Lack of association between Y chromosome haplogroups and male infertility in Japanese men

The Y chromosome carries several genes involved in spermatogenesis, which are distributed in three regions in the euchromatic part of the long arm, called AZFa (azoospermia factor a), AZFb, and AZFc. Microdeletions in these regions have been seen in 10-15% of sterile males with azoospermia or severe oligozoospermia. The relatively high de novo occurrence of these microdeletion events might be due to particular chromosome arrangements associated with certain Y chromosome haplogroups. To test whether there is any association between Y chromosome types and male infertility, we studied a sample of 84 Japanese oligozoospermic or azoospermic males. The patients were analyzed for the presence of Yq microdeletions and also typed with a battery of unique event polymorphisms (UEPs) to define their Y haplogroups. Six of the infertile patients presented likely pathological microdeletions detectable with the sequence tagged sites (STS) markers used. There was no significant association between Y chromosome haplogroups and the microdeletions. We also compared the Y haplogroup frequencies in our subset sample of 51 idiopathic azoospermia patients with 57 fertile control Japanese males, and did not observe any significant differences. Contrary to previous reports, our data suggest that Y microdeletions and other molecular events causally associated with male infertility in Japan occur independently of the Y chromosome background.     

Polymorphic DAZ gene family in polymorphic structure of AZFc locus: Artwork or functional for human spermatogenesis?

Human spermatogenesis is regulated by a network of genes located on autosomes and on sex chromosomes, but especially on the Y chromosome. Most results concerning the germ cell function of the Y genes were obtained by genomic breakpoint mapping studies of the Y chromosome of infertile patients. Although this approach has the benefit of focussing on those Y regions that contain most likely the Y genes of functional importance, its major drawback is the fact that fertile control samples were often missing. In fertile men, molecular and cytogenetic analyses of the Y chromosome has revealed highly polymorphic chromatin domains especially in the distal euchromatic part (Yq11.23) and in the heterochromatic part (Yq12) of the long arm. In sterile patients cytogenetic analyses mapped microscopically visible Y deletions and rearrangements in the same polymorphic Y regions. The presence of a Y chromosomal spermatogenesis locus was postulated to be located in Yq11.23 and designated as AZoospermia Factor (ZF). More recently, molecular deletion mapping in Yq11 has revealed a series of microdeletions that could be mapped to one of three different AZF loci: AZFa in proximal Yq11 (Yq11.21), AZFb and AZFc in two non-overlapping Y-regions in distal Yq11 (Yq11.23). This view was supported by the observation that AZFa and AZFb microdeletions were associated with a specific pathology in the patients' testis tissue. Only AZFc deletions were associated with a variable testicular pathology and in rare cases AZFc deletions were even found inherited from father to son. However, AZFc deletions were found with a frequency of 10-20% only in infertile men and most of them were proved to be "de novo", i.e. the AZFc deletion was restricted to the patient's Y chromosome. Based mainly on positional cloning experiments of testis cDNA clones and on the Y chromosomal sequence now published in GenBank, a first blueprint for the putative gene content of the AZFc locus can now be given and the gene location compared to the polymorphic DNA domains. This artwork of repetitive sequence blocks called AZFc amplicons raised the question whether the AZFc chromatin is still part of the heterochromatic domain of the Y long arm well known for its polymorphic extensions or is decondensed and part of the Yq11.23 euchromatin? We discuss also the polymorphic DAZ gene family and disclose putative origins of its molecular heterogeneity in fertile and infertile men recently identified by the analyses of Single Nucleotide Variants (SNVs) in this AZFc gene locus.     

