42 research outputs found

    Form from Function, Order from Chaos in Male Germline Chromatin

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    Spermatogenesis requires radical restructuring of germline chromatin at multiple stages, involving co-ordinated waves of DNA methylation and demethylation, histone modification, replacement and removal occurring before, during and after meiosis. This Special Issue has drawn together papers addressing many aspects of chromatin organization and dynamics in the male germ line, in humans and in model organisms. Two major themes emerge from these studies: the first is the functional significance of nuclear organisation in the developing germline; the second is the interplay between sperm chromatin structure and susceptibility to DNA damage and mutation. The consequences of these aspects for fertility, both in humans and other animals, is a major health and social welfare issue and this is reflected in these nine exciting manuscripts

    A genetic basis for a postmeiotic X versus Y chromosome intragenomic conflict in the mouse.

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    Intragenomic conflicts arise when a genetic element favours its own transmission to the detriment of others. Conflicts over sex chromosome transmission are expected to have influenced genome structure, gene regulation, and speciation. In the mouse, the existence of an intragenomic conflict between X- and Y-linked multicopy genes has long been suggested but never demonstrated. The Y-encoded multicopy gene Sly has been shown to have a predominant role in the epigenetic repression of post meiotic sex chromatin (PMSC) and, as such, represses X and Y genes, among which are its X-linked homologs Slx and Slxl1. Here, we produced mice that are deficient for both Sly and Slx/Slxl1 and observed that Slx/Slxl1 has an opposite role to that of Sly, in that it stimulates XY gene expression in spermatids. Slx/Slxl1 deficiency rescues the sperm differentiation defects and near sterility caused by Sly deficiency and vice versa. Slx/Slxl1 deficiency also causes a sex ratio distortion towards the production of male offspring that is corrected by Sly deficiency. All in all, our data show that Slx/Slxl1 and Sly have antagonistic effects during sperm differentiation and are involved in a postmeiotic intragenomic conflict that causes segregation distortion and male sterility. This is undoubtedly what drove the massive gene amplification on the mouse X and Y chromosomes. It may also be at the basis of cases of F1 male hybrid sterility where the balance between Slx/Slxl1 and Sly copy number, and therefore expression, is disrupted. To the best of our knowledge, our work is the first demonstration of a competition occurring between X and Y related genes in mammals. It also provides a biological basis for the concept that intragenomic conflict is an important evolutionary force which impacts on gene expression, genome structure, and speciation

    The multicopy gene Sly represses the sex chromosomes in the male mouse germline after meiosis.

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    Studies of mice with Y chromosome long arm deficiencies suggest that the male-specific region (MSYq) encodes information required for sperm differentiation and postmeiotic sex chromatin repression (PSCR). Several genes have been identified on MSYq, but because they are present in more than 40 copies each, their functions cannot be investigated using traditional gene targeting. Here, we generate transgenic mice producing small interfering RNAs that specifically target the transcripts of the MSYq-encoded multicopy gene Sly (Sycp3-like Y-linked). Microarray analyses performed on these Sly-deficient males and on MSYq-deficient males show a remarkable up-regulation of sex chromosome genes in spermatids. SLY protein colocalizes with the X and Y chromatin in spermatids of normal males, and Sly deficiency leads to defective repressive marks on the sex chromatin, such as reduced levels of the heterochromatin protein CBX1 and of histone H3 methylated at lysine 9. Sly-deficient mice, just like MSYq-deficient mice, have severe impairment of sperm differentiation and are near sterile. We propose that their spermiogenesis phenotype is a consequence of the change in spermatid gene expression following Sly deficiency. To our knowledge, this is the first successful targeted disruption of the function of a multicopy gene (or of any Y gene). It shows that SLY has a predominant role in PSCR, either via direct interaction with the spermatid sex chromatin or via interaction with sex chromatin protein partners. Sly deficiency is the major underlying cause of the spectrum of anomalies identified 17 y ago in MSYq-deficient males. Our results also suggest that the expansion of sex-linked spermatid-expressed genes in mouse is a consequence of the enhancement of PSCR that accompanies Sly amplification

    A shared ‘vulnerability code’ underpins varying sources of DNA damage throughout paternal germline transmission in mouse

