A patient with a dicentric Y chromosome

A patient with some features of Turner's syndrome, but without evidence of masculinization, is reported. Cytogenetic studies showed 45, X/46, X, dic (Y) (q 1:2) mosaicism. The additional cell lines present, 46, X, del (dic Y); 47, X, dic Y, dic Y; 47, X, dic Y, del (dic Y) and 47, X,del (dic Y), del (dic Y, are attributed to instability of the dicentric Y chromosome.     

Mitotic and meiotic instability of a telomere association involving the Y chromosome

Constitutional telomere associations and jumping translocations (JTs) are rare events and usually occur post-zygotically. We report a telomere association involving the Y chromosome which "jumped" during meiosis. A 21-year-old woman was referred for amniocentesis due to non-immune hydrops seen in a previous pregnancy. Cytogenetic analysis of the amniocytes showed a 45,X,tas(Y;15)[4]/45,X[16] karyotype with the long arm of the Y chromosome attached to the end of the short arm of chromosome 15. Parental chromosome analyzes revealed a tas(Y;19)[63]/45,X[7] karyotype in the father with Yq attached to the end of the short arm of chromosome 19. A phenotypically normal male was born and blood chromosome analysis confirmed a 45,X,tas(Y;15)[39]/45,X[10]/46,XY[1] karyotype. Two other male children have 46,XY karyotypes, which further demonstrates the instability of the tas(Y;19) in meiosis. Fluorescence in situ hybridization (FISH) analysis with probes for theY-centromere, the Yqh region, the shared Xq/Yq telomere and SRY showed hybridization on the tas(Y;19) and tas(Y;15). A chromosome 19p specific subtelomeric probe showed hybridization to the tas(Y;19) in the father. In addition, a probe for the simple telomeric sequences TTAGGG showed positive hybridization to the junction of the associations. The presence of TTAGGG telomere repeats and unique telomere sequences indicate that the Y;15 and Y;19 associations occur with no detectable loss of any sequences. The interstitial telomere sequences at the junction of the telomere association may explain the mitotic and meiotic instability of the association.     

两例Turner综合征患者微小额外标记染色体来源鉴定

目的 为指导遗传咨询和临床治疗,对两例特纳综合征患者微小额外标记染色体(small supernumerary marker chromosome,sSMC)来源进行鉴定.方法 高分辨染色体G显带和C显带核型分析;PCR扩增SRY基因;中期染色体荧光原位杂交.结果 两例患者核型分析结果分别为45,X[29]/46,X,+mar[31]和45,X[71]/46,X,+mar[29].病例1 SRY基因检测阳性,其sSMC来源于Y染色体,通过荧光原位杂交最终确定其核型为45,X[29]/46,X,idic(Y)(q10)[31].ish idic(Y)(q10)(RP11-115 H13 ×2)(SRY+).病例2 sSMC来源于X染色体,核型最终确定为45,X[713/46,X,r(X)(p11.23q21)[29]ish r(X)(p11.23q21)(AL591394.11+,AC 092268.3-).结论 联合应用多种遗传学检测技术,准确鉴定了两例特纳综合征患者微小额外标记染色体的来源,以正确指导临床诊断和治疗.     

Monozygotic twins of discordant sex both with 45,X/46,X,idic(Y) mosaicism.

A female twin with short stature, unusual facial appearance, widely spaced nipples, and coarctation of the aorta was found to have a peripheral blood lymphocyte karyotype of 45,X(43%)/46,X,idic(Y)(p11). Her twin brother, also short with similar facial appearance, had the same mosaicism (40% 45,X). Cultured skin fibroblast studies showed discrepant karyotypes of 45,X (100%) in the girl and 45,X (78%)/46,X,idic(Y)(p11) in the boy. The mother and the father had normal chromosomes. Comparison of 27 biochemical markers yielded a likelihood of monozygosity of 0.9977. This report documents the occurrence of discordant phenotypic sex in monozygotic twins, involving gonadal dysgenesis with an abnormal dicentric Y, which presumably occurred de novo, followed by anaphase lag probably before the occurrence of twinning. Unequal distribution of the two resultant cell lines in various tissues of each twin could account for the development of the very different phenotypes, apparently normal boy and Ullrich-Turner girl.     

