Molecular diagnosis of Turner''s syndrome.

Turner's syndrome is a common disorder which occurs in around 1/3000 live births in girls. Diagnostic use of polymorphic DNA markers for the X chromosome could help to reduce the number of time consuming karyotype analyses needed. The M27 beta probe maps on the X chromosome to Xcen-Xp11-22 and in 83% of female subjects detects heterozygosity with multiallelic polymorphism. In Southern blotting, a single X chromosome yields a single hybridisation band. In this study, genomic DNA was extracted from leucocytes of 49 patients with Turner's syndrome (karyotypes: 45,XO, n = 29; 45,XO/46,XX, n = 4; 46,Xi(Xq), n = 1; 45,XO/46,Xi(Xq), n = 4; 45,XO/46,Xr(X), n = 4; 45,XO/46,XY, n = 4; 46,XXp-, n = 3), digested with EcoRI or HindIII, and analysed by Southern blotting. The molecular data for each patient were compared with DNA controls (homozygous 46,XX, heterozygous 46,XX and 46,XY DNA). A single band of reduced intensity compared to homozygous 46,XX control DNA was seen in 41 cases. Two hybridisation bands of different intensities were seen in four patients, in one of whom mosaicism was suspected on the basis of molecular analysis, despite a 45,XO karyotype. In four cases, Turner's syndrome failed to be detected: one 45,XO/46,XX mosaicism with only 4% of 45,XO cells and three distal Xp deletions. DNA analysis appears to be a useful and rapid tool in screening for Turner's syndrome and could be an alternative to cytogenetic analysis in diagnosing the disorder when severe growth retardation or delayed puberty are not accompanied by a Turner phenotype.     

51例Turner综合征患者染色体核型分析及临床特征

目的探讨Turner综合征不同核型的遗传学特征、临床特点及其所占比例。方法无菌取患者外周血,淋巴细胞常规培养制作染色体标本,胰酶法G显带,显微镜下进行染色体核型分析。结果 51例Turner综合征患者的染色体核型为:45,XO 19例(37.56%),45,XO/46,XX 9例(17.65%),46,Xi(Xq)8例(15.69%),45,XO/46,Xi(Xq)5例(9.8%),47,XXX 3例(5.88%),45,XO/46,X+mar 2例(3.92%),45,XO/46,XY 2例(3.92%),45,XO/45,i(Xq)2例(3.92%),46,X,del(X)(qter→q11:)1例(1.96%)。结论 Turner综合征患者的染色体有数目异常和结构畸变等多种核型,均可不同程度导致女性闭经、性腺发育异常及智力低下等症状,应提倡优生优育,做好产前诊断。     

Phenotypic and genotypic variability in monozygotic triplets with Turner syndrome

Turner syndrome (TS) is a common disorder (1/2500 and 1/5000 female births) which is diagnosed at birth in approximately 20% of patients and during childhood (usually due to growth retardation) or later, (due to lack of pubertal development) for the remaining patients. Here we present a cytogenetic and molecular analysis of three monozygotic sisters. The diagnosis of TS was done for one of them (patient 1) who presented with a typical Turner phenotype. A first karyotype was established as normal and a second karyotype (carried out on 200 cells) revealed a 45,X/46,XX mosaicism with 6% of cells with a 45,X karyotype. Lymphocyte karyotype analysis showed the same mosaicism pattern for the two other sisters, one of them exhibiting only a mild (patient 2) and the other no clinical features of Turner syndrome (patient 3). Karyotype analysis was this time conducted on fibroblasts and showed that the 45,X/46,XX mosaicism pattern correlated with the clinical phenotype with 99, 43 and 3% of 45,X cells in patients 1, 2, and 3, respectively.
These data suggest that different tissues other than lymphocytes should be subjected to a karyotype analysis when the observed genotype does not correlate with the clinical phenotype.     

