The role of human and mouse Y chromosome genes in male infertility

Pathogenic landscape of idiopathic male infertility: new insight towards its regulatory networks

Idiopathic male infertility (IMI) affects nearly 10-15% of men in their prime reproductive age. More than 500 target genes were postulated to be associated with this disease condition through various genomic studies. The challenge is to determine the functional role of these genes and proteins that form part of a larger network leading to pathogenesis of the IMI phenotype in humans. In the current study, we have catalogued all of the genes associated with IMI from published studies, as well as looked at reactive oxygen species and antioxidant genes, the two key physiological determinants essential for normal spermatogenesis. Any imbalance in these genes through mutation, single-nucleotide polymorphisms (SNPs) or other forms could result in abnormal regulation of genes leading to infertility. SNPs catalogued in the current study, representing a third of the IMI genes, could possibly explain the various hidden factors associated with this condition. The enriched biological functions in SNPs, as well as functional analysis of IMI genes, resulted in the identification of novel gene pairs, from which we proposed new models to describe the underlying pathogenesis of this disease condition. The outcome of this study will give a new set of genes and proteins that could help explain the disease from a global perspective previously not addressed using standard approaches. Genes corresponding to proteins identified from the current study for spermatozoa and seminal plasma showed functional correlation based on their localization, which gave further confirmation of their roles in defective spermatogenesis as seen in IMI.

SSTY proteins co-localize with the post-meiotic sex chromatin and interact with regulators of its expression

In mammals, X- and Y-encoded genes are transcriptionally shut down during male meiosis, but expression of many of them is (re)activated in spermatids after meiosis. Post-meiotic XY gene expression is regulated by active epigenetic marks, which are de novo incorporated in the sex chromatin of spermatids, and by repressive epigenetic marks inherited during meiosis; alterations in this process lead to male infertility. In the mouse, post-meiotic XY gene expression is known to depend on genetic information carried by the male-specific region of the Y chromosome long arm (MSYq). The MSYq gene Sly has been shown to be a key regulator of post-meiotic sex chromosome gene expression and is necessary for the maintenance/recruitment of repressive epigenetic marks on the sex chromatin, but studies suggest that another MSYq gene may also be required. The best candidate to date is Ssty, an MSYq multi-copy gene of unknown function. Here, we show that SSTY proteins are specifically expressed in round and elongating spermatids, and co-localize with post-meiotic sex chromatin. Moreover, SSTY proteins interact with SLY protein and its X-linked homolog SLX/SLXL1, and may be required for localization of SLX/SLY proteins in the spermatid nucleus and sex chromatin. Our data suggest that SSTY is a second MSYq factor involved in the control of XY gene expression during sperm differentiation. As Slx/Slxl1 and Sly genes have been shown to be involved in the XY intra-genomic conflict, which affects the offspring sex ratio, Ssty may constitute another player in this conflict.

Male-biased genes in catfish as revealed by RNA-Seq analysis of the testis transcriptome

Background

Catfish has a male-heterogametic (XY) sex determination system, but genes involved in gonadogenesis, spermatogenesis, testicular determination, and sex determination are poorly understood. As a first step of understanding the transcriptome of the testis, here, we conducted RNA-Seq analysis using high throughput Illumina sequencing.

Methodology/Principal Findings

A total of 269.6 million high quality reads were assembled into 193,462 contigs with a N50 length of 806 bp. Of these contigs, 67,923 contigs had hits to a set of 25,307 unigenes, including 167 unique genes that had not been previously identified in catfish. A meta-analysis of expressed genes in the testis and in the gynogen (double haploid female) allowed the identification of 5,450 genes that are preferentially expressed in the testis, providing a pool of putative male-biased genes. Gene ontology and annotation analysis suggested that many of these male-biased genes were involved in gonadogenesis, spermatogenesis, testicular determination, gametogenesis, gonad differentiation, and possibly sex determination.

Conclusion/Significance

We provide the first transcriptome-level analysis of the catfish testis. Our analysis would lay the basis for sequential follow-up studies of genes involved in sex determination and differentiation in catfish.