True hermaphroditism with ambiguous genitalia due to a complicated mosaic karyotype: clinical features,cytogenetic findings,and literature review

Abnormal recombination between the X and Y chromosomes during meiosis, occurring outside the pseudoautosomal region, can result in translocation of the SRY gene from the Y to the X chromosome, and consequently in abnormal sexual differentiation, such as the development of 46,XX males or true hermaphroditism. In this report we present clinical, cytogenetic, and molecular-cytogenetic data of a patient with ambiguous genitalia and true hermaphroditism, who had a unique mosaic karyotype, comprising three different cell lines: 46,XX(SRY+), 45,X(SRY+), and 45,X. The mosaic karyotype of our patient probably represents two different events: abnormal recombination between the X and Y chromosomes during paternal meiosis, and postzygotic loss of one of the X chromosomes. Replication studies demonstrated that in 80% of the XX cells, the SRY sequence was located on the active X chromosome. This finding suggests nonrandom X inactivation and, together with the presence of the SRY gene, explains the male phenotype of our patient. On the other hand, the presence of the 45,X cell line may have contributed to genital ambiguity. We conclude that fluorescence in situ hybridization (FISH) analysis with SRY probes is highly recommended and allows accurate diagnosis and optimal management in cases of 46,XX hermaphroditism and ambiguous genitalia.     

Telomeric fusion and chromosome instability in multiple tissues of a patient with mosaic Ullrich-Turner syndrome

We describe the cytogenetic evolution of multiple cell lines in the gonadal tissue of a 10-year-old girl with mosaic Ullrich-Turner syndrome (UTS) involving clonal telomeric associations (tas) of the Y chromosome. G-band analysis of all tissues showed at least 2 cell lines; 45, X and 46,X,tas(Y;21)(q12;p13). However, analysis of left gonadal tissue of this patient showed the evolution of 2 additional cell lines, one designated 45,X,tas(Y;21)(q12;p13),−22 and the other 46,X,tas(Y;21)(q12;p13),+tas(Y;14)(q12;p13),−22. Fluorescence in situ hybridization (FISH) analysis of interphase nuclei from uncultured gonadal tissue confirmed the findings of aneuploidy in the left gonadal tissue and extended the findings of aneuploidy to the tissue of the right gonad. The chromosome findings in the gonadal tissue of this patient suggest a preneoplastic karyotype relating to several distinct tumor associations. The clonal evolution of telomeric fusions indicates chromosome instability and suggests the extra copy of the Y chromosome may have resulted from a fusion-related malsegregation. In addition, the extra Y suggests low-level amplification of a putative gonadoblastoma gene, while the loss of chromosome 22 suggests the loss of heterozygosity for genes on chromosome 22. This case demonstrates the utility of the study of gonadal tissue in 45,X/46,XY UTS patients, and provides evidence that clonal telomeric fusions may, in rare cases, be associated with chromosomal malsegregation and with the subsequent evolution of unstable karyotypes. Am. J. Med. Genet. 69:383–387, 1997. © 1997 Wiley-Liss, Inc.     

