Routine diagnostic testing of Y chromosome deletions in male infertile and subfertile

Male factor infertility elucidated about half the couple of infertility and in around 50% of cases, its etiology remains unknown. The aim of this study was to investigate a predisposing genetic background for Yq deletions and male infertility and effectiveness of molecular genetic approaches have uncovered several etiopathogenetic factors, such as microdeletions of Yq chromosome. The Y chromosome microdeletions removing the azoospermia factor (AZF) regions, which are most common molecular genetic causes of oligospermia or azoospermia. However, with the analysis of Yq deletions, we are able to obtain a better understanding of the clinical significance of genetic anomaly and to the identifying of fertility candidate genes in the AZF regions. Molecular genetic approaches, becomes a routine diagnostic test, that provides an etiology for spermatogenic disturbances, and prognosis for testicular sperm retrieval according to the type of deletion.     

X chromosomal mutations and spermatogenic failure

The X and Y chromosomes, the sex chromosomes, are important key players in germ cell development. Both chromosomes contain genes that are uniquely expressed in male spermatogenesis. Furthermore, these chromosomes are special because men only have a single copy of them. These features make the sex chromosomes interesting for studying in view of spermatogenesis defects. The role of the Y chromosome, together with the presence of Yq microdeletions, in male infertility is well established. Less well-understood are the X-linked genes, their expression patterns and potential impact on male infertility. This review provides an overview of the current knowledge on potential spermatogenesis genes that are located on the mouse and human X chromosomes. A summary is given on knock-out mice models in which X-linked genes have been shown to alter spermatogenesis, and on genes that have been studied in humans. Finally, new research areas like miRNA analysis, Genome Wide Association Studies (GWAS) and array comparative genomic hybridisation (CGH) studies are discussed. This article is part of a Special Issue entitled: Molecular Genetics of Human Reproductive Failure.     

Y chromosome microdeletions in Brazilian fertility clinic patients

Microdeletions in Yq are associated with defects in spermatogenesis, while those in the AZF region are considered critical for germ cell development. We examined microdeletions in the Y chromosomes of patients attended at the Laboratory of Human Reproduction of the Clinical Hospital of the Federal University of Goiás as part of a screening of patients who plan to undergo assisted reproduction. Analysis was made of the AZF region of the Y chromosome in men who had altered spermograms to detect possible microdeletions in Yq. Twenty-three patients with azoospermia and 40 with severe oligozoospermia were analyzed by PCR for the detection of six sequence-tagged sites: sY84 and sY86 for AZFa, sY127 and sY134 for AZFb, and sY254 and sY255 for AZFc. Microdeletions were detected in 28 patients, including 10 azoospermics and 18 severe oligozoospermics. The patients with azoospermia had 43.4% of their microdeletions in the AZFa region, 8.6% in the AZFb region and 17.4% in the AZFc region. In the severe oligozoospermics, 40% were in the AZFa region, 5% in the AZFb region and 5% in the AZFc region. We conclude that microdeletions can be the cause of idiopathic male infertility, supporting conclusions from previous studies.     

Chromosome microarray analysis: a case report of infertile brothers with CATSPER gene deletion

We present the case of two brothers who were referred to a male infertility clinic for infertility workup. Conventional chromosome analysis and Y chromosome microdeletions did not reveal any genetic alterations. We utilized the chromosome microarray analysis (CMA) to identify novel and common variations associated with this severely impaired spermatogenesis cases. CMA specific results showed a common deletion in the 15q15.3 region that harbors genes like CATSPER2, STRC and PPIP5K1 in both cases (M18 and M19). In addition we identified small duplication in X and 11 chromosomes of M19. This is the first familial case report from India on occurrence of CATSPER gene deletion in human male infertility.     