COMMENTS

Human spermatogenesis is regulated by a network of genes located on autosomes and on sex chromosomes, but especially on the Y chromosome. Most results concerning the germ cell function of the Y genes were obtained by genomic breakpoint mapping studies of the Y chromosome of infertile patients. Although this approach has the benefit of focussing on those Y regions that contain most likely the Y genes of functional importance, its major drawback is the fact that fertile control samples were often missing. In fertile men, molecular and cytogenetic analyses of the Y chromosome has revealed highly polymorphic chromatin domains especially in the distal euchromatic part (Yq11.23) and in the heterochromatic part (Yq12) of the long arm. In sterile patients cytogenetic analyses mapped microscopically visible Y deletions and rearrangements in the same polymorphic Y regions. The presence of a Y chromosomal spermatogenesis locus was postulated to be located in Yq11.23 and designated as AZoospermia Factor (ZF). More recently, molecular deletion mapping in Yq11 has revealed a series of microdeletions that could be mapped to one of three different AZF loci: AZFa in proximal Yq11 (Yq11.21), AZFb and AZFc in two non‐overlapping Y‐regions in distal Yq11 (Yq11.23). This view was supported by the observation that AZFa and AZFb microdeletions were associated with a specific pathology in the patients' testis tissue. Only AZFc deletions were associated with a variable testicular pathology and in rare cases AZFc deletions were even found inherited from father to son. However, AZFc deletions were found with a frequency of 10–20% only in infertile men and most of them were proved to be “de novo”, i.e. the AZFc deletion was restricted to the patient's Y chromosome. Based mainly on positional cloning experiments of testis cDNA clones and on the Y chromosomal sequence now published in GenBank, a first blueprint for the putative gene content of the AZFc locus can now be given and the gene location compared to the polymorphic DNA domains. This artwork of repetitive sequence blocks called AZFc amplicons raised the question whether the AZFc chromatin is still part of the heterochromatic domain of the Y long arm well known for its polymorphic extensions or is decondensed and part of the Yq11.23 euchromatin? We discuss also the polymorphic DAZ gene family and disclose putative origins of its molecular heterogeneity in fertile and infertile men recently identified by the analyses of Single Nucleotide Variants (SNVs) in this AZFc gene locus.     

25例无精症患者的分子细胞遗传学研究

目的 通过对无精症患者异常染色体及Y染色体(Yq11.2区段)无精症因子(azoospermic factor,AZF)微缺失的分析,探讨无精症与染色体异常的关系.方法 对25例原因不明的无精症患者进行G带染色体核型分析、荧光Q-显带、荧光原位杂交(fluorescence in situ hybridization,FISH)和AZF微缺失PCR检测.结果 25例原因不明的无精症患者中染色体核型异常7例,异常发生率为28%;对8例无精症患者进行AZF微缺失检测:AZF区微缺失2例,分别为AZFb(SYl27,SYl34)+AZFe(SY254,SY255)缺失、AZFe(SY243,sYl58)缺失.结论 染色体异常及Y染色体AZF微缺失是引起无精症并造成男性不育的重要原因之一,对无精症等不育男性患者在排除睾丸病变、阻塞性无精症、内分泌及免疫系统等临床病理学因素后,包括配偶有不明原因习惯性流产的男性均需做外周血染色体常规GTG-显带、荧光Q-显带检查.Q-带阴性的患者说明其Y染色体长臂缺失的断裂点高于Yq12,在Yq11.2区段,则需要结合FISH和AZF微缺失的PCR检测,以确诊Y染色体的微缺失区段,为患者的临床进一步治疗提供可靠的依据.     

Prevalence of chromosomal abnormalities in 2078 infertile couples referred for assisted reproductive techniques

BACKGROUND: This study analyses the prevalence of karyotype changes and Yq11 microdeletions among couples referred for assisted reproduction techniques. METHODS: Prior to receiving either IVF or ICSI treatment, each partner of 2078 infertile couples was screened for karyotype changes by GTG-banding technique on peripheral lymphocytes. No subject presented with obvious phenotype of chromosomal rearrangement. All the oligo/azoospermic men with normal karyotype were further investigated by PCR for Yq11 microdeletions. RESULTS: Eighty-two out of 2078 couples (3.95%) had one partner carrying a chromosomal change, and 10 out of 202 (4.95%) men showed Yq11 microdeletions. The chromosomal rearrangements were 44 (2.1%) translocations, 23 (1.1%) gonosomal mosaics, six (0.3%) 47,XXY, five (0.24%) marker chromosomes, three (0.14%) inversions and one (0.05%) duplication. Frequency of anomalies in men and women were similar: 42 and 40 cases respectively. CONCLUSIONS: Partners of infertile couples requiring IVF or ICSI treatment appear to be affected by higher frequency of chromosomal rearrangements than the general population. Categories with greater risk were represented by men with sperm cell count <20 x 10(6) sperm/ml, and women with history of pregnancy loss.     