Detection of Y-specific sequences in 122 patients with Turner syndrome: nested PCR is not a reliable method

The incidence of Y chromosome sequences in patients with Turner syndrome has been evaluated in several studies, and its frequency varied from 0% to 61%, depending on the molecular methodology used. The aim of our study was to screen for Y chromosome sequences in 122 patients with Turner syndrome without cytogenetic evidence of this chromosome. DNA of 100 normal women was also screened and it was used as a negative control. To identify cryptic Y mosaicism, eight regions of Y chromosome were amplified by PCR. In order to increase the sensitivity of Y sequence detection, a nested PCR of the SRY and TSPY genes was also performed. All patients had several stigmata of Turner syndrome and none of them presented with signs of virilization. The most frequent karyotype was 45,X (54.1%), followed by mosaicism involving structural aberration of the X chromosome. There were 12 patients who carried a marker or ring chromosome. First-round PCR identified Y chromosome sequences in only four patients (3%), and all of them had a chromosome mosaicism with at least one cell lineage with a marker chromosome. After nested PCR, 25% of the patients and 14% of the normal women were positive for the presence of Y sequences. Contamination with extraneous genomic DNA was ruled out by microsatellite studies, but we cannot eliminate the possibility of contamination with PCR products, despite careful handling. We conclude that nested PCR overestimated the frequency of Y sequences in patients with Turner syndrome and should be avoided to prevent false positive results, which lead to unnecessary surgical treatment of these patients.     

Detection of Y‐specific sequences in 122 patients with Turner syndrome: Nested PCR is not a reliable method

The incidence of Y chromosome sequences in patients with Turner syndrome has been evaluated in several studies, and its frequency varied from 0% to 61%, depending on the molecular methodology used. The aim of our study was to screen for Y chromosome sequences in 122 patients with Turner syndrome without cytogenetic evidence of this chromosome. DNA of 100 normal women was also screened and it was used as a negative control. To identify cryptic Y mosaicism, eight regions of Y chromosome were amplified by PCR. In order to increase the sensitivity of Y sequence detection, a nested PCR of the SRY and TSPY genes was also performed. All patients had several stigmata of Turner syndrome and none of them presented with signs of virilization. The most frequent karyotype was 45,X (54.1%), followed by mosaicism involving structural aberration of the X chromosome. There were 12 patients who carried a marker or ring chromosome. First‐round PCR identified Y chromosome sequences in only four patients (3%), and all of them had a chromosome mosaicism with at least one cell lineage with a marker chromosome. After nested PCR, 25% of the patients and 14% of the normal women were positive for the presence of Y sequences. Contamination with extraneous genomic DNA was ruled out by microsatellite studies, but we cannot eliminate the possibility of contamination with PCR products, despite careful handling. We conclude that nested PCR overestimated the frequency of Y sequences in patients with Turner syndrome and should be avoided to prevent false positive results, which lead to unnecessary surgical treatment of these patients. © 2001 Wiley‐Liss, Inc.     

High frequency of tissue-specific mosaicism in Turner syndrome patients

Interphase fluorescent studies of X chromosome aneuploidy in cultured and uncultured blood lymphocytes and oral mucosa epithelial cells using X centromere-specific DNA probe in addition to standard karyotype analysis were performed in 50 females with a clinical suspicion of Turner syndrome. All the patients were previously screened for the presence of 'hidden' Y chromosome mosaicism, using the primers DYZ3 and DYZ. The use of fluorescence in situ hybridization (FISH) analysis of interphase nuclei of tissues from different germ layers (lymphocytes from mesoderm and buccal epithelial cells from ectoderm) improves the accuracy of detection of low-level mosaicism. FISH studies on interphase nuclei revealed that 29% of patients with a pure form of monosomy X detected by metaphase analysis are, in fact, mosaics. The level of cells with the normal chromosomal constitution in lymphocytes of these cases as a rule was low, ranging from 3 to 18%, with an average of 7%. Two false-positive cases and one false-negative case of X monosomy mosaicism determined by standard cytogenetic approach were detected using FISH analysis. The majority of patients (92%) with mosaic form of Turner syndrome have considerable tissue-specific differences in levels of X aneuploidy. Our data indicate that in cases when mosaic aneuploidy with low-level frequency is questionable (approximately 10% and lower), the results of standard metaphase analysis should be supplemented with additional FISH studies of interphase nuclei. Tissue-specific differences in contents of different cell lines in the same patients point to the necessity of studying more than one tissue from each patient.     

