定量荧光PCR技术产前检测21三体嵌合体二例

目的报道采用多重定量荧光PCR（QF-PCR）方法在产前诊断中检测到2例21-三体嵌合体。方法采用QF-PCR方法检测21号染色体的数目同时采用传统的核型分型方法检测产前羊水标本,并将二者结果进行对比。结果 QF-PCR方法可以明显看出21三体嵌合体2例,核型分析这2个标本结果为：47,XX,＋21[5]/46,XX,[45];47,XX,＋21[34]/46,XX,[66]。结论 QF-PCR方法与核型分析方法一样可以用于产前三体嵌合体检测,为遗传咨询和产前诊断提供实验依据。     

A case of myelodysplastic syndrome with acquired monosomy 7 in a child with a constitutional t(1;19) and a mosaicism for trisomy 21

A 3-year-old patient presented with anemia, thrombocytopenia, and blasts in the peripheral blood. A bone marrow aspirate revealed a myelodysplastic syndrome (MDS). A mosaic abnormal female karyotype 46,XX, t(1;19)(q42; p13.1)c[12]/ 47,idem,+21c[3]/ 47,idem,-7,+21c,+mar[7] was obtained on G-banded metaphases from unstimulated bone marrow aspirate cell culture. To rule out constitutional abnormalities, we performed a cytogenetic analysis on the patient's phytohemagglutinin-stimulated peripheral blood and cultured skin fibroblasts. A karyotype of 46,XX,t(1;19) (q42;p13.1)c was found in all 20 peripheral lymphocytes analyzed, confirming the constitutional origin of the translocation. In addition, 5 out of 50 cells from two separate cultures of the skin fibroblasts contained an extra chromosome 21. The presence of two cell lines in multiple cultures indicates that the patient is a true low-level mosaic for trisomy 21. Because of the finding of monosomy 7 and a marker chromosome only in the trisomy 21 clone, we conclude that the leukemic clone arose from a hematopoietic precursor with constitutional trisomy 21. It is also possible that the t(1;19) played some role in the development of the MDS. Because acute myelogenous leukemia (AML) and MDS with Down syndrome (DS) have distinct biologic and clinical features, the identification of DS patients with a mild or normal phenotype in the AML/MDS population is of fundamental importance for clinical diagnosis and management.     

Monozygotic twins discordant for trisomy 21 and maternal 21q inheritance: a complex series of events

We report on a monochorionic/diamniotic twin pregnancy discordant for trisomy 21. Amniocentesis (at 13(5/7) weeks) was performed following ultrasound signs of hydrops and cystic hygroma in twin 1 (T1). Prenatal karyotype showed non-mosaic trisomy 21 in T1 (47,XX,+21[7]), and low-grade mosaic trisomy 21 in twin 2 (T2) (47,XX,+21[2]/46,XX[19]). Post mortem examination of fetal skin, kidneys and lungs confirmed trisomy 21 in T1 (47,XX,+21[548]) and the placenta (47,XX,+21[200]). T2 had a normal karyotype (46,XX[648]). Analysis of microsatellite polymorphisms in multiple samples from the placenta, hand, lungs, kidneys and the umbilical cords of both twins confirmed monozygosity for all loci tested, and trisomy 21 in T1. Unexpectedly, T1 and T2 inherited different maternal alleles for markers of the most distal 4 Mbp of 21q. At least four successive events are needed to explain the genetic status of both twins and include maternal MI premature chromatids separation or maternal II meiotic nondisjunction and post-zygotic events such as, chromosome rescue, nondisjunction, an/or recombination.     

A small supernumerary marker chromosome X identified by in situ hybridization

Cytogenetic analysis of a girl with moderate mental retardation and dysmorphic features revealed a 46,XX/47,XX,+mar karyotype. Fluorescence in situ hybridization using chromosome specific alpha satellite probes showed that the supernumerary marker originated from the X chromosome. To our knowledge, this is the first reported case of a female patient mosaic for a supernumerary small marker chromosome derived from X, and hence mosaic for trisomy of the pericentric region of the X chromosome.     

