Cytogenetics and fluorescence in situ hybridization assessment of sex-chromosome mosaicism in Klinefelter's syndrome

A retrospective study was carried out in 152 infertile men to determine the prevalence of sex chromosome abnormalities among non-obstructive azoospermic and severe oligospermic men (n = 51) and to evaluate the feasibility of fluorescence in situ hybridization (FISH) techniques to assess mosaicism in Klinefelter's patients in comparison with conventional cytogenetics. Cytogenetic analysis were performed for 51 infertile men and among 14 chromosomal abnormalities found, nine were compatible with Klinefelter's syndrome. FISH staining with a CEP X/CEP Y probes were performed for Klinefelter's patients and for five of them; testes were biopsied for histopathologic examination. Six Klinefelter's patients showed a non-mosaic 47,XXY and three showed a 47,XXY/46,XY mosaic by G or R banding analysis of 20 cells with a ratio of 17%, 20% and 33%, respectively. FISH analysis confirmed mosaicism in only one patient (the first) in whom a third cells population was found. There was no relationship between the ratios of mosaicism by banding and FISH analysis. Conventional histopathologic findings in five non-mosaic Klinefelter's patients confirm the diagnosis of Sertoli Only Cells syndrome. FISH is recommended in Klinefelter's syndrome to define exactly the cytogenetic statute as mosaic or non-mosaic and then discussing prognosis and decision regarding fertility counseling.     

An azoospermic male with a Y/Autosome translocation

Summary This report describes an azoospermic male carrying a Y/autosome translocation. The patient had a 46,X,t(Y;10)(q12;p13) chromosome complement in a lymphocyte culture. The cytogenetic study of this patient is described, together with testicular histology, spermiogram, hormone levels, and clinical history.     

A dysmorphic newborn with 45,X,der(1)inv(1)(p13;qter)t(Y;1)(pter-->q11;p13),-Y de novo karyotype

A dysmorphic newborn with 45,x,der(1)inv(1)(p13;qter)t(y;1)(pter-->q11;p13),-Y de novo karyotype: Y/autosome translocations are very rare chromosomal rearrangements. In most cases, the long arm of the Y chromosome is translocated onto an autosome and most patients are referred because of male infertility. Y/1 translocations are very rare, and have been reported in seven patients so far. Pericentric inversions may be seen in all chromosomes and are not associated with phenotypic abnormalities. Here we report a 6-day old male baby with prenatal growth retardation, frontal bossing, hypertelorism, micrognathia, cleft soft palate, absent uvula, hypospadias, simian line in both hands and hammer toes. Cytogenetic analysis was performed with GTG-banding, C-banding and FISH analysis containing X centromeric probe, Yq12-qter locus specific probe and whole chromosome Y probe. An unbalanced Y/1 translocation was diagnosed: 45,X,der(1)inv(1)(p13;qter)t(Y;1)(pter-->q11;p13),-Y.     

Chromosomal Abnormality and Y Chromosome Microdeletion in Chinese Patients with Azoospermia or Severe Oligozoo-spermia

Chromosomal abnormality and Y chromosome microdeletion are regarded as two frequent genetic causes associated with spermatogenic failure in Caucasian population. To investigate the distribution of the two genetic defects in Chinese patients with azoospermia or severe oligozoospermia, karyotype analysis by G-banding was carried out in 358 idiopathic infertile men, including 256 patients with azoospermia and 102 patients with severe oligozoospermia, and screening of AZF region microdeletion of Y chromosome by multiplex PCR was performed in those patients without detectable chromosomal abnormality and 100 fertile controls. Of 358 patients, 39(10.9%) were found to have chromosomal abnormalities in which Klinefelters syndrome (47, XXY) was the most common chromosomal aberration. The incidence of sex chromosomal abnormality in patients with azoospermia was significantly higher than that in patients with severe oligozoospermia (12.1% vs 1%). Among the rest of the 319 patients with normal karyotype, 46 (14.4%) were found to have microdeletions in AZF region. The prevalence rates of AZF microdeletion was 15% and 13.1% in patients with azoospermia and severe oligozoospermia respectively. The microdeletion in AZFc was the most frequent deletion and all the microdeletions in AZFa were found in azoospermic patients. No microdeletion in AZF region was detected in fertile controls. In conclusion, chromosomal abnormality and AZF region microdeletion of Y chromosome might account for about 25% of Chinese infertile patients with azoospermia or severe oligozoospermia, suggesting the two abnormalities are important genetic etiology of spematogenic failure in Chinese population and it is essential to screen them during diagnosis of male infertility before in vitro assisted fertilization by introcytoplasmic sperm injection.     