Gonadoblastoma and Y-chromosome fluorescence

In this report we summarize our experience in 4 patients with 45,X/46,XY, one patient with 45,X/47,XYY mosaicism, and one patient with 46,XY karyotype and ambiguous external genitalia. In the 3 patients with a fluorescent Y-chromosome, the development of one or two gonadoblastomas was found, independent of the age of the patients at the time of examination. In the 3 patients with 45,X/46,XYnf mosaicism no gonadoblastoma was detected. This finding prompted us to review the data on patients reported with 45,X/46,XYnf mosaicism. Up to now, no patient with well documented 45,X/46,XYnf mosaicism and convincing evidence of development of gonadoblastoma has been reported. These data seem to confirm that alterations of the characteristic distal fluorescence of Yq may protect the dysgenetic gonad against tumoral degeneration in patients with 45,X/46,XY mosaicism. Possible mechanisms responsible for these changes in the oncogenic potential of Yq in relation with the Y chromosome fluorescence are discussed.     

Acro-renal polytopic defect

A female twin with short stature, unusual facial appearance, widely spaced nipples, and coarctation of the aorta was found to have a peripheral blood lymphocyte karyotype of 45, X(43%)/46, X, idic(Y)(p11). Her twin brother, also short with similar facial appearance, had the same mosaicism (40% 45, X). Cultured skin fibroblast studies showed discrepant karyotypes of 45, X (100%) in the girl and 45, X (78%)/46, X, idic(Y)(p11) in the boy. The mother and the father had normal chromosomes. Comparison of 27 biochemical markers yielded a likelihood of monozygosity of 0.9977. This report documents the occurrence of discordant phenotypic sex in monozygotic twins, involving gonadal dysgenesis with an abnormal dicentric Y, which presumably occurred de novo, followed by anaphase lag probably before the occurrence of twinning. Unequal distribution of the two resultant cell lines in various tissues of each twin could account for the development of the very different phenotypes, apparently normal boy and Ullrich-Turner girl.     

Sex chromosome mosaicism in males carrying Y chromosome long arm deletions

Microdeletions of the long arm of the Y chromosome (Yq) are a common cause of male infertility. Since large structural rearrangements of the Y chromosome are commonly associated with a 45,XO/46,XY chromosomal mosaicism, we studied whether submicroscopic Yq deletions could also be associated with the development of 45,XO cell lines. We studied blood samples from 14 infertile men carrying a Yq microdeletion as revealed by polymerase chain reaction (PCR). Patients were divided into two groups: group 1 (n = 6), in which karyotype analysis demonstrated a 45,X/46,XY mosaicism, and group 2 (n = 8) with apparently a normal 46,XY karyotype. 45,XO cells were identified by fluorescence in-situ hybridization (FISH) using X and Y centromeric probes. Lymphocytes from 11 fertile men were studied as controls. In addition, sperm cells were studied in three oligozoospermic patients in group 2. Our results showed that large and submicroscopic Yq deletions were associated with significantly increased percentages of 45,XO cells in lymphocytes and of sperm cells nullisomic for gonosomes, especially for the Y chromosome. Moreover, two isodicentric Y chromosomes, classified as normal by cytogenetic methods, were detected. Therefore, Yq microdeletions may be associated with Y chromosomal instability leading to the formation of 45,XO cell lines.     

Characterization by fluorescence and electron microscopy in situ hybridization of a double Y isochromosome

A patient with mixed gonadal dysgenesis and Y isochromosomes i(Y) is described. Lymphocyte cultures from peripheral blood contained a high proportion of 45,X cells and several other cell lines with two different marker chromosomes (mars). These markers had either a monocentric (mar1) or a dicentric appearance (mar2). Following high-resolution GTG, RBG, QFQ, and CBG bandings, five cell lines were identified; 45,X/46,X, + mar1/46,X, + mar2/47,X, + mar1x2/47,X, + mar2x2. The percentages were 66/6/26/1/1%, respectively. Chromosome banding analyses were insufficient for characterization of the markers. In situ hybridization of specific probes for the Y centromere and its short arm showed, both in fluorescence and electron microscopy (EM), two different Y rearrangements. Mar1 is an isochromosome for the short arm i(Yp) and mar2 is a dicentric which was shown by EM to be a double isochromosome Yp, inv dup i(Yp). The breakpoint producing mar1 is within the centromere and the one producing mar2 is within one of the short arms of the Y isochromosome. The findings of different cell populations in peripheral blood lymphocytes indicate the postzygotic instability of this i(Yp). © 1995 Wiley-Liss, Inc.     

