16种罕见的人类染色体异常核型报告

通过对患有闭经、自发流产、死胎、死产等患者外周血淋巴细胞染色体检查,发现16种新的罕见人类染色体异常核型,它们是46,XY,t(6;11)(q25;p15);46,XY,inv(3)(p25;q29);46,XY,t(7;18)(q10;p10);46,X,t(X;13)(q24;q14);46,XY,t(4;7)(q33;q22);46,XY,t(8;15)(q24;q15);46,XY,t(2;17)(q33;q25);46,XX,t(4;7)(q34;q11);46,XX,t(1;3)(p36;p23);46,XX,t(4;6)(q35;p11);46,X,inv(X)(q22;q28);46,XX,t(7;10)(p11;q26);46,XX,t(3;6)(p21;q23);46,XX,t(8;16)(p21;p13);46,XX,t(8;9)(q21;q34);46,XY,t(17;22)(q21;q11)。描述了患者的临床表现,并对生殖异常患者染色体畸变与其表型效应关系进行探讨。Abstract：By examining the lymphocytic chromosomes of peripheral blood from patients with amenorrhea,spontaneous abortion and stillbirth history, .the 16 rare species of human chromosomal abnormal karyotypes were discovered. They wre 46,XY,t(6;11)(q25;p15);46,XY,inv(3)(p25;q29);46,XY,t(7;18)(q10;p10);46,X,t(X;13)(q24;q14);46,XY,t(4;7)(q33;q22);46,XY,t(8;15)(q24;q15);46,XY,t(2;17)(q33;q25);46,XX,t(4;7)(q34;q11);46,XX,t(1;3)(p36;p23);46,XX,t(4;6)(q35;p11);46,X,inv(X)(q22;q28);46,XX,t(7;10)(p11;q26);46,XX,t(3;6)(p21;q23);46,XX,t(8;16)(p21;p13);46,XX,t(8;9)(q21;q34);46,XY,t(17;22)(q21;q11). Their clinical situation were described. Discussion on the relationship between the chromosomal aberrations and phenotype effect indicates the importance of chromosome karyotyping in patients with abnormal reproductive history.     

9种新的人类染色体异常核型报告

发现9种新的人类染色体异常核型,分别为: 46, XX, t(2; 10)(q33; q11); 46, XY, t(10; 12)(q26; q22); 46, XY, t(6; 15)(p23; q23); 46, XY, t(1; 6)(p36; q21); 46, XY, t(1; 19)(p32; p13); 46, XY, t(16; 18)(q22; q21); 46, XY, inv(1)(p36q25); 46, XY, t(13; 17)(q12; q25); 46, XY, t(15; 21)(q26; q11)。异常核型是导致自然流产和不育的原因。 Abstract　Nine new kinds of human chromosomal abnormal karyotypes were reported. They were46, XX, t(2; 10)(q33; q11); 46, XY, t(10; 12)(q26; q22); 46, XY, t(6; 15)(p23; q23); 46, XY, t(1; 6)(p36; q21); 46, XY , t(1; 19)(p32; p13); 46, XY, t(16; 18)(q22; q21); 46, XY, inv(1)(p36q25); 46, XY, t(13; 17)(q12; q25) and 46, XY, t(15; 21)(q26; q11). The chromosomal anomalies were the causes of spontaneous abortions and infertilities.     

14例闭经患者的细胞遗传研究

运用数种细胞遗传学技术研究了14例闭经患者的病因,发现11例(占78.6％)具有异常核型。包括45,Ⅹ(3例);45,Ⅹ/46,Ⅹ,i(Xq)(2例);45,Ⅹ/46,ⅩⅩ/47,ⅩⅩⅩ(1例);45,X/46,Ⅹ,idlc(X)(1例);16,X,idic(X)(1例);46,X,del(X)(q24)(1例);15,X/46,X,del(X)(p11.3)(1例)和46,XY(1例)。其中6例(54.5％)涉及X染色体结构异常。对闭经患者的细胞遗传病因、核型与表型之间的可能关系以及失活X染色体的迟复制区段进行了讨论。     