大连地区78例Turner综合征的临床特征与染色体核型分析

目的探讨Turner综合征（TS）不同核型的遗传学特征、临床特点及其所占比例。方法成人外周血染色体核型分析,高危孕妇羊水染色体核型分析。结果成人外周血检测发现TS 75例,羊水检测发现TS 3例。78例患者中,45,XO 32例（41%）,45,XO/46,XX嵌合型10例（12.8%）,45,XO/46,XX/47,XXX嵌合型2例（2.6%）,45,XO/47,XXX嵌合型4例（5.1%）,46,X,i（X）4例（5.1%）,45,XO/46,X,i（X）嵌合型9例（11.5%）,46,X,del（Xp-）7例（9.0%）,46,X,del（Xq-）7例（9.0%）,45,XO/46,X,del（Xp11）嵌合型2例（2.6%）,45,XO/46,X,del（Xq21）嵌合型1例（1.3%）。结论 TS核型主要包括X单体型,X单体嵌合型和结构畸变型及其嵌合型三种,45,XO的X单体型为本综合症的主要类型;不同核型患者临床表现可存在差异;对有相关临床表现的女孩争取做到早诊断,早治疗;对部分具有一定生育能力的TS患者做好产前诊断,做到优生优育。     

Turner syndrome: evaluation of prenatal diagnosis in 19 European registries

This study evaluated the prenatal diagnosis of Turner syndrome by ultrasound examination in an unselected population from all over Europe. Data from 19 congenital malformation registries from 11 European countries were analyzed. Turner syndrome was diagnosed in 125 cases (7.2%) in a total of 1,738 chromosome abnormalities. Sixty-seven percent of cases were detected prenatally by ultrasound examination due to the presence of congenital defects. The most frequent anomalies were cystic hygroma (59.5%) and hydrops fetalis (19%). The most frequent karyotype was 45,X (81.6%) followed by different types of mosaicism (16.8%). Significant differences in congenital defects (P = 0.0003) were observed between 45,X karyotypes and 45,X mosaicism cases. Prenatal counseling for 45,X mosaicism should take into account the expectation of a milder phenotype. In 78.6% of cases diagnosed by ultrasound examination due to congenital anomalies, the pregnancy was terminated. Prenatal detection of Turner syndrome by ultrasound examination was high in this unselected population.     

Familial Turner syndrome

A 28-year-old Turner female with secondary amenorrhea is described, who showed 45,X/46,X,del(Xp) mosaicism in her blood lymphocytes and a 46,X,del(Xp) karyotype only in her ovaries. 45,X/46,XX mosaicism was found in the patient's mother, who presented short stature, mild Turner dysmorphism and had a normal reproductive life-span. Phenotypic implications of the cytogenetic findings in the patients are discussed, and literature data on fertility in Turner syndrome are briefly reviewed.     

Familial Turner syndrome with an X;Y translocation mosaicism: Implications for genetic counseling

Spontaneous fertility is rare among patients with Turner syndrome and is most likely in women with mosaicism for a normal 46,XX cell line. We report an unusual case of familial Turner syndrome with mosaicism for a novel X;Y translocation involving Xp and Yp. The chromosomal analysis was carried out through cytogenetics and molecular karyotyping using a SNP array platform. The mother, a Turner syndrome woman, diagnosed in midchildhood because of short stature, was found to have a 45,X/46,X,der(X)t(X;Y)(p11.4;p11.2) karyotype, with a predominant 45,X cell line. Her parents decided against prophylactic gonadectomy, generally recommended at an early age when Y chromosome has been identified, because at age 13, she had spontaneous puberty and menarche. She reached a final height of 154 cm after treatment with growth hormone. At age 24, she became spontaneously pregnant. She had a mild aortic coarctation and close follow-up cardiac evaluation, including cardiac magnetic resonance imaging, had been performed during her pregnancy, which progressed uneventfully, except for intra-uterine growth retardation. Prenatal diagnosis revealed a female karyotype, with transmission of the maternal translocation with an unexpected different mosaic:47,X,der(X)t(X;Y)x2/46,X,der(X)t(X;Y) karyotype. This complex and unusual karyotype, including a mosaic partial trisomy X and a non-mosaic Xpter-Xp11.4 monosomy, results in transmission of Turner syndrome from mother to daughter. At birth, the girl had normal physical examination except for growth retardation. This family illustrates the complexity and difficulties, in term of patient counseling and management in Turner syndrome, in determining ovarian status, fertility planning, risks associated with pregnancies, particularly when mosaicism for Y material chromosome is identified.     