Characterization of two supernumerary marker chromosomes in a patient with signs of Klinefelter syndrome, mild facial anomalies, and severe speech delay

A boy with signs of Klinefelter syndrome, mild facial dysmorphic features, and severely retarded speech development displayed a female karyotype with mosaicism for two marker chromosomes 48,XX,+mar1,+mar2[68]/47,XX,+mar1[19]/47,XX,+mar2[6]/46,XX[8]. Using chromosomal microdissection, locus-specific fluorescence in situ hybridization (FISH), and PCR with several Y-chromosome markers, the larger supernumerary marker chromosome (SMC) was characterized as a ring Y-chromosome. Detection of the SRY-region explained the male phenotype. The smaller second marker chromosome contained the pericentromeric region of chromosome 8. We suggest that the co-occurrence of a partial Y-chromosome and partial trisomy 8 explain the severe speech delay and the facial dysmorphic features.     

一例idic(15)来源的嵌合型标记染色体的遗传学分析

目的:应用细胞遗传学和分子生物学检测方法明确1例嵌合型标记染色体患者的核型及其来源。方法:抽取患者的外周血样,进行染色体核型分析、基因芯片检测和荧光原位杂交检测。结果:染色体分析结果显示患者核型为mos 47,XX,+mar [45]/48,XX, +2mar[3]/ 46,XX[52];基因芯片检测结果为arr[hg...     

Turner phenotype in a girl with a 45,X/46,XX/47,XX,+18 mosaicism

We report a girl with Turner syndrome phenotype, whose karyotype on amniocyte culture was 45,X, while cytogenetic analysis on peripheral blood lymphocytes showed the presence of a mosaic chromosome constitution with three different cell lines: 45,X[5]/46,XX[3]/47,XX,+18 [35]. No signs of trisomy 18 were observed and a follow up during childhood revealed normal psychomotor development. Parental origin and mechanism of formation were studied using high polymorphic microsatellites and Quantitative Fluorescent PCR. The 18-trisomic cells showed one paternal allele and two maternal homozygous alleles at different loci of chromosome 18, suggesting a maternal M-II meiotic or a postzygotic error. A biparental origin of the X-alleles in the trisomic cells were determined, being the paternal allele retained in the 45,X cells. The possible mechanism of formation implying meiotic and/or mitotic errors is discussed.     

Complex karyotype in a low grade phyllodes tumor of the breast

Cytogenetic analysis of a phyllodes tumor of low grade malignancy disclosed the karyotype 52-55,XX, -1,+5,+7,+9,+10,+11,-15,+18,-19,+20,der(21)t(1;21)(p13;q22),+mar1x 2-4,+mar2[cp18]/46,XX. This study shows that a complex chromosome karyotype can be found in low-grade phyllodes tumors and is not necessarily a sign of extreme malignancy of these neoplasms.     

一例伴有der(Y)t(Y;1)异常的多发性骨髓瘤的临床和实验研究

目的 对1例伴有不平衡染色体易位der(Y)t(Y;1)的多发性骨髓瘤(multiple myeloma,MM)患者进行细胞遗传学、中期荧光原位杂交、免疫学及临床研究.方法 采用细胞遗传学G显带行中期染色体核型分析;用1号染色体涂抹探针、Y染色体异染色质区探针进行中期荧光原位杂交检测;免疫分型检测CD38、CD138、ZAP70等的表达及免疫电泳检测免疫球蛋白类型等.结果 细胞遗传学分析结果 发现患者具有高度复杂的异常克隆,其核型为:92,XXYY[3]/49,X,der(Y)t(Y;1)(q12;q21),t(11;14)(q13;q32),+18,+20,+21[47]/49,X,idem,del(13q22),ace[1]/98,XX,der(Y)t(Y;1)×2,+18,+18,+20,+20,+21,+21[10]/46,XY[19].中期荧光原位杂交结果 证实der(Y)t(Y;1)的G显带结果 ,为1q部分三体与Y染色体长臂的不平衡易位.其异常的单克隆免疫球蛋白为IgD,定量6.24 g/L;免疫分型结果 为表达CD38、CD138,不表达ZAP70,考虑为异常克隆浆细胞的表达.结论 Y染色体的结构异常在血液系统肿瘤中非常罕见,本文报道1例发生于多发性骨髓瘤中的伴der(Y)t(Y;1)的核型异常、实验室及临床特点.     