Y chromosome microdeletions in Tunisian infertile males

AIM: To determine frequency of Y microdeletions in azoospermic and oligospermic Tunisian infertile males. METHODS: A Sample of 146 Tunisian infertile males with a low sperm count (<5 x 10(6) sperms per mililiter) and normal karyotype was screened for Y chromosome microdeletions. 76 men were azoospermic and 70 men were oligospermic. Genomic DNA was isolated from blood and multiplex PCR was carried out with a set of 20 AZFa, AZFb and AZFc STS markers to detect the microdeletions as recommended by the European Academy of Andrology. RESULTS: In 10/146 (6.85%) subjects AZF deletions were observed. Of these ten males with microdeletions, 9/10 subjects were azoospermic (90%), 1/10 was oligospermic (10%). Frequency of microdeletions in azoospermic men was 9/76 (11.84%). None of the patients showed isolated microdeletion in the AZFa region, but one azoospermic man had deletion in the AZFb region. Eight azoospermic patients and one oligospremic man have AZFc microdeletions. AZFc and AZFb were deleted in three azoospermic patients. AZFc, AZFb and AZFa were deleted in three azoospermic patients We estimate the sensitivity of the test comprising six STS in our sample to be 90%. CONCLUSION: The incidence of Yq microdeletions in the study population of infertile Tunisian men falls within the range published in other countries. We suggest to analyze 9STS in the first step to detect efficiently Y microdeletions in our population.     

424例非梗阻性无精子症和严重少精子症患者的细胞与分子遗传学研究

目的探讨非梗阻性无精子症和严重少精子症患者的细胞与分子遗传学特点。方法应用染色体核型分析、Y染色体微缺失检测和荧光原位杂交（FISH）、PCR等技术对非梗阻性无精子症（n=291）和严重少精子症患者（n=133）男性不育患者（共424例）进行细胞和分子遗传学检测。结果424例患者中有98例明确为遗传异常引起的,其中66例检测到染色体畸变,44例Y染色体微缺失检测见缺失,12例患者染色体核型和微缺失检测均见异常。部分AZF缺失患者精液或睾丸中有精子,但其生精功能呈进行性下降的特点。结论男性不育最常见的遗传学病因为K linefelter综合征和Y染色体AZFc缺失。Y染色体微缺失检测对Y染色体长臂异染色质区缺失是否为多态性具有明确诊断的作用。细胞与分子遗传学检测为男性不育的诊断、治疗和预后以及ICSI治疗前遗传咨询提供重要依据。     

Y chromosome microdeletions, in azoospermic or near-azoospermic subjects, are located in the AZFc (DAZ) subregion

Submicroscopic deletions of the Y chromosome and polymorphisms of the androgen receptor (AR) gene in the X chromosome have been observed in men with defective spermatogenesis. To further define the subregions/genes in the Y chromosome causing male infertility and its relationship to polymorphisms of the AR polyglutamine tract, we screened the genomic DNA of 202 subfertile males and 101 healthy fertile controls of predominantly Chinese ethnic origin. Y microdeletions were examined with 16 sequence-tagged site (STS) probes, including the RBM and DAZ genes, spanning the AZFb and AZFc subregions of Yq11, and related to the size of trinucleotide repeat encoding the AR polyglutamine tract. Y microdeletions were detected and confirmed in three out of 44 (6.8%) of azoospermic and three out of 86 (3.5%) severely oligozoospermic patients. No deletions were detected in any of the patients with sperm counts of >0.5 x 10(6)/ml, nor in any of the 101 fertile controls. All six affected patients had almost contiguous Y microdeletions spanning the entire AZFc region including the DAZ gene. The AZFb region, containing the RBM1 gene, was intact in five of the six subjects. Y deletions were not found in those with long AR polyglutamine tracts. Our study, the first in a Chinese population, suggest a cause and effect relationship between Y microdeletions in the AZFc region (possibly DAZ), and azoospermia or near-azoospermia. Y microdeletions and long AR polyglutamine tracts appear to be independent contributors to male infertility.      