Cryopreservation of ovarian tissue and in vitro matured oocytes in a female with mosaic Turner syndrome: Case Report

We report a novel approach of fertility preservation in a young woman with mosaic Turner syndrome. A 16-year-old female with 20% 45XO and 80% 46XX karyotype underwent laparoscopic ovarian wedge resection. Before performing ovarian tissue cryopreservation, all visible follicles on the ovarian surface were aspirated. We recovered 11 immature germinal vesicle stage oocytes, which were subjected to in vitro maturation (IVM). Eight oocytes that matured (73% maturation rate) were cryopreserved by vitrification. The combination of ovarian tissue cryobanking and immature oocyte collection from the tissue followed by IVM and vitrification of matured oocytes represent a promising approach of fertility preservation for young women with mosaic Turner syndrome.     

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.     

Microsatellite analysis in Turner syndrome: parental origin of X chromosomes and possible mechanism of formation of abnormal chromosomes.

Turner syndrome is a chromosomal disorder in which all or part of one X chromosome is missing. The meiotic or mitotic origin of most cases remains unknown due to the difficulty in detecting hidden mosaicism and to the lack of meiotic segregation studies. We analyzed 15 Turner patients, 10 with a 45,X whereas the rest had a second cell line with abnormal X-chromosomes: a pseudodicentric, an isochromosome, one large and one small ring, and the last with a long arm deletion. Our aims were: to detect X cryptic mosaicism in patients with a 45,X constitution; to determine the parental origin of the abnormality; to infer the zygotic origin of the karyotype and to suggest the timing and mechanism of the error(s) leading to the formation of abnormal X chromosomes from maternal origin. Molecular investigation did not revealed heterozygosity for any microsatellite, excluding X mosaicism in the 45,X cases. Parental origin of the single X chromosome was maternal in 90% of these patients. Three of the structurally abnormal Xs were maternally derived whereas the other two were paternal. These results allowed us to corroborate breakpoints in these abnormal X chromosomes and suggest that the pseudodicentric chromosome originated from post-zygotic sister chromatid exchange, whereas the Xq deleted chromosome probably arose after a recombination event during maternal meiosis.     

Turner综合征自发性青春发育分析

目的探讨先天性卵巢发育不全综合征（Turnersyndrome,TS）患儿自发的青春发育与染色体核型及性激素水平之间的关系。方法30例Turner综合征患儿进行染色体检查,评估第二性征及性腺发育情况,检测性激素水平。结果染色体核型分4组,第1组45,XO,10例;第2组嵌合型,9例;第3组x染色体结构畸变,10例;第4组伴有Y染色体,1例。30例患儿随访至15周岁,其中10例出现不同程度的自发性青春发育,20例呈无性发育,4组患儿中以嵌合型TS出现自发青春发育几率最大。有青春发育患儿的性激素水平与无性发育患儿的性激素水平有显著差异。结论Turner综合征患儿自发性青春发育与染色体核型及性激素水平有密切相关性。     

Microsatellite analysis in Turner syndrome: Parental origin of X chromosomes and possible mechanism of formation of abnormal chromosomes

Turner syndrome is a chromosomal disorder in which all or part of one X chromosome is missing. The meiotic or mitotic origin of most cases remains unknown due to the difficulty in detecting hidden mosaicism and to the lack of meiotic segregation studies. We analyzed 15 Turner patients, 10 with a 45,X whereas the rest had a second cell line with abnormal X‐chromosomes: a pseudodicentric, an isochromosome, one large and one small ring, and the last with a long arm deletion. Our aims were: to detect X cryptic mosaicism in patients with a 45,X constitution; to determine the parental origin of the abnormality; to infer the zygotic origin of the karyotype and to suggest the timing and mechanism of the error(s) leading to the formation of abnormal X chromosomes from maternal origin. Molecular investigation did not revealed heterozygosity for any microsatellite, excluding X mosaicism in the 45,X cases. Parental origin of the single X chromosome was maternal in 90% of these patients. Three of the structurally abnormal Xs were maternally derived whereas the other two were paternal. These results allowed us to corroborate breakpoints in these abnormal X chromosomes and suggest that the pseudodicentric chromosome originated from post‐zygotic sister chromatid exchange, whereas the Xq deleted chromosome probably arose after a recombination event during maternal meiosis. © 2001 Wiley‐Liss, Inc.     