新近发现的自然流产夫妇的几种染色体异常

本文对218对自然流产夫妇进行了染色体分析,发现17种异常核型,其中46,XY,t(13;14)(q14;q32)、46,XX,t(11;18)(q25;q21)、46,XY,t(4;10)(q31;q11)、 46,XX,t(15;21)(q24;q11)和46,XY,t(6;16)(p24;q13)为世界首报核型。作者同时报道了7例单个细胞染色体异常病例。对染色体异常与流产的关系进行了讨论。 Abstract:Chontaneous abortions and 17 kinds of abnormal karyotypes were discovered.Among which,five abnormal karyotypes were first reported in the world.They are 46,XY,t (13;14)(q14;q32);46,XX;t(11;18)(q25;q21);46,XY,t (4;10) (q31;q11); 46,XX,t (15;21) (q24;q11) and 46,XY,t (6;16) (p24;q13). The chromosome abnormalitics and spontaneous abortious was discussed.     

无精和严重少精症患者的遗传缺陷分析——-附2例世界首报染色体异常核型

对217例无精和严重少精症患者外周血淋巴细胞染色体核型进行分析,并采用聚合酶链反应对7例Y染色体结构异常患者的AZFc区进行检测。发现187例无精症患者中检出异常核型77例（41.18%）（其中46,XY,t(6;14)(p21;p13),46,XY,t(8;12)(p21;q24)为世界首报核型）,主要涉及染色体异常（数目异常和结构异常）;染色体异态（Y染色体异态和9号染色体臂间倒位）及46,XX性反转;30例严重少精症患者中检出异常核型4例（13.33%）（结构异常和46,XX性反转）。由此可见,性染色体数目和结构异常是精子发生障碍的主要原因,其次常染色体的某些断裂点也可能影响精子发生。AZFc区的缺失与否与精子发生也有直接关系。     

一例涉及六条染色体有三个易位的畸变

本文报道了一例极为罕见的、涉及六条染色体有三个易位的染色体结构畸变。患者为10个月龄的幼儿,智力明显低下。取外周血淋巴细胞作G显带染色体标本,核型分析60个中期细胞的结果,每个核型均具有涉及2、3;6、15;7、14号六条染色体的三个易位,其核型按国际体制可表示为46,XY,t(2;3)(q37;q25),t(6;15)(q13;p11),t(7;14)(q11;q13)。     

罕见的异常核型6例报告

ReportofSixRareCasesofAbnormalKaryotypesLiGuixinSongGuangjiangSongXingjun(BiologyDepartment,TaishanMedicalCollege,Taiah,Shandong271000)我定在对外遗传咨询并进行染色体检查时,发现6例异常核型,经医学细胞遗传学国家培训中心夏家辉等专家鉴定,为世界首报枝型．现报告如下：例1女,26岁,表型正常．妊娠4次,均于3个月自然流产．无任何诱因．常规染色体检查,核型为46,XX但有两条异常染色体．经G显带分析,异常核型为46,XX,t（1;8）（lqter-1p32：：8q22-8qter;8pier-8q22：：1p32－1pter）（图1）．例2女,25岁…     

一例t(1; 5）相互易位并伴inv(12)臂内倒位的报告

人类染色体平衡易位携带者多为表型正常，其 最显著的遗传效应是流产及生出染色体异常的子女。 我们在男性不孕症的研究中发现一例核型为46, X介 t(l; 5)(p12; q3l), inv(12) (q15 82405）的平衡易 位携带者并伴一条12号染色体臂内倒位。现报告如 下。     

一例t(1;5)相互易位并伴inv(12)臂内倒位的报告

人类染色体平衡易位携带者多为表型正常,其最显著的遗传效应是流产及生出染色体异常的子女。我们在男性不孕症的研究中发现一例核型为46,XY,t(1;5)(p12;q31),inv(12)(q15 q2405)的平衡易位携带者并伴一条12号染色体臂内倒位。现报告如下。     