AZF microdeletions on the Y chromosome of infertile men from Turkey

Intervals V and VI of Yq11.23 regions contain responsible genes for spermatogenesis, and are named as "azoospermia factor locus" (AZF). Deletions in these genes are thought to be pathogenetically involved in some cases of male infertility associated with azoospermia or oligozoospermia. The aim of this study was to establish the prevalence of microdeletions on the Y chromosome in infertile Turkish males with azoospermia or oligozoospermia. We applied multiplex polymerase chain reaction (PCR) using several sequence-tagged site (STS) primer sets, in order to determine Y chromosome microdeletions. In this study, 61 infertile males were enrolled for the molecular AZF screening program. In this cohort, one infertile male had 46,XX karyotype and the remaining had 46,XY karyotypes. Forty-eight patients had a diagnosis of azoospermia and 13 had oligozoospermia. Microdeletions in AZFa, AZFb and AZFc (DAZ gene) regions were detected in two of the 60 (3.3%) idiopathic infertile males with normal karyotypes and a SRY translocation was determined on 46,XX male. Our findings suggest that genetic screening should be advised to infertile men before starting assisted reproductive treatments.     

Detection of Y chromosome microdeletions and mitochondrial DNA mutations in male infertility patients

Infertility affects about 10-15% of all couples attempting pregnancy with infertility attributed to the male partner in approximately half of the cases. Proposed causes of male infertility include sperm motility disturbances, Y chromosome microdeletions, chromosomal abnormalities, single gene mutations, and sperm mitochondrial DNA (mtDNA) rearrangements. To investigate the etiology of decreased sperm fertility and motility of sperm and to develop an appropriate therapeutic strategy, the molecular basis of these defects must be elucidated. In this study, we aimed to reveal the relationships between the genetic factors including sperm mtDNA mutations, Y chromosome microdeletions, and sperm parameters that can be regarded as candidate factors for male infertility. Thirty men with a history of infertility and 30 fertile men were recruited to the study. Y chromosome microdeletions were analyzed by multiplex PCR. Mitochondrial genes ATPase6, Cytb, and ND1, were amplified by PCR and then analyzed by direct sequencing. No Y chromosome microdeletions were detected in either group. However, a total of 38 different nucleotide substitutions were identified in the examined mitochondrial genes in both groups, all of which are statistically non-significant. Fifteen substitutions caused an amino acid change and 12 were considered novel mutations. As a conclusion, mtDNA mutations and Y chromosome microdeletions in male infertility should be examined in larger numbers in order to clarify the effect of genetic factors.     

A new deletion of the mouse Y chromosome long arm associated with the loss of Ssty expression, abnormal sperm development and sterility

The mouse Y chromosome carries 10 distinct genes or gene families that have open reading frames suggestive of retained functionality; it has been assumed that many of these function in spermatogenesis. However, we have recently shown that only two Y genes, the testis determinant Sry and the translation initiation factor Eif2s3y, are essential for spermatogenesis to proceed to the round spermatid stage. Thus, any further substantive mouse Y-gene functions in spermatogenesis are likely to be during sperm differentiation. The complex Ssty gene family present on the mouse Y long arm (Yq) has been implicated in sperm development, with partial Yq deletions that reduce Ssty expression resulting in impaired fertilization efficiency. Here we report the identification of a more extensive Yq deletion that abolishes Ssty expression and results in severe sperm defects and sterility. This result establishes that genetic information (Ssty?) essential for normal sperm differentiation and function is present on mouse Yq.     

Necessity of nuclear and mitochondrial genome analysis prior to assisted reproductive techniques/intracytoplasmic sperm injection

Assisted reproductive technique (ART) has revolutionized the management of severe male factor infertility and in some countries 5% babies are conceived through ART/intra cytoplasmic sperm injection (ICSI). However, the carry-home live birth rate after several ART cycles is low (18-25%) and this is financially, physically and emotionally crippling for the couples. Genetic factors could lead to pre or post-implantation failure and thus explain for low ART success rate. Thus, this study was planned to understand, if infertile men harbour genetic abnormalities which may be iatrogenically transmitted by ART and adversely affect growth potential of embryo. Ninety infertile men underwent semen, cytogenetic, Yq microdeletion and mitochondrial mutation analysis. Of these, 14.4% cases harboured cytogenetic abnormality, and 8.89% Yq microdeletions. A high frequency of mitochondrial mutations was found in 23 men with asthenospermia. It is important to understand that through ART genetic abnormalities are transmitted to offspring, resulting in impaired growth and development potential of embryo and poor take-home live birth rate. Thus, genetic analysis is strongly recommend in all men with idiopathic infertility who opt for ART to counsel couples and provide them with most adapted therapeutics.     

