Mutations involving the SRY-related gene SOX8 are associated with a spectrum of human reproductive anomalies.

© The Author(s) 2018. Published by Oxford University Press. All rights reserved. SOX8 is an HMG-box transcription factor closely related to SRY and SOX9. Deletion of the gene encoding Sox8 in mice causes reproductive dysfunction but the role of SOX8 in humans is unknown. Here, we show that SOX8 is expressed in the somatic cells of the early developing gonad in the human and influences human sex determination. We identified two individuals with 46, XY disorders/differences in sex development (DSD) and chromosomal rearrangements encompassing the SOX8 locus and a third individual with 46, XY DSD and a missense mutation in the HMG-box of SOX8. In vitro functional assays indicate that this mutation alters the biological activity of the protein. As an emerging body of evidence suggests that DSDs and infertility can have common etiologies, we also analysed SOX8 in a cohort of infertile men (n=274) and two independent cohorts of women with primary ovarian insufficiency (POI; n=153 and n=104). SOX8 mutations were found at increased frequency in oligozoospermic men (3.5%; P < 0.05) and POI (5.06%; P=4.5×10 -5 ) as compared with fertile/normospermic control populations (0.74%). The mutant proteins identified altered SOX8 biological activity as compared with the wild-type protein. These data demonstrate that SOX8 plays an important role in human reproduction and SOX8 mutations contribute to a spectrum of phenotypes including 46, XY DSD, male infertility and 46, XX POI.Link_to_subscribed_fulltex

Facteurs génétiques et épigénétiques associés à l'infertilité masculine

La spermatogenèse est un processus complexe qui dépend de la coopération de nombreux gènes. Son produit final le spermatozoïde, est un sujet d’étude idéal car il renferme à la fois des indices d’événements passés ainsi que des informations qui seront transmises à l'ovocyte lors de la fécondation. L'identification de nouveaux acteurs de la spermatogenèse, des modifications spécifiques de l'ADN du sperme ou la présence de transcrits spécifiques pourraient servir comme biomarqueurs dans le diagnostic de l’infertilité. Cette thèse avait pour but d’analyser le génome, le transcriptome et l’épigénome de spermatozoïdes dans le contexte de l'infertilité masculine. Nous avons identifié de nouvelles causes génétiques et confirmé la présence d'anomalies de méthylation dans le sperme d'hommes infertiles. Nous avons découvert 20 mutations dans le gène SOX8, chez des patients atteints de trouble du développement sexuel ou d'infertilité masculine ou féminine, qui apparaît comme un régulateur du développement et de la fonction gonadique. Par séquençage d’exome, une mutation dans le gène ATAD2 modeleur de la chromatine spécifique de la lignée germinale mâle fut également identifiée. Par RNA-seq et MeDIP-chIP du sperme d’hommes fertiles et infertiles, nous avons caractérisé la signature transcriptionnelle du sperme. La majorité des ARNs spermatiques humain est remarquablement conservée chez les mammifères placentaires suggérant des fonctions ancestrales importantes. Enfin, nos données transcriptomiques et épigénétiques tendent à indiquer qu’une expression et une régulation adéquates des gènes impliqués dans le remodelage de la chromatine constituent un facteur clé pour la fertilité masculine.Spermatogenesis is a complex process which depends on the cooperation of many genes. The end-product, the spermatozoon, is an ideal subject for study since it carries both clues of the past events and information which will be transmitted to the oocyte at fertilization. The identification of main actors of spermatogenesis, specific modifications of sperm DNAs or sperm specific isoforms could improve our understanding of a such complex mechanism and could serve as a determination of biomarkers or diagnostic tools for fertility. The aim of the project was to go further three omes: genome, epigenome and transcriptome of mature human sperm in the context of male infertility. We identified new genetic causes of male infertility and confirmed the presence of methylation abnormalities in sperm cells of infertile men. Firstly, SOX8 gene was found mutated in a cohort of 20 patients with disorder of sex development and male or female infertility. Similarly, to NR5A1, SOX8 appears to be a novel regulator of gonadal development and function. Then by exome-sequencing, we identified a homozygous nonsense mutation in the male germline-specific chromatin modeler ATAD2. Furthermore, RNA-seq and MeDIP-chIP of sperm from fertile and infertile men along with bioinformatics analyzes of the generated data, enabled us to characterize more deeply the normal sperm transcriptional signature. We also found that the majority of human sperm RNAs are remarkably preserved in placental mammals suggesting crucial ancestral functions. Finally, proper expression and regulation of chromatin remodelers seem to be critical for male fertility, as revealed by both the transcriptomic and the epigenetic data

Molecular basis of the attenuated phenotype of human APOBEC3B DNA mutator enzyme

International audienceThe human APOBEC3A and APOBEC3B genes (A3A and A3B) encode DNA mutator enzymes that deaminate cytidine and 5-methylcytidine residues in single-stranded DNA (ssDNA). They are important sources of mutations in many cancer genomes which show a preponderance of CG->TA transitions. Although both enzymes can hypermutate chromosomal DNA in an experimental setting, only A3A can induce double strand DNA breaks, even though the catalytic domains of A3B and A3A differ by only 9% at the protein level. Accordingly we sought the molecular basis underlying A3B attenuation through the generation of A3A-A3B chimeras and mutants. It transpires that the N-terminal domain facilitates A3B activity while a handful of substitutions in the catalytic C-terminal domain impacting ssDNA binding serve to attenuate A3B compared to A3A. Interestingly, functional attenuation is also observed for the rhesus monkey rhA3B enzyme compared to rhA3A indicating that this genotoxic dichotomy has been selected for and maintained for some 38 million years. Expression of all human ssDNA cytidine deaminase genes is absent in mature sperm indicating they contribute to somatic mutation and cancer but not human diversity

High-resolution profiling of novel transcribed regions during rat spermatogenesis

International audienceMammalian spermatogenesis is a complex and highly orchestrated combination of processes in which male germline proliferation and differentiation result in the production of mature spermatozoa. If recent genome-wide studies have contributed to the in-depth analysis of the male germline protein-encoding transcriptome, little effort has yet been devoted to the systematic identification of novel unannotated transcribed regions expressed during mammalian spermatogenesis. We report high-resolution expression profiling of male germ cells in rat, using next-generation sequencing technology and highly enriched testicular cell populations. Among 20 424 high-confidence transcripts reconstructed, we defined a stringent set of 1419 long multi-exonic unannotated transcripts expressed in the testis (testis-expressed unannotated transcripts [TUTs]). TUTs were divided into 7 groups with different expression patterns. Most TUTs share many of the characteristics of vertebrate long noncoding RNAs (lncRNAs). We also markedly reinforced the finding that TUTs and known lncRNAs accumulate during the meiotic and postmeiotic stages of spermatogenesis in mammals and that X-linked meiotic TUTs do not escape the silencing effects of meiotic sex chromosome inactivation. Importantly, we discovered that TUTs and known lncRNAs with a peak expression during meiosis define a distinct class of noncoding transcripts that exhibit exons twice as long as those of other transcripts. Our study provides new insights in transcriptional profiling of the male germline and represents a high-quality resource for novel loci expressed during spermatogenesis that significantly contributes to rat genome annotation