Human male infertility and Y chromosome deletions: role of the AZF-candidate genes DAZ, RBM and DFFRY.

Microdeletions in Yq11 overlapping three distinct 'azoospermia factors' (AZFa-c) represent the aetiological factor of 10-15% of idiopathic azoospermia and severe oligozoospermia, with higher prevalence in more severe testiculopathies, such as Sertoli cell-only syndrome. Using a PCR-based screening, we analysed Yq microdeletions in 180 infertile patients affected by idiopathic Sertoli cell-only syndrome and different degrees of hypospermatogenesis, compared with 50 patients with known causes of testicular alteration, 30 with obstructive azoospermia, and 100 normal fertile men. In idiopathic severe testiculopathies (Sertoli cell-only syndrome and severe hypospermatogenesis), a high prevalence of microdeletions (34.5% and 24.7% respectively) was found, while milder forms were not associated with Yq alteration. No deletions were found in testiculopathies of known aetiology, obstructive azoospermia, normal fertile men and male relatives of patients with deletions. Deletions in the AZFc region involving the DAZ gene were the most frequent finding and they were more often observed in severe hypospermatogenesis than in Sertoli cell-only syndrome, suggesting that deletions of this region are not sufficient to cause complete loss of the spermatogenic line. Deletions in AZFb involving the RBM gene were less frequently detected and there was no correlation with testicular phenotype, with an apparent minor role for such gene in spermatogenesis. The DFFRY gene was absent in a fraction of patients, making it a candidate AZFa gene. Our data suggest that larger deletions involving more than one AZF-candidate gene are associated with a more severe testicular phenotype.     

No AZF deletion in 160 patients with testicular germ cell neoplasia

Testicular germ cell cancer is aetiologically linked to genital malformations and male infertility and is most probably caused by a disruption of embryonic programming and gonadal development during fetal life. In some cases, germ cell neoplasia is associated with a relative reduction of Y chromosomal material (e.g. 45,X/46,XY) or other abnormalities of the Y chromosome. The euchromatic long arm of the human Y chromosome (Yq11) contains three azoospermia factors (AZFa, AZFb, AZFc) functionally important in human spermatogenesis. Microdeletions encompassing one of these three AZF loci result in the deletion of multiple genes normally expressed in testis tissue and are associated with spermatogenic failure. The aim of our study was to investigate whether AZF microdeletions, in addition to causing infertility, predispose also to germ cell neoplasia, since subjects with poor spermatogenesis have an increased risk of testicular cancer. We screened for putative deletions of AZF loci on the Y chromosome in DNA isolated from white blood cells of 160 Danish patients with testicular germ cell neoplasia. Interestingly, although AZF microdeletions are found frequently in patients with idiopathic infertility, in all cases studied of testicular germ cell cancer the Yq region was found to be intact. We conclude that the molecular aetiology of testicular germ cell neoplasia of the young adult type most likely does not involve the same pathways as male infertility caused by AZF deletions. Malignant transformation of germ cells is thus caused by the dysfunction of some other genes that still need to be identified.     