中国无精症、严重寡精症患者的染色体异常和Y染色体微缺失

染色体异常和Y染色体微缺失被认为是两个白种人群中常见的生精障碍相关遗传因素。为了解中国无精症、严重寡精症患者中的染色体异常和Y染色体微缺失,运用染色体G显带技术,在358个原发无精症（256人）和严重寡精症（102人）不育患者中进行染色体核型分析;同时运用多重PCR技术,在核型正常的患者和100个正常生育男性中,对Y染色体AZF区微缺失进行筛查。在358个患者中,39人（10．9％）发现有染色体异常,Klinefelter（47,XYY）最为常见。无精症患者性染色体异常频率明显高于严重寡精症患者（12．1％VS1％）。在319个核型正常的患者中,46（14．4％）发现有AZF区微缺失,无精症和寡精症患者中Y染色体微缺失频率分别为15％和13．1％,AZFc区的微缺失最为常见,AZFa区的微缺失只见于无精症患者,正常生育男性中未发现AZF区的微缺失。结果显示,在中国无精症、严重寡精症患者中,大约25％的患者有染色体异常或Y染色体AZF区微缺失,提示这两种遗传异常是中国人群生精障碍的重要相关遗传病因,有必要在男性不育的诊断以及利用细胞浆内精子注射技术进行辅助生育时,对患者的这些遗传异常进行筛查。     

The case of an infertile male with an uncommon reciprocal X-autosomal translocation: how does this affect male fertility?

Infertility is defined as the inability to conceive after one year of regular unprotected intercourse. Constitutional numerical and/or structural chromosomal aberrations like sex-chromosome aberrations are one of the possible factors involved in fertility problems. Reciprocal translocations between an X-chromosome and an autosome are rarely seen in men. Male carriers of an X-autosome translocation are invariably sterile, regardless of the position of the breakpoint in the X-chromosome. Breakpoints in autosomal chromosomes could also be involved in male infertility. In this paper, we describe a 31-year-old male with azoospermia. GTG banding with high resolution multicolor-banding (MCB) techniques revealed a karyotype 46,Y,t(X;1)(p22.3;q25), and we discuss how the breakpoint of this translocation could affect male infertility. As a conclusion, cytogenetic evaluation of infertile subjects with azoospermia should be considered in the first place before in vitro fertilisation procedures are planned.     

Genetic diagnosis in infertile men with numerical and constitutional sperm abnormalities

Infertile men having numerical or structural sperm defects may carry several genetic abnormalities (karyotype abnormalities, Y chromosome microdeletions, cystic fibrosis transmembrane conductance regulator (CFTR) gene mutations, androgen receptor gene mutations, and abnormalities seen in sperm cells) leading to this situation. First we aimed to investigate the relationship between the numerical and constitutional (morphological) sperm anomalies and the genetic disorders that can be seen in infertile males. Our other aim was to compare two different kinds of kits that we use for the detection of Y chromosome microdeletions. Sixty-three infertile males [44 nonobstructive azoospermic, 8 severe oligozoospermic, and 11 oligoasthenoteratozoospermic] were investigated in terms of somatic chromosomal constitutions and microdeletions of the Y chromosome. Sperm aneuploidy levels were analyzed by fluorescence in situ hybridization (FISH) in sperm cells obtained from the semen of six OAT patients. Microdeletion and sex chromosome aneuploidy (47,XXY) rates in somatic cells were found to be approximately 3.2% and 4.7%, respectively. Sperm aneuploidy rates were determined as 9%, 22%, and 47% in three patients out of six. Two of these three patients also had high rates of head anomalies in semen samples. High correlation was found between sperm aneuploidy rates and sperm head anomalies. Since the introduction of the assisted reproductive techniques for the treatment of severe male infertility, genetic tests and genetic counseling became very important due to the transmission of genetic abnormalities to the next generation. Thus in a very near future, for a comprehensive male infertility panel, it will be essential to include additional genetic tests, such as CFTR gene mutations, sperm mitochondrial DNA mutations, and androgen receptor gene mutations, besides the conventional chromosomal analyses, Y chromosome microdeletion detection, and sperm-FISH analyses.     

