性染色体非整倍体合并罗氏易位患者的遗传学分析

目的应用细胞遗传学和分子生物学技术分析1例少弱精子患者的核型,确定其少弱精子的原因。方法应用实验室常规染色体标本制备方法进行G-显带和C-显带,并应用Yq12区DYZ1探针和Yp11.1-q11.1区DYZ3探针与病例的中期分裂相进行荧光原位杂交(fluorescence in situ hybridization,FISH),同时对患者进行了Y染色体微缺失的检测。结果结合G-显带、C-显带和FISH检测结果,确定该患者核型为46,XYY,dic(13,22)(p11.1;p11.1)。Yq11区生精基因微缺失检测未发现该患者存在缺失。结论细胞遗传学检测结合FISH可以明确诊断复杂的染色体异常,为患者提供正确的遗传咨询和生育指导。     

Pregnancy outcome in carriers of Robertsonian translocations

Robertsonian translocation carriers are at increased risk for infertility, spontaneous abortions, or chromosomally unbalanced offspring. Reproductive counseling of these carriers is challenging. We performed a retrospective analysis of all prenatal diagnoses from Robertsonian translocation carriers during the time period January 1, 1992 through December 31, 2007. Data on the carriers and the results of their prenatal analyses were retrieved as well as data on their previous pregnancies. We identified 28 female and 20 male carriers of Robertsonian translocations and results on 79 prenatal samples were obtained. Among female carriers, 10.3% of chorionic villus sampling and 5.9% of amniocentesis results were unbalanced, whereas for male carriers, this was 3.6% and 0%, respectively. When considering all pregnancies involving carriers, 52.7% of those to female carriers and 61.8% of those to male carriers led to the birth of a healthy child. Male carriers in whom the translocation was ascertained because of infertility or recurrent miscarriages appear to be at higher risk, whereas carriers in whom ascertainment was because of a family history are at lower risk. We conclude that pregnancies of Robertsonian translocation carriers are at increased risk for chromosomal imbalance, and prenatal chromosomal testing should be discussed. More than half of the pregnancies led to the birth of a healthy child, but prediction of which couples will be successful in obtaining a pregnancy with or without assisted reproductive technologies and/or embryo selection remains difficult. The reason for ascertainment of the translocation should be taken into account when counseling these couples. The possibility of preimplantation genetic diagnosis should also be discussed with the couples.     

Distinct phenotype in maternal uniparental disomy of chromosome 14

We report on the occurrence of maternal uniparental disomy for chromosome 14 (mUPD14) in a 4-year-old girl with a de novo Robertsonian translocation, 45,XX,t (13q,14q). The child has arrested hydrocephalus, short stature, minor anomalies, small hands with hyperextensible joints, and mild to moderate developmental delay. Comparison of her phenotype with those of three previously described individuals show some common distinct traits which suggest a mUPD14 syndrome. © 1994 Wiley-Liss, Inc.     

Segregation of chromosomes into the spermatozoa of a man heterozygous for a 14;21 Robertsonian translocation

Twenty-four spermatozoa from a man heterozygous for a Robertsonian translocation (45,XY,-14,-21,+t(14q;21q) were studied cytogenetically in order to determine the meiotic segregation of the translocation. When compared to the expected 1:1 ratio we observed a greater number of chromosomally normal sperm than sperm with the balanced translocation. Three sperm carried the translocation in an unbalanced form.     

Biparental inheritance of chromosome 21 polymorphic markers indicates that some Robertsonian translocations t(21; 21) occur postzygotically

Robertsonian translocations between acrocentric chromosomes are the most common structural chromosomal rearrangements in humans and many other organisms, and several mechanisms for their formation have been proposed. We have analyzed highly informative DNA polymorphisms in a family with a non-mosaic de novo Robertsonian translocation 21q; 21q, to determine the parental origin of the two 21q arms of the rearranged chromosome. The genotypes indicated a biparental origin, i.e. one 21q was paternal and the other maternal. These results imply that in some cases the formation of the rob (21q; 21q) occurs in the zygote or in the first few postzygotic mitotic divisions. © 1994 Wiley-Liss, Inc.     

