Toward understanding the core meiotic transcriptome in mammals and its implications for somatic cancer.

International audienceProgression through meiotic development is in part controlled by an expression program that coordinates the timing of induction and time of function of numerous loci essential for the process. Whole-genome profiling of male germline expression in mouse, rat, and human provides important clues about the transcriptional regulatory machinery that drives the expression of its target genes. Among several thousand genes differentially expressed between testicular Sertoli and germ cells, a subset of conserved loci display highly similar meiotic and postmeiotic profiles across rodents and Homo sapiens. Mouse genes transcribed in the germline, but not in somatic control tissues, are frequently found to be important for sexual reproduction, thus correlating potentially specific expression and essential function in the male germline. In silico promoter analysis yields insight into DNA sequence conservation and the distribution of known regulatory elements within potential promoter regions of meiotic and postmeiotic genes. Some genes strongly expressed in male gonads are implicated in cancer, thus supporting the idea that gametogenesis and tumorigenesis may share molecular functions. Transcriptome, proteome, and protein network data reveal the kinetics of mRNA synthesis and translation in the germline, and help identify novel potentially important genes previously unassociated with the mammalian male germline

Transcription of two long noncoding RNAs mediates mating-type control of gametogenesis in budding yeast.

International audienceThe cell-fate decision leading to gametogenesis is essential for sexual reproduction. In S. cerevisiae, only diploid MATa/α but not haploid MATa or MATα cells undergo gametogenesis, known as sporulation. We find that transcription of two long noncoding RNAs (lncRNAs) mediates mating-type control of sporulation. In MATa or MATα haploids, expression of IME1, the central inducer of gametogenesis, is inhibited in cis by transcription of the lncRNA IRT1, located in the IME1 promoter. IRT1 transcription recruits the Set2 histone methyltransferase and the Set3 histone deacetylase complex to establish repressive chromatin at the IME1 promoter. Inhibiting expression of IRT1 and an antisense transcript that antagonizes the expression of the meiotic regulator IME4 allows cells expressing the haploid mating type to sporulate with kinetics that are indistinguishable from that of MATa/α diploids. Conversely, expression of the two lncRNAs abolishes sporulation in MATa/α diploids. Thus, transcription of two lncRNAs governs mating-type control of gametogenesis in yeast