孕早期产前诊断46,XX,rec(4)和46,XY,inv(4)及其家系的细胞遗传学研究

本文报道了用绒毛细胞直接制备染色体的方法,诊断出一个家系中3例染色体异常胎儿。一例核型为:46,XX,rec(4),dup p,inv(4)(P12 q35)pat;另外两例核型为:46,XY,inv(4)(p12 q35)Pat。对此家系2代中8人进行了染色体检查。其中3人核型为46,XY,inv(4)(P12q35)。3例胎儿的异常染色体是来自他们的父亲(4号染色体臂间倒位携带者)。并讨论了臂间倒位染色体携带者对后代的影响。     

9种新的人类染色体异常核型报告

发现９种新的人类染色体异常核型,分别为：４６,ＸＸ,ｔ（２;１０）（ｑ３３;ｑ１１）;４６,ＸＹ,ｔ（１０;１２）（ｑ２６;ｑ２２）;４６,ＸＹ,ｔ（６;１５）（ｐ２３;ｑ２３）;４６,ＸＹ,ｔ（１;６）（ｐ３６;ｑ２１）;４６,ＸＹ,ｔ（１;１９）（ｐ３２;ｐ１３）;４６,ＸＹ,ｔ（１６;１８）（ｑ２２;ｑ２１）;４６,ＸＹ,ｉｎｖ（１）（ｐ３６ｑ２５）;４６,ＸＹ,ｔ（１３;１７）（ｑ１２;ｑ２５）;４６,ＸＹ,ｔ（１５;２１）（ｑ２６;ｑ１１）。异常核型是导致自然流产和不育的原因。     

A case of (X;15) translocation diagnosed as a paracentric inversion of Xp: diagnostic revision with FISH.

In 1990 we reported the case of a 17 years old girl with growth retardation, overweight and primary amenorrhea, presenting a de novo chromosomal rearrangement cytogenetically characterized as a paracentric inversion of the short arm of X chromosome. The FISH analyses that were recently performed, revealed that in fact our patient presented a case of unbalanced translocation, 46,X, t(X;15)(p11.2; q15).     

Regional localization of alpha-galactosidase (GLA) to Xpter----q22, hexosaminidase B (HEXB) to 5q13----qter, and arylsulfatase B (ARSB) to 5pter----q13

Two series of somatic cell hybrids were made by fusion of human cells with karyotypes 46,X,t(X;2;15)(q22;p12;p12) and 46,XX,t(5;7)(q13;p15) and rodent cells. Chromosome and isozyme analysis of human chromosomes and gene products in the hybrids localized GLA to Xpter----q22, HEXB to 5q13----qter, in both cases narrowing the regional assignments, and ARSB to 5pter----q13.     

Partial trisomy of distal 5q and partial monosomy of Xp as a result of mating between two translocation carriers: a female with a balanced translocation t(X;5)(p11;q31) and a male with a der(13;14)(q10;q10)--a case report and a family study

This paper presents the family of a dysmorphic child with the phenotypic features of Turner's syndrome and 5q trisomy, whose parents are both carriers of a balanced translocation. The parents' karyotypes are 46,X,t(X;5)(p11.1;q31) and 45,XY,der(13;14)(q10;q10), respectively.     

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.     

Complex mosaicism in sex reversed SRY+ male twins

Sex reversal is characterized by discordance between genetic and phenotypic sex. Most XX males result from an unequal interchange between X and Y chromosomes during paternal meiosis, therefore transferring SRY to the X chromosome, which explains the male development in the presence of an otherwise normal female karyotype. We present here the case of sex reversed SRY+ male twins with several cell lines. They consulted for infertility. The presence of SRY on an X chromosome was demonstrated by FISH. Their respective karyotypes were: 46,X,der(X)t(X;Y)(p22.3;p11.2)[249]/45,X [12]/45,der(X)t(X;Y)(p22.3;p11.2)[11]/47,XX,der(X)t(X;Y) (p22.3;p11.2)[1]/47,X,der(X)t(X;Y)(p22.3;p11.2)x2[1]/50, XX,der(X)t(X;Y)(p22.3;p11.2)x4[1]/46,XX[1] for the first twin (SH-1) and 46,X,der(X)t(X;Y)(p22.3;p11.2)[108]/45,X [3]/47,XX,der(X)t(X;Y)(p22.3;p11.2)[2]/45,der(X)t(X;Y) (p22.3;p11.2)[1]/47,X,der(X)t(X;Y)(p22.3;p11.2)x2[1] for the second twin (SH-2). There are three different types of XX males: 1) with normal genitalia, 2) with genital ambiguity, and 3) XX true hermaphrodites. The phenotype of the twins presented in this report is consistent with what is generally seen in XX SRY+ males: they have normal genitalia.     