Cytogenetic and molecular characterization of two isodicentric Y chromosomes

We report the results of detailed molecular-cytogenetic studies of two isodicentric Y [idic(Y)] chromosomes identified in patients with complex mosaic karyotypes. We used fluorescence in situ hybridization (FISH) and polymerase chain reaction (PCR) to determine the structure and genetic content of the abnormal chromosomes. In the first patient, classical cytogenetics and FISH analysis with Y chromosome-specific probes showed in peripheral blood lymphocytes a karyotype with 4 cell lines: 45,X[128]/46,X,+idic(Y)(p11.32)[65]/47,XY,+idic(Y)(p11.32)[2]/47,X,+2idic(Y)(p11.32)[1]. No Y chromosome material was found in the removed gonads. For precise characterization of the Yp breakpoint, FISH and fiberFISH analysis, using a telomeric probe and a panel of cosmid probes from the pseudoautosomal region PAR1, was performed. The results showed that the breakpoint maps approximately 1,000 Kb from Ypter. The second idic(Y) chromosome was found in a boy with mild mental retardation, craniofacial anomalies, and the karyotype in lymphocytes 47,X,+idic(Y)(q11.23),+i(Y)(p10)[77]/46,X,+i(Y)(p10)[23]. To our knowledge, such an association has not been previously described. FISH and PCR analysis indicated the presence of at least two copies of the SRY gene in all analyzed cells. Using 17 PCR primers, the Yq breakpoint was shown to map between sY123 (DYS214) and sY121 (DYS212) loci in interval 5O in AZFb region. Possible mechanisms of formation of abnormal Y chromosomes and karyotype-phenotype correlations are discussed.     

Prenatal diagnosis of trisomy 4 mosaicism

Trisomy 4 mosaicism is rare. To our knowledge only two cases of prenatally diagnosed trisomy 4 mosaicism have been reported. One case resulted in a normal liveborn male, the other resulted in an abnormal liveborn female. The karyotype of our case at the time of amniocentesis was 47,XY,+4[3]/ 46,XY[33] and resulted in a normal liveborn male. FISH analysis using an alpha satellite chromosome 4 probe was performed to confirm the cytogenetic findings. Follow-up chromosome analysis of cord blood, peripheral blood, foreskin, and umbilical cord fibroblasts showed a normal 46,XY male karyotype in all cells. FISH analysis of cord blood, umbilical cord fibroblasts, and amniotic fluid cells demonstrated two signals in 246 nuclei (i.e., 46,XY) and three signals in six nuclei (i.e., 47,XY,+4). Here we describe the present case of trisomy 4 mosaicism, the literature is reviewed, and the significance of this finding is discussed.     

Prenatal diagnosis of low level trisomy 15 mosaicism: review of the literature

Low level chromosome mosaicism found at amniocentesis is problematic for clinicians and patients. We report prenatal diagnosis of a fetus with a rare karyotype of 47.XX, + 15/46, XX. Second trimester amniocentesis was performed for advanced maternal age. Fetal ultrasound revealed a hypoplastic right ventricle and intrauterine growth retardation (IUGR). The rest of the fetal anatomy was within normal limits. A mosaic karyotype of 47.XX, + 15/46, XX was observed. The couple interrupted the pregnancy at 19 weeks by dilation and suction evacuation. Careful evaluation of multiple pieces of fetal parts and placenta revealed one abnormal finding: a single umbilical artery. Cytogenetic metaphase and fluorescent in situ hybridization (FISH) interphase analyses of cells from fetal lung, heart, placenta, and skin revealed the presence of the trisomic line in all tissues. Molecular analysis demonstrated that the origin of the extra chromosome 15 was maternal, the error most likely occurred in meiosis I and the diploid line was of biparental inheritance. This case report discusses the associated findings in this fetus and reviews the literature describing other cases of mosaic trisomy 15.     