Types of Y chromosome deletions and their frequency in infertile men

Deletions of Y chromosome AZF locus were analyzed during a large-scale andrological and genetic examination of 810 infertile men. The search for Yq microdeletions was carried out according to the standard EAA/EMQN guidelines. The breakpoints were mapped for the deletions in AZF locus. The Y chromosome macro- and microdeletions were detected in 61 (7.5%) infertile men. The frequencies of AZF deletions during azoospermia and severe oligozoospermia amounted to 12.2 and 8.1 %, respectively. On the whole, the frequencies of Yq microdeletions and the genophenotypic correlations characteristic of various AZF deletion types comply with the relevant published data. However, spermatozoids in the ejaculate sediment of men with completely deleted AZFa region or AZFb+c deletions (from solitary spermatozoids to several dozens) were detected for the first time. It was demonstrated that the breakpoints were localized between AZFa and AZFb regions proximally to AZFb+c microdeletions for the majority of cytogenetically detectable deletions in the Y chromosome long arm. This indicates that the mechanisms underlying Yq macro- and microdeletions are somewhat different. The issues related to the role of Y chromosome deletions in the origins of monosomy for X chromosome and X/XY mosaicism are discussed.     

Types of Y chromosome deletions and their frequency in infertile men

Y chromosome deletions in the AZF locus were analyzed during a large-scale andrological and genetic examination of 810 infertile men. The search for Yq microdeletions was carried out according to the standard EAA/EMQN guidelines. The breakpoints were mapped for the revealed AZF deletions. The Y chromosome macro-and microdeletions were detected in 61 (7.5%) infertile men. The frequencies of AZF deletions in patients with azoospermia and severe oligozoospermia amounted to 12.2 and 8.1%, respectively. On the whole, the frequencies of Yq microdeletions and the genophenotypic correlations characteristic of various AZF deletion types agree with the relevant published data. However, spermatozoa in the ejaculate sediment of men with completely deleted AZFa region or AZFb+c deletions (from solitary spermatozoa to several dozens) were detected for the first time. It was demonstrated that the breakpoints were localized between AZFa and AZFb regions proximally to AZFb+c microdeletions for the majority of cytogenetically detectable deletions of the Y chromosome long arm. This indicates that the mechanisms underlying Yq macro-and microdeletions are somewhat different. The issues related to the role of Y chromosome deletions in the origins of X chromosome monosomy and X/XY mosaicism are discussed.     

无精子症和严重少精子症患者Y染色体微缺失研究

目的：研究Y染色体微缺失与男性不育的关系。方法：采用多重PCR技术,研究正常男性、无精子症和严重少精子症男性不育患者Y染色体无精子因子（AZF）区域3个序列标志位点（STS）的缺失情况。结果：在93例无精子症或严重少精子症患者中,15例有Y染色体微缺失,缺失率为16%。其中,42例无精子症患者中,6例为AZFc区SY255位点缺失,2例为AZFb区SY134位点缺失;51例严重少精子症患者中,7例为AZFc区SY255位点缺失。40例正常男性无Y染色体微缺失。结论：多重PCR技术是简便而有效的对男性不育患者进行Y染色体微缺失筛查的方法;Y染色体微缺失是造成男性不育的一个重要原因,对男性不育患者进行辅助生育技术治疗前应常规进行Y染色体微缺失的检测。     

Reduction in the DAZ gene copy number in two infertile men with impaired spermatogenesis.

Microdeletions of Yq are associated with azoospermia and severe oligozoospermia. Recently, we described a new molecular genetic strategy based on the denaturing gradient gel electrophoresis (DGGE) to rapidly identify deletions of the Y chromosome that include the DAZ locus. Using this approach, we have shown not a complete deletion but only a reduction in the number of copies of the DAZ gene by PCR-DGGE in two oligozoospermic patients. These results have been confirmed by Southern blot analysis. This finding suggests that partial deletion of the DAZ cluster could be cause of impaired spermatogenesis.     