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    During mammalian spermatogenesis, the paternal genome is extensively remodelled via replacement of histones with protamines forming the highly compact mature sperm nucleus. Compaction occurs in post-meiotic spermatids and is accompanied by extensive double strand break (DSB) formation. We investigate the epigenomic and genomic context of mouse spermatid DSBs, identifying primary sequence motifs, secondary DNA structures and chromatin contexts associated with this damage. Consistent with previously published results we find spermatid DSBs positively associated with short tandem repeats and LINE elements. We further show spermatid DSBs preferentially occur in association with (CA)n, (NA)n and (RY)n repeats, in predicted Z-DNA, are not associated with G-quadruplexes, are preferentially found in regions of low histone mark coverage and engage the remodelling/NHEJ factor BRD4. Locations incurring DSBs in spermatids also show distinct epigenetic profiles throughout later developmental stages: regions retaining histones in mature sperm, regions susceptible to oxidative damage in mature sperm, and fragile two-cell like embryonic stem cell regions bound by ZSCAN4 all co-localise with spermatid DSBs and with each other. Our results point to a common ‘vulnerability code’ unifying several types of DNA damage occurring on the paternal genome during reproduction, potentially underpinned by torsional changes during sperm chromatin remodelling

    Zfy genes are required for efficient meiotic sex chromosome inactivation (MSCI) in spermatocytes

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    During spermatogenesis, germ cells that fail to synapse their chromosomes or fail to undergo meiotic sex chromosome inactivation (MSCI) are eliminated via apoptosis during mid-pachytene. Previous work showed that Y-linked genes Zfy1 and Zfy2 act as "executioners" for this checkpoint, and that wrongful expression of either gene during pachytene triggers germ cell death. Here, we show that in mice, Zfy genes are also necessary for efficient MSCI and the sex chromosomes are not correctly silenced in Zfy-deficient spermatocytes. This unexpectedly reveals a triple role for Zfy at the mid-pachytene checkpoint in which Zfy genes first promote MSCI, then monitor its progress (since if MSCI is achieved, Zfy genes will be silenced), and finally execute cells with MSCI failure. This potentially constitutes a negative feedback loop governing this critical checkpoint mechanism

    Implementation of World Health Organization Recommendations for Semen Analysis: A Survey of Laboratories in the United Kingdom

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    The standard method for identification of male fertility status is a semen analysis. This is performed in fertility and pathology laboratories accredited by different bodies in the UK such as the HFEA or UKAS, and is based on whether they perform licenced clinical treatment or diagnostic testing. The WHO laboratory semen analysis criteria provide the most comprehensive guidance for best practice, yet this is not strictly adhered to. Our objective was to determine any differences in semen analyses between laboratories in the UK, based on the regulatory body they are registered with. A cross-sectional survey was sent to NEQAS for andrology registrants (n=184 laboratories), HFEA (n=117 clinics), and individual ARCS members (n=682). Most ARCS members are associated with NEQAS and/or the HFEA. A ∼50% laboratory response rate (n=106 included responses) was found. Results were grouped based on accreditation: Group 1, UKAS accredited only (n=38); Group 2, both UKAS accredited and HFEA licenced (n=17); Group 3, HFEA licenced only (n=42); and Group 4, no accreditation (n=9). Over 85%of UKAS accredited laboratories (Groups 1 and 2) state they perform semen analysis according to WHO 2010 recommendations and adhere to best practice guidelines. A significantly fewer number of HFEA only laboratories (<74% Group 3, p <0:01) adhere to both guidelines. Non-HFEA laboratories (Groups 1 and 4) are almost all performing sperm counts according to WHO criteria, while <60% HFEA clinics (Groups 2 and 3) perform counts according to regulation (Group 1 vs. Groups 2 and 3: Fixed sperm, p <0:05; Neubauer chamber: p <0:005). QC is implemented in most laboratories, however there is a significant difference (p <0:01) between non- UKAS (Groups 3 and 4) and UKAS laboratories (Groups 1 and 2). There is a significant difference in semen analysis performance between UKAS and HFEA laboratories with regards to implementation of best practice guidelines and QC procedures. This may have a detrimental effect on result accuracy and consequently lead to patient misdiagnosis and mismanagement

    Successful recovery of motile and viable boar sperm after vitrification with different methods (pearls and mini straws) using sucrose as a cryoprotectant