Genetic analysis for 2 females carrying idic(Y)(p) and with sex development disorders北大核心CSCD

Objective: To investigate the phenotype-genotype association of isodicentromere Y chromosome by analysis of two female patients carrying the chromosome with sexual development disorders. Methods: The karyotypes of the two patients were determined by application of conventional G banding of peripheral blood samples and fluorescence in situ hybridization (FISH). PCR was applied to detect the presence of SRY gene. Results: Conventional karyotype analysis showed case 1 to be a mosaic: mos. 45,X[38]/46,X,+mar[151]/47,XY,+mar[5]/47,X,+marX2[2]/46,XY[4], FISH showed that 12 different cell lines were presented in the karyotype of case 1 and partial cell lines with SRY gene, the marker is an isodicentromere Y chromosome[idic(Y)(p)]. No mutation was found in the SRY gene. The karyotype of case 2 was mos. 45,X[25]/46,X,+mar[35]. FISH showed the marker to be an idic(Y)(p) without the SRY gene. Conclusion: The karyotype of patients carrying idic(Y)(p) seems unstable, and female patients have the characteristics of short stature and secondary sexual hypoplasia. Karyotype analysis combined with FISH analysis can accurately determine the breakpoint of idic(Y) and identify the types of complex mosaic, which may facilitate genetic counseling and prognosis. © 2016, West China University of Medical Sciences. All rights reserved.     

An investigation of ring and dicentric chromosomes found in three Turner''s syndrome patients using DNA analysis and in situ hybridisation with X and Y chromosome specific probes.

We have studied three patients with features of Turner''s syndrome, two with a 45,X/46,X,r(?) and the third with a 45,X/46,X,dic?(Y) karyotype. Because Turner''s syndrome patients with a mosaic karyotype containing a Y chromosome are known to have a high risk of developing gonadal tumours, we used DNA analysis and in situ hybridisation with X and Y specific probes to identify the chromosomal origin of the rings and dicentric chromosomes in the three index patients. Both ring chromosomes were shown to be of X origin, while the dicentric was composed of Y chromosome material. We discuss the importance of using a combination of molecular and cytogenetic analyses in such cases.     

DNA analysis of a patient with two different marker chromosomes using Y-specific DNA probes

A female patient with unilateral gonadal dysgenesis was a mosaic for three cell lines, 45,X/46,X, + marI/46,X, + marII, including two different marker chromosomes. DNA analysis using 17 Y-specific DNA probes revealed that each marker consists of different segments of the Y chromosome.     

Cytogenetic and molecular findings in patients with Turner''s syndrome stigmata.

Cytogenetic and DNA analysis in 12 people with stigmata of Turner's syndrome was carried out. Cytogenetic analysis of these patients showed two subjects with 46,X, i(Xq) karyotypes, one with 45,X/46,X, i(Xq), one with 46,X,t(X;Y), and eight with 45,X/46,X,mar. Molecular analysis of DNA samples was performed in nine out of 12 patients with marker chromosomes. PCR analysis with oligoprimers specific for SRY, DYZ1, or DYZ3 loci identified Y chromosome material in five patients in the latter group. The X chromosome origin of the marker chromosome was proved by FISH technique with biotin labelled pericentromeric X chromosome specific probe in four other patients. These results show that patients with a number of Turner's syndrome stigmata usually do not have a typical XO karyotype but have some structural chromosomal aberrations involving the X or Y chromosomes. Combined application of cytogenetic, molecular cytogenetic (FISH), and PCR techniques significantly improves the precision of marker chromosome identification and thus might be of practical importance for the proper management and treatment of affected patients. Peculiarities of pathological manifestations of different karyotypes bearing structural abnormalities of the X or Y chromosomes in patients with Turner's syndrome stigmata, as well as feasible genetic mechanisms of sex determination and differentiation abnormalities in these subjects, are briefly discussed.     