Prescription et pratique de la recherche des microdélétions du chromosome Y en France: résultats de l’enquête nationale réalisée sous l’égide de la Société d’Andrologie de Langue Française

Screening for Y chromosome microdeletions is recommended in cases of severe impaired spermatogenesis. Improvement of molecular biology techniques has made this diagnosis more accessible in routine practice when evaluation of male infertility is necessary. However, the diagnosis of Y chromosome microdeletions is not proposed by all IVF centres. The aim of the present study was to specify the prescribing conditions (indication, financing) and practical conduct (methods, billing) for this analysis in France. We observed that microdeletion screening is a rapidly expanding activity. The development of a consensus on the indications for this screening and a standardised technique, with a national quality control, appears to be necessary. The funding of this analysis by French Social Security appears to be an essential step to ensure widespread use in routine practice. Lastly, the answers to our questionnaire revealed a strong demand for information concerning this analysis.     

Screening for microdeletions in human Y chromosome--AZF candidate genes and male infertility

About 30% of couple infertilities are of male origin, some of them caused by genetic abnormalities of the Y chromosome. Deletions in AZF region can cause severe spermatogenic defects ranging from non-obstructive azoospermia to oligospermia. The intracytoplasmatic sperm injection technique (ICSI) is rapidly becoming a versatile procedure for human assisted reproduction in case of male infertility. The use of ICSI allows Y chromosome defects to be passed from father. The goal of our study is to evaluate the frequency of microdeletions in the long arm of Y chromosome, within the AZF regions, in these cases of infertilities, using molecular genetics techniques. Thirty infertile men with azoospermia or oligozoospermia, determined by spermogram, were studied after exclusion of patients with endocrine or obstructive causes of infertility. Peripheral blood DNA was extracted from each patient, then amplified by multiplex PCR with STS genomic markers from the Y chromosome AZF zones. Each case was checked by multiplex PCR through coamplification with the SRY marker. Three men with microdeletions of the long arm of the Y chromosome were diagnosed among the 30 patients, corresponding to a proportion of 10%. The relatively high proportion of microdeletions found in our population suggest the need for strict patient selection to avoid unnecessary screening for long arm Y chromosome microdeletions. The molecular diagnostics was performed according to the current European Academy of Andrology laboratory guidelines for molecular diagnosis of Y chromosomal microdeletions.     

A cost-effective screening test for detecting AZF microdeletions on the human Y chromosome

PCR-based screening of microdeletions in the azoospermic factor (AZF) on the Yq chromosome is an accepted means of identifying a common genetic cause of male infertility, responsible for 5-15% of cases associated with a low sperm count (相似文献   

Molecular analysis of Y chromosome microdeletions in idiopathic cases of male infertility in Serbia

The aim of this study was to detect frequency of microdeletions of Y chromosome in idiopathic cases of male infertility in Serbian population. Patients were subjected to detailed clinical, endocrinological and cytogenetic examinations. Ninety patients with normal cytogenetic findings with azoospermia and severe oligozoospermia were included in the study. In these patients microdeletion analysis was performed by multiplex polymerase chain reaction (PCR) method on DNA extracted from peripheral blood. In each case 6 markers in azoospermia factor (AZF) regions were tested: sY84, sY86 (AZFa); sY127, sY134 (AZFb); sY254, sY255 (AZFc). Deletions on Y chromosome were detected in 14 of 90 cases (15.6%), 9 with azoospermia and 5 with severe oligozoospermia. Of total number of 17 deletions, 11 (64.7%) were detected in AZFc region, 3 (17.6%) in AZFa region and 3 (17.6%) in AZFb region. Microdeletions in AZF region of Y chromosome, especially AZFc microdeletions, represent common genetic cause of idiopathic azoospermia and severe oligozoospremia in Serbian infertile men. Therefore, testing for Y chromosome microdeletions should be considered as an important element in diagnosis and genetic counseling of infertile men in Serbia and decisions regarding the assisted reproduction should be made based on the presence and type of AZF microdeletions.     