165例男性不育染色体核型及AZF基因缺失分析

目的探讨男性不育患者染色体核型异常及无精症因子（AZF）基因缺失与男性不育的关系。方法对2012年5月-2014年5月来本院就诊的（重庆地区）原发性男性不育患者165例,进行外周血G显带核型分析并采用多重PCR对无精症因子区域的15个标签序列位点进行检测。结果165例生精障碍患者中染色体异常共检出5例,1例为男性性反转（46,XX）,1例为克氏综合征（47,XXY）,1例为47,XY,＋mar,1例为46,XY,Y≥18,1例46,XY,in（9）,其余均为正常核型,总异常率为3.03％（5／165）;AZF基因位点发生微缺失患者共检出25例,总缺失率为15.15S。结论染色体异常和AZF微缺失是男性不育的重要原因,对男性不育诊断时有必要进行检查。     

High frequency of well-defined Y-chromosome deletions in idiopathic Sertoli cell-only syndrome

Idiopathic Sertoli cell-only syndrome (SCOS) is characterized by azoospermia, small testes, absence of germ cells in the testes, elevated follicle stimulating hormone and normal testosterone concentrations. The Y-chromosome is involved in the regulation of spermatogenesis and in the pathogenesis of a fraction of idiopathic male infertility. An azoospermia factor (AZF) is present on the Y- chromosome long arm euchromatic region (Yq11) and two gene families (DAZ and RBM) have been identified within this region. The aim of this study was to investigate whether a specific pattern of Yq11 microdeletions may be associated with idiopathic SCOS. Eighteen idiopathic subjects showing a testicular cytological picture of bilateral SCOS were selected and tested by polymerase chain reaction for a set of 29 Y-specific sequence-tagged sites (STS). We found Yq microdeletions in 10 out of 18 patients (55.5%) while the fathers or brothers of six out of 10 patients deleted for Yq were shown to carry an intact Y-chromosome. These deletions may therefore be considered as de-novo deletions and the cause of SCOS. The analysis of the microdeletions allowed us to identify two homogeneous regions that have a high incidence of deletion. The smallest deletion, common to all patients, is located in Yq interval 5. We therefore speculate that there is a relationship between specific, well-characterized Yq11 microdeletions and a testicular picture of SCOS, identifying an Y- related region frequently deleted in this syndrome. In conclusion, the findings of this study demonstrate that a large percentage of idiopathic SCOS may be genetically determined and identify an Y-related region that seems to possess one or more still unknown genes essential for spermatogenesis.      

Transmission of Y chromosomal microdeletions from father to son through intracytoplasmic sperm injection

 We conducted chromosomal analysis of three male infants fathered by severe oligozoospermic males with Y chromosomal microdeletions through intracytoplasmic sperm injection (ICSI). Two of the infants had the same Y chromosomal microdeletions as their fathers. The third infant also had a Y chromosomal microdeletion, which was longer than that found in his father. The results confirm that Y chromosomal microdeletions are transmitted from a father to a son via ICSI and also suggest that the microdeletions may be expanded during such transmission. Genetic counseling for infertile couples contemplating ICSI is important if the male carries Y chromosomal microdeletions. Received: January 11, 2002 / Accepted: May 19, 2002     

618例不育男性的AZF基因微缺失分析

目的研究Y染色体AZF基因微缺失与男性不育的关系。方法应用多重PCR对618例男性不育患者进行Y染色体AZF基因的15个位点进行检测。结果一共检出Y染色体微缺失患者23例,占受检人群的3．72％,其中包括16例AZFc全部缺失、3例为AZFb＋c部分／全部缺失、3例为AZFa部分缺失和1例AZFa、AZFb、AZFc和AZFd四个区15个检测位点全部缺失。AZFc全部缺失患者中,中度至重度少精症13例,无精症3例;AZFb部分／全部缺失患者中,严重少弱精1例,无精症2例;AZFa部分缺失患者和15个位点全部缺失患者均为无精症。结论Y染色体AZF基因微缺失是男性不育的重要原因之一,该检测可为患者的诊断、治疗及遗传咨询提供依据。     

Prognostic value of Y deletion analysis: How reliable is the outcome of Y deletion analysis in providing a sound prognosis?