Turner syndrome: a cytogenetic and molecular study

Two hundred and eleven patients with a clinical diagnosis of Turner syndrome were studied. We report (i) the cytogenetic results, (ii) the frequency of cryptic mosaicism and (iii) the parental age and the parental origin of the abnormality. We scored 100 cells from blood cultures and found 97 patients to have a 45,X constitution, 15 to be 45,X/46,XX or 45,X/47,XXX mosaics, 86 to have a structurally abnormal X and 13 to have a structurally abnormal Y chromosome. Molecular methods were used to look for cryptic X and Y chromosome mosaicism in patients with a 45,X constitution. Two cryptic X but no cryptic Y mosaics were detected. In 74% of the 45,X patients the X was maternal in origin. The i(Xq)s were approximately equally likely to involve the paternal or maternal chromosome, while the majority of deletions and rings and virtually all the abnormal Y chromosomes were paternal in origin. We suggest that the preponderance of paternal errors in Turner syndrome may result from the absence of pairing along the greater part of the XY bivalent during paternal mei I, which may make the sex chromosomes particularly susceptible to both structural and non-disjunctional errors during male gametogenesis.     

A heterozygous mutation in RPGR associated with X‐linked retinitis pigmentosa in a patient with Turner syndrome mosaicism (45,X/46,XX)

Turner syndrome with retinitis pigmentosa (RP) is rare, with only three cases reported based on clinical examination alone. We summarized the 4‐year follow‐up and molecular findings in a 28‐year‐old patient with Turner syndrome and the typical features of short stature and neck webbing, who also had X‐linked RP. Her main complaints were night blindness and progressive loss of vision since the age of 9 years. Ophthalmologic examination, optical coherent tomographic imaging, and visual electrophysiology tests showed classic manifestations of RP. The karyotype of peripheral blood showed mosaicism (45,X [72%]/46,XX[28%]). A novel heterozygous frameshift mutation (c.2403_2406delAGAG, p.T801fsX812) in the RP GTPase regulator (RPGR) gene was detected using next generation sequencing and validated by Sanger sequencing. We believe that this is the first report of X‐linked RP in a patient with Turner syndrome associated with mosaicism, and an RPGR heterozygous mutation. We hypothesize that X‐linked RP in this woman is not related to Turner syndrome, but may be a manifestation of the lack of a normal paternal X chromosome with intact but mutated RPGR.     

Isodicentric Y chromosome in an Ullrich‐Turner patient without virilization

We report on a 17‐year‐old young woman with Ullrich‐Turner syndrome (UTS), who was found to have a karyotype 45,X/46,X,idic(Y)(q11). She had age‐appropriate genitalia without virilization in spite of the presence of the Y‐derived marker chromosome and SRY locus in 70% of her lymphocytes. Having reviewed the literature, we conclude that a possible explanation for the lack of virilization in these mosaic patients is most likely an uneven distribution of tissue mosaicism (gonadal mosaicism). Am. J. Med. Genet. 91:99–101, 2000. © 2000 Wiley‐Liss, Inc.     

45 XO/49 XYYYY Mosaicism in a male with stigmata of Turner''s syndrome

A male subject with Turner-like stigmata and chromosomic constitution 45,XO (97.5%) and 49,XYYYY (1.1%) is reported. The findings of a low percentage line bearing Y chromosome in a patient with clinical features similar to those described for XO males, would support the hypothesis that masculinization in certain individuals with 45,XO karyotype may be due to an undetected mosaicism.     

Detection of low level sex chromosome mosaicism in Ullrich-Turner syndrome patients

Ullrich-Turner syndrome (UTS) is most commonly due to a 45,X chromosome defect, but is also seen in patients with a variety of X-chromosome abnormalities or 45,X/46,XY mosaicism. The phenotype of UTS patients is highly variable, and depends largely on the karyotype. Patients are at an increased risk of gonadoblastoma when a Y-derived chromosome or chromosome fragment is present. Since constitutional mosaicism is present in approximately 50% of UTS patients, the identification of minor cell populations is clinically important and a challenge to laboratories. We identified 50 females with a 45,X karyotype as the sole abnormality or as part of a more complex karyotype. Twenty two (44%) had a 45,X karyotype; mosaicism for a second normal or structurally abnormal X was observed in 24 (48%) samples, and mosaicism for Y chromosomal material in 4 (8%) cases. To further investigate the possibility of mosaicism in the 22 patients with an apparently non-mosaic 45,X karyotype, we performed FISH using centromere probes for the X and Y chromosomes. A minor XX cell line was identified in 3 patients, and the 45,X result was confirmed in 19 samples. No samples with XY mosaicism were identified. We describe our validation process for a FISH assay to be used in clinical practice to identify XX or XY mosaicism. FISH as an adjunct to karyotype analysis provides a sensitive and cost-effective technique to identify sex chromosome mosaicism in UTS patients.