Tracking microdeletions of the AZF region in a patrilineal line of infertile men

Male infertility is considered to be a difficult-to-treat condition because it is not a single entity, but rather reflects a variety of different pathologic conditions, thus making it difficult to use a single treatment strategy. Structural alterations in the Y chromosome have been the principal factor responsible for male infertility. We examined 26 family members of 13 patients with male infertility who showed deletions in the AZF region. In family 1, the father and a brother did not show microdeletions. However, a son showed a microdeletion in AZFa (sY84) and an azoospermic sperm analysis, but another son had a microdeletion in AZFa (sY84) and AZFb (sY127) and a normal sperm analysis. The father of family 2, with severe oligozoospermia, had a microdeletion in the AZFa region (sY84) and his son, conceived by intracytoplasmic sperm injection, also showed the same microdeletion. In the other families, only the men with an altered sperm analysis had a microdeletion. It is possible that in family 1, the father and brother who did not show microdeletions in this study, could have microdeletions in regions upstream or downstream of the one analyzed. The treatment with intracytoplasmic sperm injection can result in vertical transmission of microdeletions of the AZF region and can also cause the expansion of a de novo mutation. This finding reinforces the necessity of an investigation of microdeletions of the Y chromosome in individuals who are candidates for assisted reproduction, as well as genetic counciling and follow-up.     

Role of Yq11-chromosome microdeletion in the development of nonobstructive infertility in men

Recent studies have shown that a significant proportion of men with severe infertility had microdeletions of the Y-chromosome. It has thus become important to screen men with a high risk of the Y-chromosome microdeletions, as this will determine if counseling is needed prior to starting infertility treatment. The current state of knowledge about the nature of genes responsible for spermatogenesis and significance of microdeletions of the Y-chromosome for male infertility are analyzed in the review.     

Specific expression of VCY2 in human male germ cells and its involvement in the pathogenesis of male infertility

Abnormal spermatogenesis in men with Y-chromosome microdeletions suggests that genes important for spermatogenesis have been removed from these individuals. VCY2 is a testis-specific gene that locates in the most frequently deleted azoospermia factor c region in the Y chromosome. We have raised an antiserum to VCY2 and used it to characterize the localization of VCY2 in human testis. Using Western blot analysis, the affinity-purified polyclonal VCY2 antibody gave a single specific band of approximately 14 kDa in size, corresponding to the expected size of VCY2 in all the collected human testicular biopsy specimens with normal spermatogenesis. Immunohistochemical analyses showed that VCY2 localized to the nuclei of spermatogonia, spermatocytes, and round spermatids, except elongated spermatids. At the ultrastructural level, VCY2 expression was found in the nucleus of human ejaculated spermatozoa. To determine the possible relationship of VCY2 with the pathogenesis of male infertility, we examined a group of infertile men with and without Y-chromosome microdeletions and with known testicular pathology using VCY2 antibody. VCY2 was weakly expressed at the spermatogonia and immunonegative in spermatocytes and round spermatids in testicular biopsy specimens with maturation arrest or hypospermatogenesis. The specific localization of the protein in germ cell nuclei indicates that VCY2 is likely to function in male germ cell development. The impaired expression of VCY2 in infertile men suggests its involvement in the pathogenesis of male infertility.     

Existe-il, dans la population générale masculine un risque plus fort de développer des délétions du chromosome Y qui entraîneraient une infertilité?

The role of the Y-chromosome in spermatogenesis remains one of the hottest topics in andrology. Three non overlapping recurrently deleted regions on Yq (AZFa, AZFb, AZFc) have been defined, each of them containing several genes that are candidates for male infertility. The causes and mechanisms leading to microdeletion formation on the Y are largely unknown. Theoretically, it could be possible that some groups of Y-chromosomes (haplogroups) currently distributed in the population could confer a selective advantage/disadvantage towards deletion formation. A precedent in the field is the recent identification of a Y-chromosome haplotype that confers a selective advantage against a translocation of Yp leading to another form of male infertility, the Y+XX-male phenotype. In order to test if selection is acting on Y-chromosome haplotype distribution, we have defined and compared Y-chromosome haplotypes in a group of around 60 individuals with Y microdeletions from North-Western Europe using 10 biallelic Y-markers (SRY-2627, SRY-1532, SRY-8299, 92R7, Tat, YAP, sY81, LLY22g, M9, DYS257). The defined heplotypes were compared to a control normospermic population of the same ethnic/geographic origin (in the framework of the European Biodiversity Project). We evaluatte the relationship between different Y-chromosome backgrounds and microdeletions, and to which extent selection on this chromosome could have influenced fifness of certain individuals/populations. We also discuss the selective forces that are acting on this chromosome and speculate on the mechanisms underlying deletion formation.