Y chromosomal microdeletions at the azoospermia factor (AZF) locus have been implicated as one of the major causes of idiopathic male infertility. The availability of intracytoplasmic sperm injection (ICSI) in treating a variety of male infertility has raised the risk of the transmission of Y microdeletions from father to son. In many IVF centres, Y microdeletion analysis has been used as a diagnostic tool for genetic counselling of infertile couples. Presently, the only prognosis that can be derived from Y microdeletion analysis is that the affected male offspring would benefit from proper clinical management of their infertility. Prognoses based on the pattern of Y microdeletions in relation to phenotype are rather subjective and inconclusive because of insufficient data to derive a definitive correlation whose significance can be determined by statistical analysis. Standardization of the number and choice of sequence-tagged sites (STS), whose deletions result in defective spermatogenesis, for the polymerase chain reaction (PCR) analysis of Y microdeletions would enhance its reliability in the interpretation of the results which is crucial for therapeutic decision-making. Furthermore, in-depth understanding of the gene functions in male infertility, especially at the AZF locus, would contribute greatly to the quality of the prognostic value of Y microdeletion analysis.     

Genetic risk factors in infertile men with severe oligozoospermia and azoospermia.

BACKGROUND: Male infertility due to severe oligozoospermia and azoospermia has been associated with a number of genetic risk factors. METHODS: In this study 150 men from couples requesting ICSI were investigated for genetic abnormalities, such as constitutive chromosome abnormalities, microdeletions of the Y chromosome (AZF region) and mutations in the cystic fibrosis transmembrane conductance regulator (CFTR) gene. RESULTS: Genetic analysis identified 16/150 (10.6%) abnormal karyotypes, 8/150 (5.3%) AZFc deletions and 14/150 (9.3%) CFTR gene mutations. An abnormal karyotype was found both in men with oligozoospermia and azoospermia: 9 men had a sex-chromosomal aneuploidy, 6 translocations were identified and one marker chromosome was found. Y chromosomal microdeletions were mainly associated with male infertility, due to testicular insufficiency. All deletions identified comprised the AZFc region, containing the Deleted in Azoospermia (DAZ) gene. CFTR gene mutations were commonly seen in men with congenital absence of the vas deferens, but also in 16% of men with azoospermia without any apparent abnormality of the vas deferens. CONCLUSIONS: A genetic abnormality was identified in 36/150 (24%) men with extreme oligozoospermia and azoospermia. Application of ICSI in these couples can result in offspring with an enhanced risk of unbalanced chromosome complement, male infertility due to the transmission of a Y-chromosomal microdeletion, and cystic fibrosis if both partners are CFTR gene mutation carriers. Genetic testing and counselling is clearly indicated for these couples before ICSI is considered.     

The choice and outcome of the fertility treatment of 38 couples in whom the male partner has a Yq microdeletion

BACKGROUND: Patients with Yq microdeletions may suffer from fertility problems. The purpose of this study was to assess the outcome of the fertility treatment of these patients. METHODS: For 38 patients with Yq microdeletions, data were collected about medical history, karyotype, testicular histopathology and the presence of spermatozoa in the ejaculate or testicular biopsies. RESULTS: Sixteen patients with an azoospermia factor region c (AZFc) deletion had at least one cycle with ICSI. The clinical pregnancy outcome was 22% per embryo transfer. Three babies have been born and two pregnancies are ongoing. Sex selection for female embryos in combination with ICSI in order to prevent the transmission of the fertility problems was discussed with 14 couples; eight were in favour of the selection. In addition, eight couples made the decision to use donor sperm because ICSI was impossible or objectionable and, in this group of patients, a total of nine babies were born. CONCLUSIONS: Despite the improvement of assisted reproductive technology, ICSI could be offered only to patients with an AZFc deletion. Insemination with donor sperm is a potential alternative for other patients.     