Evidence of a mechanism for isodicentric chromosome Y formation in a 45,X/46,X,idic(Y)(p11.31)/46,X,del(Y)(p11.31) mosaic karyotype

Abnormalities involving sex chromosomes account for approximately 0.5% of live births. The phenotypes of individuals with mosaic cell lines having structural aberrations of the X and Y chromosomes are variable and hard to accurately predict. Phenotypes associated with sex chromosome mosaicism range from Turner syndrome to males with infertility, and often present with ambiguous genitalia. Previous studies of individuals with an 45,X/46,X,idic(Y)(p11) karyotype suggest that the presence of both cell lines should result from an intermediate, 46,XY cell line. Here we report a 2.5 year old female with phenotypic features of Turner syndrome with an isodicentric Y chromosome and a cell line with a deleted Y with a final karyotype of 45,X/46,X,idic(Y)(p11.31)/46,X,del(Y)(p11.31). Fluorescence in situ hybridization (FISH) mapping of the Y chromosome breakpoint revealed very low percentages of the deleted Y cells, but suggested a potential mechanism for the formation of the isodicentric Y chromosome. To our knowledge, the 46,X,del(Y) intermediate cell line in our patient has not been previously reported in individuals with mosaic sex chromosome structural abnormalities.     

Mosaic Turner syndrome: cytogenetics versus FISH

Twenty-two cases with Turner syndrome features were subjected to standard cytogenetic techniques using giemsa trypsin (GTG-) banding then fluorescence in situ hybridization (FISH) using a specific whole-X chromosome painting probe, Quint-Essential Y-specific DNA probe (AMELY) for Yp11.2, alpha-satellite (DYZ3) probe and X/Y cocktail-alpha satellite probe (ONCOR) for confirmation of the initial diagnosis and comparison of the two techniques. Eight cases (36%) showed the same karyotype results by both techniques [5 cases: 45,X/46,XX, 2 cases: 45,X/46,X,i(Xq) and one case with a triple cell line 45,X/46,XX/47,XXX]. In the other 14 cases (64%) the FISH technique has identified a third cell line in 7 cases (32%), delineated the origin of the marker in 5 cases (23%) to be derivative X and clarified the deletion of the Yp11.2 region in 2 cases (9%) with the 45,X/46,XY karyotype. The application of FISH has highlighted the differences between the initial diagnosis based on the standard cytogenetic technique and the final diagnosis determined by the application of DNA probes specific for the X and Y chromosomes. FISH proved useful in detection of the low frequency cell lines which need analysis of a large number of metaphase spreads by GTG-banding, helped in identifying the nature and the origin of the unknown markers which has an important implication in the development of gonadal tumours and delineated the deletion of the Yp11.2 region in the 45,X/46,XY Turner patients.     

FISH characterization of a dicentric Yq (p11.32) isochromosome in an azoospermic male

The most common structural rearrangements of the Y chromosome result in the production of dicentrics. In this work, we analyze an abnormal Y chromosome, detected as a mosaic in an azoospermic male ascertained for infertility. FISH with seven different DNA probes specific for Y chromosome sequences (Y alpha-satellite, Y alpha-satellite III, non-alpha-satellite centromeric Y, SRY gene, subtelomeric Yp, subtelomeric Yq, and PNA-tel) and CGH analysis were performed. FISH results showed that the abnormal Y chromosome was a dicentric Yq isochromosome and that the breakpoint was distally in band Yp11.32. Lymphocyte chromosomes showed a mosaicism with 46,X,idicY(qter-->p11.32::p11.32-->qter) (51.7%), 46,XY (45.6%), and other cell lines (2.7%). In oral interphase cells, the mosaicism was 46,XidicY (62.8%), 46,XY (25.7%), 45,X (6.6%), and others (4.9%). The possible origin of this dicentric Yq isochromosome is discussed. Finally, we compare differences in mosaicism and phenotype among three reported cases with the breakpoint at Yp11.32 Copyright 2004 Wiley-Liss, Inc.     

