhesus monkeys, 14-24 months of age, using a physiologic mode of intermittent stimulation with i.v. recombinant monkey LH and FSH that within 48 h produced 'adult' levels of circulating LH, FSH and testosterone. Mitotic activity was monitored by immunohistochemical assays of 5-bromo-2'-deoxyuridine and 5-ethynyl-2'-deoxyuridine incorporation. Animals were bilaterally castrated and RNA was extracted from the right testis. Global gene expression was determined using RNA-Seq. Differentially expressed genes (DEGs) were identified and evaluated by pathway analysis. mRNAs of particular interest were also quantitated using quantitative RT-PCR. Fractions of the left testis were used for histochemistry or immunoflouresence.Differentiating type B spematogonia were observed after both 48 and 96 h of gonadotrophin stimulation. Pathway analysis identified five super categories of over-represented DEGs. Repression of GFRA1 (glial cell line-derived neurotrophic factor family receptor alpha 1) and NANOS2 (nanos C2HC-type zinc finger 2) that favor spermatogonial stem cell renewal was noted after 48 and 96 h of LH and FSH stimulation. Additionally, changes in expression of numerous genes involved in regulating the Notch pathway, cell adhesion, structural plasticity and modulating the immune system were observed. Induction of genes associated with the differentiation of spermatogonia stem cells (SOHLH1(spermatogenesis- and oogenesis-specific basic helix-loop-helix 1), SOHLH2 and KIT (V-Kit Hardy-Zuckerman 4 feline sarcoma viral oncogene homolog)) was not observed. Expression of the gene encoding STRA8 (stimulated by retinoic acid 8), a protein generally considered to mark activation of retinoic acid signaling, was below our limit of detection.The entire mRNA data set for vehicle and gonadotrophin treated animals (N = 10) has been deposited in the GEO-NCBI repository (GSE97786).The limited number of monkeys per group and the dilution of low abundance germ cell transcripts by mRNAs contributed from somatic cells likely resulted in an underestimation of the number of differentially expressed germ cell genes.The findings that expression of GDNF (a major promoter of spermatogonial stem cell renewal) was not detected in the control juvenile testes, expression of SOHLH1, SOHLH2 and KIT, promoters of spermatogonial differentiation in mice, were not up-regulated in association with the gonadotrophin-induced generation of differentiating spermatogonia, and that robust activation of the retinoic acid signaling pathway was not observed, could not have been predicted. These unexpected results underline the importance of non-human primate models in translating data derived from animal research to the human situation.The work described was funded by NIH grant R01 HD072189 to T.M.P. P.A. was supported by an Endocrine Society Summer Research Fellowship Award and CONICET (Argentine Research Council), S.N. by a grant from Vali-e-Asr Reproductive Health Research Center of Tehran University of Medical Sciences (grant #24335-39-92) to Dr Batool Hosseini Rashidi, and M.P.H. by grants from the National Health and Medical Research Council of Australia, and the Victorian State Government's Operational Infrastructure Support Program. The authors have nothing to disclose." @default.
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W2753201850 date "2017-08-30" @default.
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W2753201850 title "The testicular transcriptome associated with spermatogonia differentiation initiated by gonadotrophin stimulation in the juvenile rhesus monkey (Macaca mulatta)" @default.
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W2753201850 cites W1650607266 @default.
W2753201850 cites W1939982746 @default.
W2753201850 cites W1965428318 @default.
W2753201850 cites W1972628959 @default.
W2753201850 cites W1980440773 @default.
W2753201850 cites W1987966039 @default.
W2753201850 cites W1991568351 @default.
W2753201850 cites W1993083609 @default.
W2753201850 cites W1993675281 @default.
W2753201850 cites W2002664724 @default.
W2753201850 cites W2003819643 @default.
W2753201850 cites W2006378969 @default.
W2753201850 cites W2006842552 @default.
W2753201850 cites W2010673294 @default.
W2753201850 cites W2014432968 @default.
W2753201850 cites W2018289634 @default.
W2753201850 cites W2021037171 @default.
W2753201850 cites W2021880506 @default.
W2753201850 cites W2023933818 @default.
W2753201850 cites W2053995696 @default.
W2753201850 cites W2054753350 @default.
W2753201850 cites W2059382360 @default.
W2753201850 cites W2065492865 @default.
W2753201850 cites W2075322913 @default.
W2753201850 cites W2085287554 @default.
W2753201850 cites W2092476762 @default.
W2753201850 cites W2107382596 @default.
W2753201850 cites W2109665403 @default.
W2753201850 cites W2112058982 @default.
W2753201850 cites W2116376034 @default.
W2753201850 cites W2123771994 @default.
W2753201850 cites W2125164393 @default.
W2753201850 cites W2126602233 @default.
W2753201850 cites W2129918060 @default.
W2753201850 cites W2130116522 @default.
W2753201850 cites W2140748980 @default.
W2753201850 cites W2153353888 @default.
W2753201850 cites W2153636431 @default.
W2753201850 cites W2160019572 @default.
W2753201850 cites W2164296556 @default.
W2753201850 cites W2169542750 @default.
W2753201850 cites W2190807767 @default.
W2753201850 cites W2191459521 @default.
W2753201850 cites W2252403865 @default.
W2753201850 cites W2269069106 @default.
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W2753201850 doi "https://doi.org/10.1093/humrep/dex270" @default.
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