Genotyping of Israeli infertile men with idiopathic oligozoospermia

Microdeletions of the long arm of the Y chromosome involving the azoospermia factor (AZF) region are associated with severe oligo- or azoospermia. Abnormal androgen receptor (AR) structure or function has also been implicated in male infertility. To assess the contribution of these genetic defects to male infertility, 61 Israeli men with severe oligo- (n = 15) or azoospermia (n = 46), were screened for Y chromosome microdeletions, and the AR-(CAG)n repeat length. Fifty fertile Israeli men were similarly analyzed. PCR amplification of 20-54 simple tag sequences (STSs) located at Yq was used to determine the rate and extent of Y chromosome microdeletions. PCR with primers flanking the AR-(CAG)n region and subsequent size fractionation on gradient acrylamide gels were used to determine AR-(CAG)n length. Five azoospermic individuals (5/61-8.2% and 5/46-10.8% of azoospermic patients) displayed Y chromosome microdeletions. The mean CAG repeat number in infertile men was 18.6 +/- 3.0 compared with 16.6 + 2.7 in fertile men (n = 50), a statistically significant difference (p = 0.003). Y chromosome microdeletions contribute to male infertility in our azoospermic population, and the mean length of the AR-CAG is significantly longer in our infertile population than in fertile men.     

Combined cytogenetic and Y chromosome microdeletion screening in males undergoing intracytoplasmic sperm injection

We evaluated the frequency of chromosomal aberrations and microdeletions of the Y chromosome in a sample of 204 patients included in an intracytoplasmic sperm injection (ICSI) programme. The prevalence of Y chromosome deletions in males with severely or only moderately reduced sparm counts is mainly unknown, so that patients were chosen with sperm counts ranging from mild oligozoospermia to azoospermia. While six out of 158 (3.8%) patients showed constitutional chromosomal aberrations, only two out of 204 (0.98%) patients were diagnosed with a microdeletion of Yq11. One had a terminal deletion in subinterval 6 of Yq11.23 which included the DAZ gene and a corresponding sperm count < 0.1 x 10(6) spermatozoa/ml. The second patient had an isolated deletion of marker Y6PH54c, a more proximal site in subinterval 5 on Yq11.23, but repeatedly showed sperm counts of 3-8 x 10(8) spermatozoa/ml. Thus, of the 158 patients who underwent a combined cytogenetic and Y- microdeletion screening, eight patients (5.1%) showed chromosomal abnormalities, either at the cytogenatic (n = 6) or the molecular level (n = 2). In conclusion, although rare in number, microdeletions of the Y chromosome can also be observed in patients with moderately reduced sperm counts. A more proximal site of the deletion breakpoint does not necessarily imply a more severe impairment of spermatogenesis than a distal deletion site. In our sample, the overall frequency of constitutional chromosomal aberrations exceeded the incidence of microdeletions of the Y chromosome even in patients with idiopathic azoo- or severe oligozoospermia.      

男性不育患者Y染色体AZF基因微缺失检测

目的探讨原发性无精子症、严重少精子症及少精子症患者与Y染色体无精子因子（azoospermia factor,AZF）区微缺失的关系。方法采用多重PCR方法对对照组192例已正常生育男性和实验组448例男性不育患者进行AZF区域内的15个序列标签位点（STS）的检测。结果对照组未发现AZF基因微缺失,实验组448例患者检测出五种AZF微缺失类型共41例,总缺失率为9.2%（41/448）,其中无精子症、严重少精子症和少精子症患者的缺失率分别为12.0%（19/158）、10.8%（17/157）、3.8%（5/133）,无精子症和严重少精子症患者Y染色体AZF微缺失率明显高于少精子症组,差别有统计学意义（P〈0.05）。使用15个STS位点进行检测其检出率较利用欧洲男科学会（European Academy of Andrology,EAA）推荐的6个STS位点提高约14%（5/36）。结论AZF微缺失是引起原发性无精子症、严重少精子症和少精子症的重要原因之一;增加STS位点检测数有利于提高AZF微缺失的检出率。