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    Vitrification of sperm by direct contact with liquid nitrogen is increasing in popularity as an alternative to conventional (slow) freezing. Although slow freezing is very challenging in boar sperm cryopreservation, this is currently the standard method used. We compared vitrification in “pearls” and in “mini straws” using the in vitro fertilization media Porcine Gamete Media with 0.3 M sucrose with the standard (slow) method used to preserve boar sperm. Both vitrification methods reduced the viability of the sperm sample more than slow freezing (42.2 ± 4.3% total motility and 71.4 ± 2.3% alive), however, both protocols allowed for the successful recovery of the sperm samples. By comparing two different methods of vitrification and two different methods of post-thaw preparation we were able to determine the optimal vitrification-thaw protocol for boar sperm. When comparing pearls and mini-straws, the smaller liquid volume associated with pearls had a positive effect on the survivability of the samples, reducing sperm DNA damage (1.2 ± 0.2% vs. 5.1 ± 0.1.7%) and preserving motility (26.15 ± 2.8% vs 9.39 ± 0.9%) after thawing. In conclusion, the pearl method was the most suitable of the vitrification techniques for use with boar sperm

    The contribution of sex chromosome conflict to disrupted spermatogenesis in hybrid house mice

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    Incompatibilities on the sex chromosomes are important in the evolution of hybrid male sterility, but the evolutionary forces underlying this phenomenon are unclear. House mice (Mus musculus) lineages have provided powerful models for understanding the genetic basis of hybrid male sterility. X chromosome-autosome interactions cause strong incompatibilities in Mus musculus F1 hybrids, but variation in sterility phenotypes suggests a more complex genetic basis. Additionally, X-Y chromosome conflict has resulted in rapid expansions of ampliconic genes with dosage-dependent expression that is essential to spermatogenesis. Here we evaluated the contribution of X-Y lineage mismatch to male fertility and stage-specific gene expression in hybrid mice. We performed backcrosses between two house mouse subspecies to generate reciprocal Y-introgression strains and used these strains to test the effects of X-Y mismatch in hybrids. Our transcriptome analyses of sorted spermatid cells revealed widespread overexpression of the X chromosome in sterile F1 hybrids independent of Y chromosome subspecies origin. Thus, postmeiotic overexpression of the X chromosome in sterile F1 mouse hybrids is likely a downstream consequence of disrupted meiotic X-inactivation rather than X-Y gene copy number imbalance. Y-chromosome introgression did result in subfertility phenotypes and disrupted expression of several autosomal genes in mice with an otherwise non-hybrid genomic background, suggesting that Y-linked incompatibilities contribute to reproductive barriers, but likely not as a direct consequence of X-Y conflict. Collectively, these findings suggest that rapid sex chromosome gene family evolution driven by genomic conflict has not resulted in strong male reproductive barriers between these subspecies of house mice

    A Targeted and Tuneable DNA Damage Tool Using CRISPR/Cas9

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    Mammalian cells are constantly subjected to a variety of DNA damaging events that lead to the activation of DNA repair pathways. Understanding the molecular mechanisms of the DNA damage response allows the development of therapeutics which target elements of these pathways. Double-strand breaks (DSB) are particularly deleterious to cell viability and genome stability. Typically, DSB repair is studied using DNA damaging agents such as ionising irradiation or genotoxic drugs. These induce random lesions at non-predictive genome sites, where damage dosage is difficult to control. Such interventions are unsuitable for studying how different DNA damage recognition and repair pathways are invoked at specific DSB sites in relation to the local chromatin state. The RNA-guided Cas9 (CRISPR-associated protein 9) endonuclease enzyme is a powerful tool to mediate targeted genome alterations. Cas9-based genomic intervention is attained through DSB formation in the genomic area of interest. Here, we have harnessed the power to induce DSBs at defined quantities and locations across the human genome, using custom-designed promiscuous guide RNAs, based on in silico predictions. This was achieved using electroporation of recombinant Cas9-guide complex, which provides a generic, low-cost and rapid methodology for inducing controlled DNA damage in cell culture models. View Full-Tex

    Complex master-slave enhanced optical coherence microscopy

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    We present an instrument designed to facilitate localization and high-resolution, optical coherence microscopy (OCM) imaging of small biological samples immersed in a medium several orders of magnitude greater in volume. A modified turret-equipped microscope stand was inserted into the sample arm of a spectral domain optical coherence microscopy (SD-OCM) system. The instrument enabled swift change of imaging objectives through the incorporation of complex master-slave interferometry (CMSI), providing tolerance to dispersion for any objective through the acquisition of a few (≥2) calibration spectra. We demonstrate the instrument’s ability to localize and image samples by providing examples of its application to optical phantoms and to a porcine oocyte immersed in a biological culture medium
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