Subsequent pregnancy outcomes in recurrent miscarriage patients with a paternal or maternal carrier of a structural chromosome rearrangement

Information concerning the prognosis of subsequent pregnancies in patients with reciprocal translocations is limited. This study was performed to determine the percentage success rate with first pregnancies after ascertainment of a carrier status. A total of 2,382 couples with a history of two or more consecutive miscarriages were studied in multicenters. The prevalence of an abnormal chromosome in either partner was examined, and subsequent success rates were compared between cases with and without an abnormal karyotype in either partner. A total of 129 couples (5.4%) had an abnormal karyotype in one partner excluding inversion 9 in 44 men and in 85 women. Thus, 2,253 couples had a normal karyotype in both partner. Eighty-five (3.6%) had translocations, 13 being Robertsonian translocations. Twenty-nine of the 46 cases (63.0%) who became pregnant with reciprocal translocations in either partner experienced a live birth with natural conception. In contrast, 950 of 1,207 cases (78.7%) with normal chromosomes had successful live births, the difference being significant (P = 0.019). No infant with an unbalanced translocation was found in 29 cases of successful pregnancy following recurrent miscarriage. Pregnancy prognosis was worsened with either maternal or paternal reciprocal translocations. Explanation of the success rate with natural conception should be provided before the subsequent pregnancy after ascertainment of carrier status.     

脑死亡动物模型的研究进展

脑死亡动物模型可用于研究器官移植供体的功能,大鼠、猪、狗、家兔、小鼠等是脑死亡动物模型常选用的模式动物.当前具有代表性的脑死亡建模方法,是通过急剧或缓慢颅内加压法建模,制备突发性脑死亡模型和渐进性脑死亡模型.模式动物脑死亡的判定目前尚无统一标准,现有脑死亡动物模型仍存在不足,不能全面模拟临床脑死亡,建模成功的判断与临床上脑死亡的诊断仍有差别.     

Molecular analysis of mosaicism for two different de novo acrocentric rearrangements demonstrates diversity in Robertsonian translocation formation

Robertsonian translocations (ROBs) involving chromosome 21 occur in about 5% of individuals with Down syndrome. ROBs are the most common chromosomal rearrangements in humans and are formed through whole arm exchanges of any two acrocentric chromosomes. The de novo formation of ROBs occurs at exceptionally high rates. The present case concerns a child with mosaic Down syndrome who has two cell lines that contain two different de novo ROBs: 45,XX,rob(14;21)(q10;q10) and 46,XX,rea(21;21)(q10;q10),+21. To elucidate the mechanisms by which the rearrangements formed, somatic cell hybrids were constructed to allow the parental origins of the chromosomes involved in the ROBs to be distinguished. The analysis of the hybrids showed that the rob(14q21q) must have formed postzygotically because it contained a maternal chromosome 14 and a paternal chromosome 21. Furthermore, hybrid analysis of the rea(21q21q) demonstrated two copies of the same chromosome from the mother and thus, by definition, was an isochromosome [i(21q)]. All free-lying chromosomes 21 isolated in hybrids were of maternal origin. These chromosomes may have originated from either of the patient's cell lines. We present four hypotheses for the formation of the two cell lines of this child. This case is part of an ongoing project to determine the mechanism(s) of de novo ROB formation and the results differ from the other de novo rob(14q21q) studied in our laboratory (n = 7) in that all previously studied translocations were maternally derived, leading to the conclusion that most de novo rob(14q21q) occur in oogenesis. The current case illustrates that other mechanisms may contribute to ROB formation. Am. J. Med. Genet. 80:252–259, 1998. © 1998 Wiley-Liss, Inc.     

