Project description:The role of different proteins, Always Early (Aly), Spermatocyte Arrest (Sa), Ubi-p63E (Magn) on the gene expression in spermatocyte differentation was assessed by microarray ABSTRACT: The ubiquitin proteasome system (UPS) regulates many biological pathways by posttranslationally ubiquitinating proteins for degradation. Although maintaining a dynamic balance between free ubiquitin and ubiquitinated proteins is key to UPS function, the mechanisms that regulate ubiquitin homeostasis in different tissues through development are not clear. Here we show that loss of function of Drosophila magellan (magn), the polyubiquitin Ubi-p63E, results in specifically meiotic arrest sterility in males. Expression of ubiquitin from magn/Ubi-p63E contributes predominantly to maintaining the free ubiquitin pool in testes. Function of magn/Ubip63E is required cell autonomously for proper meiotic chromatin condensation, cell cycle progression and spermatid differentiation. magn/Ubi-p63E mutant germ cells develop normally to the spermatocyte stage but arrest at the G2/M transition of meiosis I with lack of protein expression of key meiotic cell cycle regulators Boule and Cyclin B. Loss of function of magn/Ubi-p63E did not strongly affect the spermatocyte transcription program regulated by the tTAF and tMAC genes. Knocking down proteasome function specifically in spermatocytes caused a different meiotic arrest phenotype, suggesting that the magn/Ubi-p63E phenotype may not result from general defects in protein degradation. Our results suggest a conserved role of polyubiquitin genes in male meiosis and a potential mechanism leading to meiosis I maturation arrest.

Project description:The effect of Med22, spermatocyte arrest (sa) and always early (aly) loss of function on the gene expression in spermatocytes was assessed by microarray. Title: Recruitment of Mediator complex by cell type and stage-specific factors required for tissue-specific TAF dependent gene activation in an adult stem cell lineage

Project description:The effect of Med22, spermatocyte arrest (sa) and always early (aly) loss of function on the gene expression in spermatocytes was assessed by microarray. Title: Recruitment of Mediator complex by cell type and stage-specific factors required for tissue-specific TAF dependent gene activation in an adult stem cell lineage RNA was obtained from whole testes of flies with following mutations: 1)bam-gal4: UAS-Med22RNAi (VDRC#104581). Three biological replicates were included. Experiments were performed at 25C.

Project description:The Drosophila gene dany is expressed specifically in spermatocytes and encodes a nuclear protein with similarity to the products of the genes distal antenna (dan) and distal antenna-related (danr). Loss of dany function results in male sterility. Mutant spermatocytes fail to differentiate similar as previously observed in mutants lacking tTAF and tMAC function. Microarray analyses were performed to characterize the effects of loss of dany function on gene expression in testis and for a comparison of the effects with those caused by mutations in the tTAF gene spermatocyte arrest (sa) and the tMAC genes always early (aly) and matotopetli (topi) RNA was isolated after testis dissection from adult males and used for the production of probes for microarray hybridization. Five different genotypes were used for testis dissection: control, dany mutant, sa mutant, aly mutant, topi mutant. The number of biological replicates per genotypes was between two and four.

Project description:The Drosophila gene dany is expressed specifically in spermatocytes and encodes a nuclear protein with similarity to the products of the genes distal antenna (dan) and distal antenna-related (danr). Loss of dany function results in male sterility. Mutant spermatocytes fail to differentiate similar as previously observed in mutants lacking tTAF and tMAC function. Microarray analyses were performed to characterize the effects of loss of dany function on gene expression in testis and for a comparison of the effects with those caused by mutations in the tTAF gene spermatocyte arrest (sa) and the tMAC genes always early (aly) and matotopetli (topi)

Project description:Drosophila melanogaster males mutant for any meiotic arrest gene have defective spermatogenesis, with cells arresting as primary spermatocytes, and failing to progress to later stages. This phenotype is remarkably similar to meiosis I maturation arrest azoospemia in humans. Drosophila meiotic arrest genes can be categorised as "aly-class" or "can-class". The aly-class (aly, zaa and zab) regulates both meiotic division and male germ line differentiation by controlling transcriptional activation of a large set of target genes in primary spermatocytes. This set includes genes required for cell cycle progression and those required for spermatid differentiation. The can-class control transcription of the same set of differentiation genes, but not cell cycle genes. aly belongs to a protein family conserved from humans to plants. Aly protein locates to chromatin in wild type individuals, and probably controls transcriptional activity of target promoters through interaction with a DNA binding protein. Objectives: So far aly- and can-class target genes have been identified by the small-scale approach of individually testing cDNA clones (total 18). Expression of 7 genes was unaffected by the mutations (group A), transcription of 8 depended on both classes of genes (group B), finally three genes required the aly- but not the can-class for their expression (group C). The aly-class targets (group C) are particularly intriguing, since they include a gene, boule, whose human homologue deleted in azoospermia (DAZ) is essential for male fertility. This project will address the following questions: How many genes in total are regulated by the meiotic arrest genes? What types of proteins do they encode? Are they all testis specific, or are they expressed at other stages of the life cycle? What is their relevance for fertility in other species?<br> <br> Plan: We will prepare samples of wild type, aly, can, zaa and zab testes. Those transcripts expressed in wild type testes will be placed into group A, B or C based on analysis of the competitive hybridisation of wild type samples vs each mutant in turn. Microarrays will also enable us to determine whether there is a group D, consisting of genes whose down-regulation in spermatocytes is dependent on the meiotic arrest genes. We have dissected testes from 0-1 day old males of the relevent genotypes. We estimate to get >20 ug total RNA from 100 flies, so have dissected at least 500 males of each mutant genotype, and 2000 of wild type (red e, the background chromosome for aly and can). In total we have about 5000 flies worth of testes in the freezer. We have been careful to only include testes and seminal vesicles, and have excluded other tissues from the genital tract. All the males are collected from bottles that are emptied daily, to ensure they are all the same age. Because of their age relatively few of the males will have mated. For aly and can we have used well characterised null alleles. For zab we have used the only mutant allele, which we also know is a null. We havn't cloned zaa so have no idea whether the only existing mutant allele is null. The testes were dissected in testis buffer over a period of 30 min. Then they were transfered into a very small drop of testis buffer in an eppendorf and frozen in liquid nitrogen. They have been stored at -80C. Before being sent to Cambridge we will defrost the samples, add trizol, and pool samples to supply 3 or 4 tubes per genotype.