Trisomy 15 mosaicism and uniparental disomy (UPD) in a liveborn infant

We describe a liveborn infant with uniparental disomy (UPD) with trisomy 15 mosaicism. Third trimester amniocentesis yielded a 46,XX/47,XX,+15 karyotype. Symmetrical growth retardation, distinct craniofacies, congenital heart disease, severe hypotonia and minor skeletal anomalies were noted. The infant died at 6 weeks of life. Peripheral lymphocyte chromosomes were “normal” 46,XX in 100 cells. Parental lymphocyte chromosomes were normal. Skin biopsy showed 47,XX,+15 in 80% of fibroblasts and results were equivalent in fibroblasts from autopsy lung tissue. Molecular analysis revealed maternal uniparental heterodisomy for chromosome 15 in the 46,XX cell line. We describe an emerging phenotype of trisomy 15 mosaicism, confirm that more than one tissue should be studied in all cases of suspected mosaicism, and suggest that UPD be considered in all such cases. © 1996 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.     

Trisomy 9 syndrome: Report of a case with Crohn disease and review of the literature

We report on a 6-year-old boy with mosaic trisomy 9. The patient was born at 42 weeks of gestation to a 27-year-old G1 white woman. Birth weight was 2,820 g, length 52 cm, and Apgar scores were 4 and 6 at 1 and 5 min, respectively. The infant presented with apparently low-set ears, overfolded helices, epicanthal folds, prominent nasal bridge, high-arched palate, micrognathia, bilateral dislocated hips, left genu recurvatum, and cryptorchidism. Chromosome analysis showed an unusual karyotype: 47,XY,+inv(9qh+)/47,XY,+mar. The marker chromosome was thought to be a remnant of the inv(9qh+) chromosome. The mother's karyotype was 46,XX,inv(9qh+), while the father's was 46,XY. At age 5 months, the patient developed seizures and gastroesophageal reflux. Crohn disease was diagnosed at age 2 years, although symptoms began at age 1 year. Recurrent bouts of pneumonia have occurred since the patient's birth. Severe psychomotor retardation was also noted. Trisomy 9 syndrome was first reported in 1973. Over 30 cases have been reproted since then. Of these case reports, only 5 patients were older than 1 year. Inflammatory bowel disease has been reported in association with other chromosome abnormalities, but to our knowledge, has not been reported in trisomy 9 syndrome. © Wiley-Liss, Inc.     

Pure and complete 12p trisomy due to a maternal centric fission of chromosome 12

Pure and complete 12p trisomy are rare. Here, we report on a unique patient with trisomy 12p syndrome due to centric fission of maternal chromosome 12. Conventional cytogenetic and fluorescence in situ hybridization (FISH) techniques revealed the proposita's karyotype to be 47,XX,+fis(12)(p10)mat whereas the maternal one was 47,XX,-12,+fis(12)(p10),+fis(12) (q10). This is the first report on centric fission of chromosome 12 leading to stable telocentrics, each with a fully functional centromere. Our observation shows that the centric fission of chromosome 12 can be a new mechanism for generation of a partial centromere and trisomy 12p syndrome.     

Abnormal chromosome 9 in a neonate program. Report of three cases

We describe three cases with abnormal chromosome 9. Patient 1 shows translocation in a homologous chromosome, with a karyotype of 46,XX,t(9;9)(9pter----cen----9pter; 9qter----cen::9q13----9qter), 1qh+. This case has a variety of anomalies, including brain anomalies. Patient 2 shows a partial trisomy 9p with a karyotype of 47,XY,+del(9)(pter----q11:). The patient has the typical clinical features of 9p trisomy syndrome. Patient 3 is unique because of partial 9p tetrasomy mosaicism without phenotypic abnormalities; the karyotype is mos 46,XY/47,XY,+dic(9)(pter----cen----q21::q21----cen----pter).     