Sexual differentiation of behavior: the foundation of a developmental model of psychosexuality

The sexual differentiation of the brain and behavior occurs as the result of prenatal hormonal influences. Knowledge of this area is helpful for the construction of an appropriately modern psychoanalytically informed developmental paradigm of psychosexuality.

Centimorgan-range one-step mapping of fertility traits using interspecific recombinant congenic mice

In mammals, male fertility is a quantitative feature determined by numerous genes. Until now, several wide chromosomal regions involved in fertility have been defined by genetic mapping approaches; unfortunately, the underlying genes are very difficult to identify. Here, 53 interspecific recombinant congenic mouse strains (IRCSs) bearing 1-2% SEG/Pas (Mus spretus) genomic fragments disseminated in a C57Bl/6J (Mus domesticus) background were used to systematically analyze male fertility parameters. One of the most prominent advantages of this model is the possibility of analyzing stable phenotypes in living animals. Here, we demonstrate the possibility in one-step fine mapping for several fertility traits. Focusing on strains harboring a unique spretus fragment, we could unambiguously localize two testis and one prostate weight-regulating QTL (Ltw1, Ltw2, and Lpw1), four QTL controlling the sperm nucleus shape (Sh1, Sh2, Sh3, and Sh4), and one QTL influencing sperm survival (Dss1). In several cases, the spretus DNA fragment was small enough to propose sound candidates. For instance, Spata1, Capza, and Tuba7 are very strong candidates for influencing the shape of the sperm head. Identifying new genes implied in mammalian fertility pathways is a necessary prerequisite for clarifying their molecular grounds and for proposing diagnostic tools for masculine infertilities.

Analysis of sex chromosome abnormalities using X and Y chromosome DNA tiling path arrays

BACKGROUND

Array comparative genomic hybridisation is a powerful tool for the detection of copy number changes in the genome.

METHODS

A human X and Y chromosome tiling path array was developed for the analysis of sex chromosome aberrations.

RESULTS

Normal X and Y chromosome profiles were established by analysis with DNA from normal fertile males and females. Detection of infertile males with known Y deletions confirmed the competence of the array to detect AZFa, AZFb and AZFc deletions and to distinguish between different AZFc lesions. Examples of terminal and interstitial deletions of Xp (previously characterised through cytogenetic and microsatellite analysis) have been assessed using the arrays, thus both confirming and refining the established deletion breakpoints. Breakpoints in iso-Yq, iso-Yp and X-Y translocation chromosomes and X-Y interchanges in XX males are also amenable to analysis.

DISCUSSION

The resolution of the tiling path clone set used allows breakpoints to be placed within 100-200 kb, permitting more precise genotype/phenotype correlations. These data indicate that the combined X and Y tiling path arrays provide an effective tool for the investigation and diagnosis of sex chromosome copy number aberrations and rearrangements.

The genetic and cytogenetic basis of male infertility

Despite the difficulties in determining the relative maternal vs. paternal contributions to infertility it is often suggested that a male factor problem is implicated in 50% of cases. This review is concerned specifically with male fertility disorders that have a clearly defined genetic component. The genetic causes of infertility can be broken down into Y chromosome deletions (specifically deletions in the AZF a, b, and c regions), single gene disorders (particularly those relating to the CFTR gene), multifactorial causes and chromosome abnormalities. Chromosome abnormalities can be numerical (such as trisomy--full blown or mosaic) or structural (such as inversions or translocations). Of especial interest at present is the incidence of levels of numerical chromosome abnormalities in the sperm of infertile men; prospects for screening sperm for such abnormalities are discussed.