Project description:The effect of different loss of functions; kumgang (kmg or CG5204), dMi-2, and kmg and always early (aly) double on the gene expression in spermatocyte differentation was assessed by microarray. TITLE: Blocking promiscuous activation at cryptic promoters directs cell type–specific gene expression ABSTRACT: To selectively express cell type–specific transcripts during development, it is critical to maintain genes required for other lineages in a silent state. Here, we show in the Drosophila male germline stem cell lineage that a spermatocyte-specific zinc finger protein, Kumgang (Kmg), working with the chromatin remodeler dMi-2 prevents transcription of genes normally expressed only in somatic lineages. By blocking transcription from normally cryptic promoters, Kmg restricts activation by Aly, a component of the testis-meiotic arrest complex, to transcripts for male germ cell differentiation. Our results suggest that as new regions of the genome become open for transcription during terminal differentiation, blocking the action of a promiscuous activator on cryptic promoters is a critical mechanism for specifying precise gene activation.

Project description:In mammals, a key transition in spermatogenesis is the exit from spermatogonial differentiation and mitotic proliferation and the entry into spermatocyte differentiation and meiosis. Although several genes that regulate this transition have been identified, how it is controlled and coordinated remains poorly understood. Here we examine the role in male gametogenesis of the Doublesex-related gene Dmrt6 (Dmrtb1) and find that Dmrt6 plays a critical role in directing germ cells through the mitotic to meiotic germ cell transition. DMRT6 protein is expressed in late mitotic spermatogonia. In mice of the C57BL/6J strain a null mutation in Dmrt6 disrupts spermatogonial differentiation, causing expression in inappropriate cell types of spermatogonial differentiation factors including SOHLH1, SOHLH2 and DMRT1 and the meiotic initiation factor STRA8 and causing most late spermatogonia to undergo apoptosis. In mice of the 129Sv background, most Dmrt6 mutant spermatogonia can complete differentiation and enter meiosis, but they show defects in chromosome pairing, establishment of the XY body, and processing of recombination foci, and mainly arrest in mid-pachynema. mRNA profiling of Dmrt6 mutant testes together with DMRT6 ChIP-seq suggest that DMRT6 represses genes involved in spermatogonial differentiation and activates genes required for meiotic prophase. Our results indicate that Dmrt6 plays a key role in coordinating the transition in gametogenic programs from spermatogonial differentiation and mitosis to spermatocyte development and meiosis. Six samples for RNA-Seq with three biological replicates in each group. Two samples for ChIP-Seq (one input and one ChIP).

Project description:Genome wide localization of Kumgang, dMi-2, and Aly in Drosophila melanogaster testes were evaluated by ChIP-Seq in wild-type and kmg knock down testes. / Title: Blocking promiscuous activation at cryptic promoters directs cell type–specific gene expression / Abstract: To selectively express cell type–specific transcripts during development, it is critical to maintain genes required for other lineages in a silent state. Here, we show in the Drosophila male germline stem cell lineage that a spermatocyte-specific zinc finger protein, Kumgang (Kmg), working with the chromatin remodeler dMi-2 prevents transcription of genes normally expressed only in somatic lineages. By blocking transcription from normally cryptic promoters, Kmg restricts activation by Aly, a component of the testis-meiotic arrest complex, to transcripts for male germ cell differentiation. Our results suggest that as new regions of the genome become open for transcription during terminal differentiation, blocking the action of a promiscuous activator on cryptic promoters is a critical mechanism for specifying precise gene activation.

Project description:In mammals, a key transition in spermatogenesis is the exit from spermatogonial differentiation and mitotic proliferation and the entry into spermatocyte differentiation and meiosis. Although several genes that regulate this transition have been identified, how it is controlled and coordinated remains poorly understood. Here we examine the role in male gametogenesis of the Doublesex-related gene Dmrt6 (Dmrtb1) and find that Dmrt6 plays a critical role in directing germ cells through the mitotic to meiotic germ cell transition. DMRT6 protein is expressed in late mitotic spermatogonia. In mice of the C57BL/6J strain a null mutation in Dmrt6 disrupts spermatogonial differentiation, causing expression in inappropriate cell types of spermatogonial differentiation factors including SOHLH1, SOHLH2 and DMRT1 and the meiotic initiation factor STRA8 and causing most late spermatogonia to undergo apoptosis. In mice of the 129Sv background, most Dmrt6 mutant spermatogonia can complete differentiation and enter meiosis, but they show defects in chromosome pairing, establishment of the XY body, and processing of recombination foci, and mainly arrest in mid-pachynema. mRNA profiling of Dmrt6 mutant testes together with DMRT6 ChIP-seq suggest that DMRT6 represses genes involved in spermatogonial differentiation and activates genes required for meiotic prophase. Our results indicate that Dmrt6 plays a key role in coordinating the transition in gametogenic programs from spermatogonial differentiation and mitosis to spermatocyte development and meiosis.