Intrachromosomal insertion translocation resulting in duplication of chromosome band Yq11.2 in two fertile brothers

Chromosome analysis in a couple referred because of two spontaneous abortions showed a normal 46,XX karyotype in the 28-year-old female and an aberrant Y chromosome with an enlarged short arm in the 30-year-old male. Subsequent chromosome analysis showed that his 33-year-old brother was carrier of the same Y chromosome aberration. Further characterization of the aberrant Y chromosome with FISH using probes specific for chromosome bands Yp11.32, Yq11.2, the centromere and the subtelomeric region of the p-arm of the Y chromosome showed that chromosome band Yq11.2 was duplicated and inserted in the p-arm of the Y chromosome. Combining the results of the analysis of GTG-banded chromosomes and of the FISH analysis we conclude that both patients have a 46,X,ins dup(Y)(pter --> p11.23::q12 --> q11.1::p11.23 -->) karyotype. The clinical and cytogenetical findings are reported and discussed.     

Seminoma in a postmenopausal woman with a Y;15 translocation in peripheral blood lymphocytes and a t(Y;15)/45,X Turner mosaic pattern in skin fibroblasts.

We report an unusual case of a 55 year old Japanese woman with a seminoma but relatively normal menses. The patient was a phenotypic female with late onset menarche (18 years of age), who was amenorrhoeic for the first year, followed by menses of one to three days' slight flow with dysmenorrhoea, but an otherwise normal menstrual history. A typical seminoma was removed from the left adnexal region and an immature testis was identified separately as an associated right adnexal mass. Repeated karyotypic studies on peripheral blood lymphocyte cultures showed only 46,X,-Y,t(Y;15)(q12;p13). Cytogenetic examination of the patient's younger brother, who had fathered three healthy children, showed an identical karyotype. Mosaicism of 46,X,-Y,t(Y;15)(q12;p13)/45,X cell lines was found in skin samples from the patient's elbow and genital regions, although there were no clinical stigmata of Turner syndrome. An androgen receptor binding assay of cultured genital skin fibroblasts was negative. Molecular analysis using Southern blot hybridisation, PCR, and direct DNA sequencing showed that neither the patient nor her brother had a detectable deletion or other abnormalities of Y chromosome sequences, including the SRY (sex determining region of the Y chromosome) gene sequence. These findings suggest that Turner mosaicism of the 45,X cell line may have contributed to this atypical presentation in an XY female, although we cannot exclude abnormalities of other genes related to sex differentiation.     

Determination of the sexual phenotype in a child with 45,X/46,X,Idic(Yp) mosaicism: importance of the relative proportion of the 45,X line in gonadal tissue

We report on a girl who, despite her 45,X/46,X,der(Y) karyotype, showed no signs of virilization or physical signs of the Ullrich-Turner syndrome (UTS), except for a reduced growth rate. After prophylactic gonadectomy due to the risk of developing gonadoblastoma, the gonads and peripheral blood samples were analyzed by fluorescence in situ hybridization (FISH) and polymerase chain reaction (PCR) to detect Y-specific sequences. These analyses allowed us to characterize the Y-derived chromosome as being an isodicentric Yp chromosome (idic(Yp)) and showed a pronounced difference in the distribution of the 45,X/46,X,idic(Yp) mosaicism between the two analyzed tissues. It was shown that, although in peripheral blood almost all cells (97.5%) belonged to the idic(Yp) line with a duplicated SRY gene, this did not determine any degree of male sexual differentiation in the patient, as in the gonads the predominant cell line was 45,X (60%).