Y染色体异常29例分析

本文从1992例遗传咨询病例中收集29例Y染色体异常的病例,其中Y染色体数 目异常(47,XYY)2例;Y染色体结构异常8例:Y/Y易位1例、Yp+3例、de l(Y)3例、嵌合 体dic(Y)1例;Y染色体长度变异19例。对Y染色体这几种异常类型的遗传效应进行分析。 Abstract:Twenty nine cases of Y chromosome abnormalities were found in 1992 patients asking genetic counseling.Different kinds of Y chromosome abnormalitics were detected by G and banding techniques.These were 47,XYY(2 cascs);46,X,del(Y)(3 cascs);46,X,Yp+(3 cases);46,X,t(Y;Y)(1 case);45,X/46,X,dic(Y)(1 case) and length changes of Y chromosome(19 cases).The genetic effects of Y chromosome abnormalities have been analyzed in this report.     

Human X-autosome translocations: differential inactivation of the X chromosome in a kindred with an X-9 translocation.

A kindred with an X-autosome translocation and differential inactivation of the X chromosome is described. The phenotypically normal mother has a reciprocal translocation [46,X,rcp(X;9) (q11;q32)] while the daughter's karyotype is unbalanced [46,X,--X,+der(9),rcp(X;9) (q11;q32)mat], indicating adjacent-two type of segregation in the mother. In the mother's cells the normal X is late replicating, while in the daughter's cells almost the entire der(9) is late replicating, indicating the presence of autosomal inactivation. The daughter's abnormal phenotype can be explained by her sex chromosomal complement and the absence of effective trisomy 9. At this stage there is no simple explanation to account for all types of inactivation patterns encountered in the 14 balanced and 15 unbalanced cases of X-autosome translocations reported to date. Selection of X inactivation is not an inherent characteristic of the X chromosome per se, and it is not dependent on the direction of chromosomal exchange, as was suggested previously. Correlation of the phenotypic and cytogenetic features of these patients suggests a pattern of X and autosomal inactivation consistent with the least amount of genotypic and phenotypic imbalance in most cases. The data are most consistent with random X inactivation followed by selection of the most viable cell line.     

Azoospermia and cryptorchidism in a male with a de novo reciprocal t(Y;16) translocation

An apparently balanced reciprocal translocation between the long arm of the Y chromosome and the long arm of the chromosome 16 t(Y;16)(q12;q13) is described in an infertile man with azoospermia and cryptorchidism. The patient was phenotypically normal and had bilateral inguinal hernia repair with orchidopexy at the age of 8 years. Histological examination of testicular biopsies revealed maturation arrest. Y/autosome translocations in the literature are relatively rare and mostly associated with infertility. To our knowledge, this is the sixth report about the reciprocal t(Y;16) translocation in the literature but the first presenting with cryptorchidism.     

Different chromosome Y abnormalities in Turner syndrome.

A 17-year-old phenotypically female girl was referred for evaluation because of short stature and primary amenorrhea. Cytogenetic analysis showed a mosaic 46,XY/45,X/47,XYY/46,X,idic(Yq)/47,XY,idic(Yq)/48,XXY,idic(Yq)/46,X,t(C;Y) karyotype. Conventional cytogenetic results were supplemented with fluorescence in situ hybridization (FISH) techniques to ensure a better characterization of abnormalities. By using FISH, a supernumerary marker chromosome derived from chromosome Y which could not be detected by conventional cytogenetics was revealed. Furthermore, additional abnormalities and their frequencies were highlighted by the application of DNA probes specific for X and Y chromosomes. Thus, FISH proved useful in determining low frequency cell lines which would need analysis of a large number of good quality metaphase spreads by conventional cytogenetic techniques: it helped in identifying the nature and the origin of unknown markers and rearrangements which have important implication in sexual differentiation and development of gonadal tumours.     

