Genome-Wide and Cell-Specific Epigenetic Analysis Challenges the Role of Polycomb in Drosophila Spermatogenesis

The Drosophila spermatogenesis cell differentiation pathway involves the activation of a large set of genes in primary spermatocytes. Most of these genes are activated by testis-specific TATA-binding protein associated factors (tTAFs). In the current model for the activation mechanism, Polycomb plays a key role silencing these genes in the germline precursors, and tTAF-dependent activation in primary spermatocytes involves the displacement of Polycomb from gene promoters. We investigated the genome-wide binding of Polycomb in wild type and tTAF mutant testes. According to the model we expected to see a clear enhancement in Polycomb binding at tTAF-dependent spermatogenesis genes in tTAF mutant testes. However, we find little evidence for such an enhancement in tTAF mutant testes compared to wild type. To avoid problems arising from cellular heterogeneity in whole testis analysis, we further tested the model by analysing Polycomb binding in purified germline precursors, representing cells before tTAF-dependent gene activation. Although we find Polycomb associated with its canonical targets, we find little or no evidence of Polycomb at spermatogenesis genes. The lack of Polycomb at tTAF-dependent spermatogenesis genes in precursor cells argues against a model where Polycomb displacement is the mechanism of spermatogenesis gene activation.     

asunder Is a Critical Regulator of Dynein–Dynactin Localization during Drosophila Spermatogenesis

Spermatogenesis uses mitotic and meiotic cell cycles coordinated with growth and differentiation programs to generate functional sperm. Our analysis of a Drosophila mutant has revealed that asunder (asun), which encodes a conserved protein, is an essential regulator of spermatogenesis. asun spermatocytes arrest during prophase of meiosis I. Strikingly, arrested spermatocytes contain free centrosomes that fail to stably associate with the nucleus. Spermatocytes that overcome arrest exhibit severe defects in meiotic spindle assembly, chromosome segregation, and cytokinesis. Furthermore, the centriole-derived basal body is detached from the nucleus in asun postmeiotic spermatids, resulting in abnormalities later in spermatogenesis. We find that asun spermatocytes and spermatids exhibit drastic reduction of perinuclear dynein–dynactin, a microtubule motor complex. We propose a model in which asun coordinates spermatogenesis by promoting dynein–dynactin recruitment to the nuclear surface, a poorly understood process required for nucleus–centrosome coupling at M phase entry and fidelity of meiotic divisions.     

Roles for Drp1, a Dynamin-related Protein,and Milton,a Kinesin-associated Protein,in Mitochondrial Segregation,Unfurling, and Elongation During Drosophila Spermatogenesis

Mitochondria undergo dramatic rearrangement during Drosophila spermatogenesis. In wild type testes, the many small mitochondria present in pre-meiotic spermatocytes later aggregate, fuse, and interwrap in post-meiotic haploid spermatids to form the spherical Nebenkern, whose two giant mitochondrial compartments later unfurl and elongate beside the growing flagellar axoneme. Drp1 encodes a dynamin-related protein whose homologs in many organisms mediate mitochondrial fission and whose Drosophila homolog is known to govern mitochondrial morphology in neurons. The milton gene encodes an adaptor protein that links mitochondria with kinesin and that is required for mitochondrial transport in Drosophila neurons. To determine the roles of Drp1 and Milton in spermatogenesis, we used the FLP-FRT mitotic recombination system to generate spermatocytes homozygous for mutations in either gene in an otherwise heterozygous background. We found that absence of Drp1 leads to abnormal clustering of mitochondria in mature primary spermatocytes and aberrant unfurling of the mitochondrial derivatives in early Drp1 spermatids undergoing axonemal elongation. In milton spermatocytes, mitochondria are distributed normally; however, after meiosis, the Nebenkern is not strongly anchored to the nucleus, and the mitochondrial derivatives do not elongate properly. Our work defines specific functions for Drp1 and Milton in the anchoring, unfurling, and elongation of mitochondria during sperm formation.     

