Many complex human phenotypes exhibit sex-differentiated characteristics, however the underlying molecular mechanisms of these differences remain largely unknown. Here, we present an extensive catalog of both sex differences in gene expression and its genetic regulation across 44 human tissue sources surveyed by GTEx (v8 release). We demonstrate that sex strongly influences gene expression levels and cellular composition of tissue samples across the human body. The effect of sex on gene expression is widespread, with a total of 37% of all genes exhibiting sex-biased expression in at least one tissue. This suggests that many if not most biological processes, and thus complex traits and diseases, are impacted by sex effects on the transciptome. We expand the identification of cis-eQTLs with sex-differentiated effects and characterize their cellular origin. By integrating sex-biased eQTLs with genome-wide association study data, we identify 58 gene-trait associations that are driven by genetic regulation in a single sex, including novel associations not detected with sex-agnostic approaches. Altogether we provide the most comprehensive characterization of sex differences in the human transcriptome and its regulation to date.
Background Among asymptomatic patients with severe carotid artery stenosis but no recent stroke or transient cerebral ischaemia, either carotid artery stenting (CAS) or carotid endarterectomy (CEA) can restore patency and reduce long-term stroke risks. However, from recent national registry data, each option causes about 1% procedural risk of disabling stroke or death. Comparison of their long-term protective effects requires large-scale randomised evidence.Methods ACST-2 is an international multicentre randomised trial of CAS versus CEA among asymptomatic patients with severe stenosis thought to require intervention, interpreted with all other relevant trials. Patients were eligible if they had severe unilateral or bilateral carotid artery stenosis and both doctor and patient agreed that a carotid procedure should be undertaken, but they were substantially uncertain which one to choose. Patients were randomly allocated to CAS or CEA and followed up at 1 month and then annually, for a mean 5 years. Procedural events were those within 30 days of the intervention. Intention-to-treat analyses are provided. Analyses including procedural hazards use tabular methods. Analyses and meta-analyses of non-procedural strokes use Kaplan-Meier and log-rank methods. The trial is registered with the ISRCTN registry, ISRCTN21144362.
Marek's disease virus (MDV) is an oncogenic alphaherpesvirus that induces T-cell lymphomas in poultry.We report the construction of bacterial artificial chromosome (BAC) clones of the highly oncogenic RB-1B strain by inserting mini-F vector sequences into the U S 2 locus. MDV reconstituted from two BAC clones induced rapid-onset lymphomas similar to those induced by the wild-type virus. Virus reconstituted from another BAC clone that showed a 7.7-kbp deletion in the internal and terminal unique long repeat regions was nononcogenic, suggesting that the deleted region may be associated with oncogenicity. The generation of the oncogenic BAC clones of MDV is a significant step in unraveling the oncogenic determinants of this virus.Bacterial artificial chromosomes (BAC) containing fulllength genomes of several herpesviruses have enabled the application of rapid mutagenesis strategies to identify functions of individual genes and determinants of pathogenicity (1). Marek's disease (MD) is a contagious lymphoproliferative disease of poultry caused by the highly oncogenic alphaherpesvirus MD virus (MDV). The application of BAC mutagenesis strategies to study MDV oncogenicity has been hampered by the nonavailability of BAC clones of oncogenic strains, as two of the previously reported BAC clones derived from attenuated MDV strains were unable to induce tumors (4, 7). The RB-1B strain of MDV isolated in the early 1980s is a highly oncogenic strain (5, 6) that consistently induces a high incidence of MD with rapid-onset tumors in visceral organs. We have previously shown that RB-1B infection in 1-week-old Rhode Island red chickens caused a 100% incidence of MD with tumors in visceral organs 6 to 7 weeks after infection (4). Taking advantage of this high oncogenic potential, we have chosen the RB-1B strain for the construction of BAC clones to identify oncogenic determinants of MDV.A clone-purified fourth-passage stock of the RB-1B strain of MDV (5), tested free of avian leukosis, reticuloendotheliosis, and chicken infectious anemia viruses, was used for the preparation of viral DNA for the construction of RB-1B BAC clones. Viral DNA was prepared from chicken embryo fibroblast (CEF) cultures by sodium dodecyl sulfate-proteinase K extraction (7). RB-1B BAC construction was carried out by insertion of the mini-F plasmid pHA1 into the U S 2 gene of MDV essentially as previously described (7). Briefly, secondary CEF cultures were cotransfected with RB-1B virus-infected genomic DNA and plasmid pDS-pHA1 (7) and passaged five or six times on primary CEF in medium containing 250 g of mycophenolic acid, 50 g of xanthine, and 100 g of hypoxanthine per ml at 4-day intervals. DNA from these cells was electroporated into Escherichia coli DH10B cells and plated on Luria-Bertani plates containing 30 g of chloramphenicol per ml. Transfection of high-molecular-weight extrachromosomal BAC DNA from three single colonies (designated pRB-1B-1, pRB-1B-2, and pRB-1B-5) into primary CEF produced MDVspecific plaques in about 4 to 5 days after transf...
Marek's disease virus (MDV) is an oncogenic herpesvirus that induces fatal T cell lymphomas in chickens.With more than 20 billion doses of vaccine used annually, vaccination constitutes the cornerstone of Marek's disease control. Despite the success of vaccination, evolution of virulence among MDV strains continues to threaten the effectiveness of the current Marek's disease vaccines. MDV-encoded protein MEQ (MDV EcoRI Q) probably acts as a transcription factor and is considered to be the major MDV oncoprotein. MEQ sequence shows a Pro-Leu-Asp-Leu-Ser (PLDLS) motif known to bind C-terminal-binding protein (CtBP), a highly conserved cellular transcriptional corepressor with roles in the regulation of development, proliferation, and apoptosis. Here we show that MEQ can physically and functionally interact with CtBP through this motif and that this interaction is critical for oncogenesis because mutations in the CtBP-interaction domain completely abolished oncogenicity. This direct role for MEQ-CtBP interaction in MDV oncogenicity highlights the convergent evolution of molecular mechanisms of neoplastic transformation by herpesviruses because Epstein-Barr virus oncoproteins EBNA 3A and 3C also interact with CtBP. We also demonstrate that the nononcogenic MDV generated by mutagenesis of the CtBP-interaction domain of MEQ has the potential to be an improved vaccine against virulent MDV infection. Engineering MDV with precisely defined attenuating mutations, therefore, represents an effective strategy for generating new vaccines against this major poultry disease. viral oncogenesis ͉ vaccines ͉ transcriptional repression
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