Array CGH characterization of an unbalanced X-autosome translocation associated with Xq27.2–qter deletion, 11q24.3–qter duplication and Xq22.3–q27.1 duplication in a girl with primary amenorrhea and mental retardation

We present array comparative genomic hybridization (aCGH) characterization of an unbalanced X-autosome translocation with an Xq interstitial segmental duplication in a 16-year-old girl with primary ovarian failure, mental retardation, attention deficit disorder, learning difficulty and facial dysmorphism. aCGH analysis revealed an Xq27.2–q28 deletion, an 11q24.3–q25 duplication, and an inverted duplication of Xq22.3–q27.1. The karyotype was 46,X,der(X)t(X;11)(q27.2;q24.3) dup(X)(q27.1q22.3). We discuss the genotype–phenotype correlation in this case. Our case provides evidence for an association of primary amenorrhea and mental retardation with concomitant unbalanced X-autosome translocation and X chromosome rearrangement.     

Sex reversal due to Xp disomy by t(X;Y)(p21;q11).

A 20-month-old infant exhibiting psychomotor retardation, dysmorphisms and ambiguous external genitalia was found to have a 46-chromosome karyotype including a normal X chromosome and a marker Y with most of Yq being replaced by an extra Xp21-->pter segment. The paternal karyotype (G and C bands) was 46,XY. The marker Y composition was verified by means of FISH with a chromosome X painting, an alphoid repeat and a DMD probe. Thus, the final diagnosis was 46,X,der(Y)t(X;Y)(p21;q11)de novo.ish der(Y)(wcpX+,DYZ3+,DMD+). The patient's phenotype is consistent with the spectrum documented in 13 patients with similar Xp duplications in whom sex reversal with female or ambiguous genitalia has occurred in spite of an intact Yp or SRY gene. A review of t(X;Y) identifies five distinct exchanges described two or more times: t(X;Y)(p21;q11), t(X;Y)(p22;p11), t(X;Y)(p22;q11-12), t(X;Y) (q22;q12), and t(X;Y)(q28;q12). These translocations probably result from a recombination secondary to DNA homologies within misaligned sex chromosomes in the paternal germline with the derivatives segregating at anaphase I.     

Isodicentric X chromosome in a patient with Turner syndrome — implications for localization of the X-inactivation center

Summary Cytogenetic analyses have previously shown that the region Xq11.2–q21 is retained in all structurally abnormal X chromosomes. From these observations the conclusion has been drawn that this critical region on the proximal long arm of the X chromosome contains the locus controlling X-inactivation. Structurally abnormal X chromosomes without the X-inactivation center would allow nullisomy, disomy, or trisomy for genes on the X chromosome, and this condition is presumed nonviable. We studied a 28-year-old woman with primary amenorrhea and features of Turner syndrome who had an unusual isodicentric chromosome of the short arm of X. This patient provided us with the opportunity to more closely define the location of the X-inactivation center. High resolution chromosome analysis showed a 46,X,idic(X)(pterq13.2::q13.2pter) chromosome pattern in 94% of her cells and a 45,X complement in 6%. Replication studies showed this derivative X chromosome to be late-replicating (inactive) in all cells analyzed. DNA analysis confirmed the breakpoint of the isodicentric chromosome to be proximal to PGK1. Based on these results, the locus for the X-inactivation center can be refined to be within Xq11.2–q13.2.