Retrieval of aneuploidy by fish-technique in a case with 46,XX/47,XXX/47,XX,+8

Summary We report on a 46 year old female with a new chromosomal finding [46,XX/47,XXX/47,XX,+8] who was referred for ovarian failure. The clinical presentation was highly unusual and the patient does not exhibit the characteristic phenotype of trisomy 8 syndrome. Interphase cytogenetics using FISH-technique revealed discrepancies with a different population of cells when compared with its metaphase index. Therefore, it is advised that patients with mosaic karyotypes should be evaluated by analyzing metaphase as well as interphase nuclei labeled with chromosome specific molecular tags, especially in the situations where the incidence of a mosaic cell line is very low. Nevertheless, in a cost-conscious environment, we must exercise caution prior to making universal recommendations concerning the usefulness of medical devices which are increasing at a logarithmic rate.     

Familial ring (18) mosaicism in a 23-year-old young adult with 46,XY,r(18) (::p11→q21::)/46,XY karyotype, intellectual disability, motor retardation and single maxillary incisor and in his phenotypically normal mother, karyotype 47,XX,+r(18)(::p11→q21::)/46,XX

We report on a 23-year-old man with craniofacial findings of the holoprosencephaly spectrum disorder (microcephaly, hypotelorism, depressed nasal bridge, single median maxillary central incisor), fusion of C2-C3 vertebrae, intellectual disability, and severe sleep apnea. Chromosome analysis of blood lymphocytes showed 75% ring (18) cells and 25% normal cells, karyotype mos 46,XY,r(18)(::p11→q21::)[75]/46,XY[25]. His mother was phenotypically normal except for a double ureter and bifid renal pelvis as in his son. She had a supernumerary ring (18) in 10% of blood lymphocytes, karyotype mos 47,XX,+r(18)(::p11→q21::)[10]/46,XX[90]. Familial ring (18) is a rare cytogenetic abnormality. This is the first report of a mother with a supernumerary ring (18) and a son with ring (18) mosaicism. Interestingly, the son showed a true mosaicism (mixoploidy) of ring (18) and normal cells. The mother's 46,XX cells could be easily explained by mitotic instability and ring loss during cell division. However, the coexistence of ring (18) and normal cells in the son is unusual. Possibly, during early postzygotic divisions of a 47,XY,+r(18) zygote, two (possibly subsequent) genetic events could have occurred, one when one normal chromosome 18 was lost (resulting in a cell line with ring 18), and one when the ring 18 was lost (resulting in a cell line without ring, "escape to normal"). Alternatively, the zygote of the son could have been 46,XY,r(18), and postzygotic loss of the ring 18 could have resulted in monosomy 18 cells followed by duplication of chromosome 18 in these cells (a rare mechanism for cell survival previously described as "compensatory" isodisomy).     

47,XX,UPD(7)mat,+r(7)pat/46,XX,UPD(7)mat mosaicism in a girl with Silver-Russell syndrome (SRS): possible exclusion of the putative SRS gene from a 7p13-q11 region

Maternal uniparental disomy for chromosome 7 (UPD7) may present with a characteristic phenotype reminiscent of Silver-Russell syndrome (SRS). Previous studies have suggested that approximately 10% of SRS patients have maternal UPD7. We describe a girl with a mos47,XX,+mar/46,XX karyotype associated with the features of SRS. Chromosome painting using a chromosome 7 specific probe pool showed that the small marker was a ring chromosome 7 (r(7)). PCR based microsatellite marker analysis of the patient detected only one maternal allele at each of 16 telomeric loci examined on chromosome 7, but showed both paternal and maternal alleles at four centromeric loci. Considering her mosaic karyotype composed ofdiploid cells and cells with partial trisomy for 7p13-q11, the allele types obtained at the telomeric loci may reflect the transmission of one maternal allele in duplicate, that is, maternal UPD7 (complete isodisomy or homodisomy 7), whereas those at the centromeric loci were consistent with biparental contribution to the trisomic region. It is most likely that the patient originated in a 46,XX,r(7) zygote, followed by duplication of the maternally derived whole chromosome 7 in an early mitosis, and subsequent loss of the paternally derived ring chromosome 7 in a subset of somatic cells. The cell with 46,XX,r(7) did not survive thereafter because of the monosomy for most of chromosome 7. If the putative SRS gene is imprinted, it can be ruled out from the 7p11-q11 region, because biparental alleles contribute to the region in our patient.