A detailed physical map of the horse Y chromosome

We herein report a detailed physical map of the horse Y chromosome. The euchromatic region of the chromosome comprises approximately 15 megabases (Mb) of the total 45- to 50-Mb size and lies in the distal one-third of the long arm, where the pseudoautosomal region (PAR) is located terminally. The rest of the chromosome is predominantly heterochromatic. Because of the unusual organization of the chromosome (common to all mammalian Y chromosomes), a number of approaches were used to crossvalidate the results. Analysis of the 5,000-rad horse x hamster radiation hybrid panel produced a map spanning 88 centirays with 8 genes and 15 sequence-tagged site (STS) markers. The map was verified by several fluorescence in situ hybridization approaches. Isolation of bacterial artificial chromosome (BAC) clones for the radiation hybrid-mapped markers, end sequencing of the BACs, STS development, and bidirectional chromosome walking yielded 109 markers (100 STS and 9 genes) contained in 73 BACs. STS content mapping grouped the BACs into seven physically ordered contigs (of which one is predominantly ampliconic) that were verified by metaphase-, interphase-, and fiber-fluorescence in situ hybridization and also BAC fingerprinting. The map spans almost the entire euchromatic region of the chromosome, of which 20-25% (approximately 4 Mb) is covered by isolated BACs. The map is presently the most informative among Y chromosome maps in domesticated species, third only to the human and mouse maps. The foundation laid through the map will be critical in obtaining complete sequence of the euchromatic region of the horse Y chromosome, with an aim to identify Y specific factors governing male infertility and phenotypic sex variation.

Immunodetection of aromatase in mice with a partial deletion in the long arm of the Y chromosome

Aromatization of androgens into estrogens is catalyzed by a microsomal enzyme, P450 aromatase. Males of the mouse strain B10.BR and its congenic mutant strain B10.BR-Ydel (with a partial deletion in the long arm of the Y chromosome) were used to identify the cellular source of estrogens within the testis. Immunocytochemistry was applied to localize aromatase in cultured Leydig cells, cytoplasmic droplets attached to flagella of spermatozoa, and sections of testes. The presence of aromatase in testes was checked by means of Western-blot analysis. Steroid hormones secreted by Leydig cells in vitro were measured in homogenates of testes using radioimmunological methods. Additionally, a Southern analysis was performed using the Y353/B probe to check the length of the deletion in the Y chromosome. In sections of testis of B10.BR mice, weak to moderate immunohistochemical staining of aromatase was found in Leydig cells, Sertoli cells, and germ cells. In testicular cells of B10.BR-Ydel mice, stronger immunostaining of aromatase was observed, especially in germ cells and Leydig cells. Positivity for aromatase was also found in the cytoplasm of cultured Leydig cells from both strains, but it was higher in cells derived from mutant males. Western-blot analysis revealed one major band of approx. 55kDa of aromatase in testes from both strains. Lower testosterone levels were found in mutant males in supernatants of culture media and homogenates of testes in comparison with control males. In contrast, estradiol levels were always higher in mutants. Therefore, it seems likely that the increased expression of aromatase and, as a consequence, the higher levels of endogenous estrogens enhance the morphological alterations in testis and affect spermatogenesis in mutant males.

Scanning of Y-chromosome azoospermia factors loci using real-time polymerase chain reaction and melting curve analysis

OBJECTIVE

To develop a novel method to scan AZF loci looking for microdeletions.

DESIGN

Molecular method development.

SETTING

Men undergoing reproductive techniques in a private fertility unit. Molecular methods were performed in a private center for biomedical research.

PATIENT(S)

: Fifty-eight men divided in two groups depending on seminal analyses. A group of 19 women were also included as positive controls (absence of amplification).

INTERVENTION(S)

Peripheral blood extraction and DNA purification.

MAIN OUTCOME MEASURE(S)

Our method is based on real-time polymerase chain reaction (PCR) and melting curve analysis. We performed the screening of 16 selected sequence tagged sites (STS) within AZF loci, and we also calculated the mean, range, and standard deviation for melting temperature patterns and the crossing points values for each STS tested.

RESULT(S)

We detected one azoospermic patient with several STS deleted within the AZFc region. No deletions were detected in a group of 13 healthy men, and no amplification for any of the STS tested were observed in the positive control group (19 healthy women).

CONCLUSION(S)

We have developed a novel method based on real-time PCR and melting curve analysis to scan AZF loci looking for microdeletions This method is fast and reliable and permits the scanning of DNA from one patient per hour, minimizing the risk of cross contamination, and false-positive and false-negative results.