The POLO kinase is required at multiple stages during spermatogenesis in Drosophila melanogaster

The polo gene of Drosophila melanogaster is the founding member of the polo-like kinase family which is conserved among eukaryotes. POLO has been implicated in the organisation and function of the mitotic apparatus. Furthermore, POLO has been shown to be required for normal spermatogenesis. To characterize further the role of POLO in spermatogenesis, polo mutants were analysed by immunostaining with specific antibodies and phase contrast microscopy. Immunofluorescence shows that POLO localises to the centrosomes, the centromere/kinetochore and the spindle midzone. The meiotic phenotype of various mutant allelic combinations was also studied in detail. Observation of mutant live testes indicates cytological abnormalities in all meiotic cell types, including variable DNA content and multipolar spindles. Primary spermatocytes in polo mutant testes contain an abnormal DNA content, suggesting failure of chromosome segregation during gonial division. Immunostaining of polo mutant cells with α-tubulin shows several abnormalities of the meiotic spindle, including a significantly reduced central spindle. Our results suggest that polo has multiple functions during spermatogenesis. Received: 5 August 1998; in revised form: 3 September 1998 / Accepted: 3 September, 1998     

Control of spermatogenesis resumption in post-diapausing larvae of the codling moth

The lepidopteran primary spermatocytes produce first eupyrene (nucleated) and later apyrene (anucleated) spermatozoa. The shift to apyrene commitment of the spermatocytes is related to an apyrene-spermatogenesis-inducing factor (ASIF) becoming active towards pupation. During diapause, the primary spermatocytes lyse and spermatogenesis ceases. The renewal of the dichotomous spermatogenesis in the testes of post-diapausing, last-instar larvae of the codling moth was studied in vivo and in vitro. In vivo, the post-diapausing larvae resume the two types of spermatogenesis. Since ASIF activity is related to pupation, the earliest apyrene spermatids appear one day before pupation, as in non-diapausing larvae. In vitro, renewal of spermatogenesis occurs if 20-hydroxy-ecdysone is added to the medium, but only eupyrene spermatids occur since the testes are explanted before ASIF activity has started. These spermatids are unreduced and develop directly from primary spermatocytes which do not undergo meiotic divisions. Moreover, only flagella develop in these spermatids and the nuclei remain spherical. Post-diapause resumption of spermatogenesis is thus a complex process in which meiosis-blocking and meiosis-deblocking factors, ecdysteroids, and the ASIF play regulative roles.     

RNA interference during spermatogenesis in mice

Spermatogenesis consists of complex cellular and developmental processes, such as the mitotic proliferation of spermatogonial stem cells, meiotic division of spermatocytes, and morphogenesis of haploid spermatids. In this study, we show that RNA interference (RNAi) functions throughout spermatogenesis in mice. We first carried out in vivo DNA electroporation of the testis during the first wave of spermatogenesis to enable foreign gene expression in spermatogenic cells at different stages of differentiation. Using prepubertal testes at different ages and differentiation stage-specific promoters, reporter gene expression was predominantly observed in spermatogonia, spermatocytes, and round spermatids. This method was next applied to introduce DNA vectors that express small hairpin RNAs, and the sequence-specific reduction in the reporter gene products was confirmed at each stage of spermatogenesis. RNAi against endogenous Dmc1, which encodes a DNA recombinase that is expressed and functionally required in spermatocytes, led to the same phenotypes observed in null mutant mice. Thus, RNAi is effective in male germ cells during mitosis and meiosis as well as in haploid cells. This experimental system provides a novel tool for the rapid, first-pass assessment of the physiological functions of spermatogenic genes in vivo.     

Roles for Drp1, a dynamin-related protein, and milton, a kinesin-associated protein, in mitochondrial segregation, unfurling and elongation during Drosophila spermatogenesis

Mitochondria undergo dramatic rearrangement during Drosophila spermatogenesis. In wild type testes, the many small mitochondria present in pre-meiotic spermatocytes later aggregate, fuse, and interwrap in post-meiotic haploid spermatids to form the spherical Nebenkern, whose two giant mitochondrial compartments later unfurl and elongate beside the growing flagellar axoneme. Drp1 encodes a dynamin-related protein whose homologs in many organisms mediate mitochondrial fission and whose Drosophila homolog is known to govern mitochondrial morphology in neurons. The milton gene encodes an adaptor protein that links mitochondria with kinesin and that is required for mitochondrial transport in Drosophila neurons. To determine the roles of Drp1 and Milton in spermatogenesis, we used the FLP-FRT mitotic recombination system to generate spermatocytes homozygous for mutations in either gene in an otherwise heterozygous background. We found that absence of Drp1 leads to abnormal clustering of mitochondria in mature primary spermatocytes and aberrant unfurling of the mitochondrial derivatives in early Drp1 spermatids undergoing axonemal elongation. In milton spermatocytes, mitochondria are distributed normally; however, after meiosis, the Nebenkern is not strongly anchored to the nucleus, and the mitochondrial derivatives do not elongate properly. Our work defines specific functions for Drp1 and Milton in the anchoring, unfurling, and elongation of mitochondria during sperm formation.