Patterns of replication in the neo-sex chromosomes ofDrosophila nasuta albomicans

Drosophila nasuta albomicans (with 2n = 6), contains a pair of metacentric neo-sex chromosomes. Phylogenetically these are products of centric fusion between ancestral sex (X, Y) chromosomes and an autosome (chromosome 3). The polytene chromosome complement of males with a neo-X- and neo-Y-chromosomes has revealed asynchrony in replication between the two arms of the neo-sex chromosomes. The arm which represents the ancestral X-chromosome is faster replicating than the arm which represents ancestral autosome. The latter arm of the neo-sex chromosome is synchronous with other autosomes of the complement. We conclude that one arm of the neo-X/Y is still mimicking the features of an autosome while the other arm has the features of a classical X/Y-chromosome. This X-autosome translocation differs from the other evolutionary X-autosome translocations known in certain species ofDrosophila.     

Meiotic studies of a 38,XY/39,XXY mosaic boar

Klinefelter's syndrome (KS) is the most common sex chromosome abnormality identified in human males. This syndrome is generally associated with infertility. Men with KS may have a 47,XXY or a 46,XY/47,XXY karyotype. Studies carried out in humans and mice suggest that only XY cells are able to enter and complete meiosis. These cells could originate from the XY cells present in mosaic patients or from XXY cells that have lost one X chromosome. In pig, only 3 cases of pure 39,XXY have been reported until now, and no meiotic analysis was carried out. For the first time in pig species we report the analysis of a 38,XY/39,XXY boar and describe the origin of the supplementary X chromosome and the chromosomal constitutions of the germ and Sertoli cells.     

Cytogenetic studies in a selected group of mentally retarded children

Summary Chromosomal abnormalities are an important cause of mental retardation. We studied the frequency of karyotype abnormalities in 74 mentally retarded patients selected from 306 patients referred to our clinic. Giemsa-banding was done on all cases. Additional studies in abnormal cases included autoradiography and X and Y chromatin. Karyotype analyses and blood group (Xg and Duffy) studies were carried out in family members in some cases.Fourteen of these children had chromosomal abnormalities, seven sex chromosomal, and seven had autosomal abnormalities. Three patients had 45,X and one had a 45,X/46,Xr(X) karyotype. Other sex chromosomal abnormalities were 46,XX/ 48,XXXX;48,XXXY/49,XXXXY; and 48,XXYY. Autosomal abnormalities were 46,XX,1q-;46,XY,2q-;46,XY,5p-;46,XY, dup(5p); 45,XX,t(13,14); and 46,XY,17p-. This is the first report from India of cytogenetic abnormalities in idiopathic mental retardation. The chromosomal studies in these patients help not only in accurate diagnosis, proper prognosis, and genetic counseling but also in gene localization and in the study of the origin of X-chromosome abnormalities.     

Chromosomal sensitivity to X-rays in lymphocytes from patients with Turner syndrome

Lymphocytes from patients with Turner syndrome were irradiated with X-rays (200 rad) to determine the chromosomal aberration frequency in first-division metaphases. Five patients with 45,X karyotype; three 45,X/46,Xi(X)q mosaics; one 45,X/47,XXX mosaic and 9 female controls were studied. Patients with a 45,X karyotype exhibited a radioinduced chromosomal aberration frequency similar to controls (38.6 +/- 6.37 and 36.2 +/- 5.11 respectively; p = 0.42). In the mosaics, 45,X cells had a mean frequency of 38.75 +/- 2.16; 46,Xi(X)q cells a mean of 38 +/- 2.16 and the control group a rate of 36.25 +/- 4.32. No differences were observed between 45,X and 46,Xi(X)q cells (p = 0.50), 45,X and normal cells (p = 0.24) or 46,Xi(X)q and normal cells (p = 0.35). Apparently neither the X monosomy nor the Xq isochromosome influences the 'in vitro' X-ray-induced chromosomal damage in Turner syndrome lymphocytes.     

A Turner patient with a 45,X,t(1;2) (q41;p11.2) karyotype

The most common chromosomal anomaly is 45,X in the Turner syndrome. In addition to this, anomaly, mosaicism such as structural 46,X,i(Xq), 46,X,del(Xp), 46,X,r(X), 46,X,t(X;Y) and numerical 46XO/46,XX/47XXX are seen rather frequently. An infant with the Turner syndrome was found to have a karyotype 45X,t(1;2) (q41;p16) using high resolution banding. Based on our knowledge, we present the first case of 45X,t(1;2) (q41;p11.2), a karyotype in Turner's syndrome in the literature.     

X-autosome translocation with a breakpoint in Xq22 in a fertile woman and her 47,XXX infertile daughter

Summary An unusual case is presented of a fertile woman heterozygous for a balanced X-autosome translocation t(X;12) (q22;p12) with a break-point (Xq22) in the critical region of the X chromosome. The karyotypes of her daughter, who is infertile, and one of her two sons are 47,XXX,t(X;12)(q22;p12) and 46,XY,t(X;12)(q22;p12) respectively. The literature on balanced X-autosome translocations in males and females involving both arms of the X chromosome is reviewed. All 23 of the 36 cases of females with balanced Xq-autosome translocation, that exhibited gonadal failure have a break-point between bands Xq13 and Xq26.     

Chromosome abnormalities in sperm of individuals with constitutional sex chromosomal abnormalities

The most common type of karyotype abnormality detected in infertile subjects is represented by Klinefelter's syndrome, and the most frequent non-chromosomal alteration is represented by Y chromosome long arm microdeletions. Here we report our experience and a review of the literature on sperm sex chromosome aneuploidies in these two conditions. Non mosaic 47,XXY Klinefelter patients (12 subjects) show a significantly lower percentage of normal Y-bearing sperm and slightly higher percentage of normal X-bearing sperm. Consistent with the hypothesis that 47,XXY germ cells may undergo and complete meiosis, aneuploidy rate for XX- and XY-disomies is also increased with respect to controls, whereas the percentage of YY-disomies is normal. Aneuploidy rates in men with mosaic 47,XXY/46,XY (11 subjects) are lower than those observed in men with non-mosaic Klinefelter's syndrome, and only the frequency of XY-disomic sperm is significantly higher with respect to controls. Although the great majority of children born by intracytoplasmic sperm injection from Klinefelter subjects are chromosomally normal, the risk of producing offspring with chromosome aneuploidies is significant. Men with Y chromosome microdeletions (14 subjects) showed a reduction of normal Y-bearing sperm, and an increase in nullisomic and XY-disomic sperm, suggesting an instability of the deleted Y chromosome causing its loss in germ cells, and meiotic alterations leading to XY non-disjunction. Intracytoplasmic injection of sperm from Y-deleted men will therefore transmit the deletion to male children, and therefore the spermatogenic impairment, but raises also concerns of generating 45,X and 47,XXY embryos.     

Syndrome de klinefelter et conseil génétique

Klinefelter’s syndrome is a common sex chromosomal aberration generally characterized by hypergonadotrophic hypogonadism and azoospermia. However, spermatogenesis impairment is variable and severe oligozoospermia can be found in some men, particularly those exhibiting a mosaic karyotype 47,XXY/ 46,XY. New reproductive technologies, such as intracytoplasmic sperm injection (ICSI), allow Klinefelter patients to have a progeny, even those who are azoospermic after testicular sperm recovery. The question therefore arises of whether or not there is a genetic risk for pregnancies from affected fathers. Sperm karyotyping, by in vitro penetration of zona-free hamster eggs or by fluorescence in-situ hybridization (FISH), is a method of choice for measuring aneuploidy rate in spermatozoa of patients carrying gonosomal abnormalities. A theoretical model would predict a high level of 24,XX and/or 24,XY disomic sperm cells in Klinefelter patients if 47,XXY spermatogonia were able to complete meiosis and achieve spermatogenesis. Interestingly, current observations show that the rate of abnormal spermatozoa in these patients is low, around 1–2%, which indicates that only 46,XY spermatogonia can produce mature sperm cells and that oligozoospermic Klinefelter patients probably carry a 47,XXY / 46,XY mosaicism, at least at the testicular level. However, this low but statistically significant level of disomic spermatozoa emphasizes the fact that their spermatogenesis occurs in a compromised environment which could increase the risk of meiotic errors. Therefore, the possible occurrence of autosomal aneuploidies in children born from Klinefelter fathers leads to the following recommendations: a) individual analysis by FISH of the sperm aneuploidy rate in each Klinefelter patient candidate for ICSI; b) proposal of fetal karyotyping after amniocentesis in pregnancies obtained by this technique.     

A dicentric iso (Y) chromosome in an infertile male

A dicentric Y chromosome was detected in a 30-year-old azoospermic male patient who was found to be mosaic for 45,X/46,X,dic Y(qter----p11::p11----qter). The dicentric iso (Y) chromosome was identified conclusively with C-banding, G-banding and Q-banding techniques. The relationship of structural abnormalities of the Y chromosome and azoospermia is discussed.