Molecular studies of translocations and trisomy involving chromosome 13

Twenty-four cases of trisomy 13 and one case with disomy 13, but a de novo dic(13,13) (p12p12) chromosome, were examined with molecular markers to determine the origin of the extra (or rearranged) chromosome. Twenty-one of 23 informative patients were consistent with a maternal origin of the extra chromosome. Lack of a third allele at any locus in both paternal origin cases indicate a somatic duplication of the paternal chromosome occurred. Five cases had translocation trisomy: one de novo rob(13q14q), one paternally derived rob(13q14q), two de novo t(13q13q), and one mosaic de novo t(13q13q)/r(13). The patient with a paternal rob(13q14q) had a maternal meiotic origin of the trisomy; thus, the paternal inheritance of the translocation chromosome was purely coincidental. Since there is not a significantly increased risk for unbalanced offspring of a t(13q14q) carrier and most trisomies are maternal in origin, this result should not be surprising; however, it illustrates that one cannot infer the origin of translocation trisomy based on parental origin of the translocation. Lack of a third allele at any locus in one of the three t(13q13q) cases indicates that it was most likely an isochromosome of postmeiotic origin, whereas the other two cases showed evidence of recombination. One balanced (nontrisomic) case with a nonmosaic 45,−13,−13,t(13;13) karyotype was also investigated and was determined to be a somatic Robertsonian translocation between the maternal and paternal homologues, as has been found for all balanced homologous Robertsonian translocations so far investigated. Thus, it is also incorrect to assume in de novo translocation cases that the two involved chromosomes are even from the same parent. Despite a maternal origin of the trisomy, we cannot therefore infer anything about the parental origin of the chromosomes 13 and 14 involved in the translocation in the de novo t(13q14q) case nor for the two t(13;13) chromosomes showing a meiotic origin of the trisomy. © 1996 Wiley-Liss, Inc.     

Molecular cytogenetics analysis with whole chromosome paint probes of sperm nuclei from a (13;15) Robertsonian translocation carrier

Meiotic segregation of a Robertsonian translocation (13;15) was assessed in sperm nuclei using dual-color fluorescent in situ hybridization (FISH) with whole-chromosome paint probes. Most spermatozoa in the (13;15) translocation carrier resulted from alternate segregation. Although an increased frequency of unbalanced gametes was observed, spontaneous pregnancy led to the birth of a boy with a normal karyotype.     

Whole-arm reciprocal translocation (WART) between Robertsonian chromosomes: finding of a Robertsonian heterozygous mouse with karyotype derived through WARTs

The karyotype of a mouse trapped in a hybrid zone between a Robertsonian (Rb) population (2n=22) and a population with the standard karyotype (2n=40-all-telocentrics) shows two Rb chromosomes with new arm compositions. We suggest that whole-arm reciprocal translocations between Rb chromosomes gave rise to the new chromosome constitution and that such events can greatly help in understanding house mouse karyotype diversification and chromosomal speciation.     

Further characterization of 19 cases of rea(21q21q) and delineation as isochromosomes or robertsonian translocations in down syndrome

We have used 9 conventional RFLPs and 6 dinucleotide repeat polymorphisms on chromosome 21q to demonstrate that 17 of 19 cases of rea(21q21q) were consistent with isochromosomes i(21q) with the remaining 2 being true Robertsonian translocations. Eight of the 17 isochromosomes were of maternal origin and 9 cases were paternally derived. The 2 Robertsonian translocations were both maternally derived. Of the 17 isochromosomes, 7 were dicentric Wc(21q)I and 10 were monocentric M21q)l. Both rob(21q21q) were monocentric. Our findings agree with those made in 17 previously published cases of rea(21q21q). The parental origins of the i(21q) were equally divided between maternal (n = 17) and paternal (n = 15) origins. All 4 true rob(21q21q) reported to date are of maternal origin. Collectively, it appears that most homologous rearrangements of chromosome 21 are isochromosomes and only a small proportion are consistent with true Robertsonian translocations. © 1993 Wiley-Liss, Inc.     

Fluorescence in-situ hybridisation and molecular studies used in the characterisation of a Robertsonian translocation (13q15q) in Prader-Willi syndrome

A patient with classical Prader-Willi syndrome was found to have a Robertsonian translocation 45,XY,t(13_q15_q)mat. On CBG banding, the translocation chromosome had a large centromere with one primary constriction. Using fluorescence in situ hybridisation, positive signals were obtained with chromosome 13 and chromosome 15 centromere probes, proving that the translocation was dicentric. NOR banding was negative in this chromosome, suggesting that the breakpoints were at 13p11 and 15p11. DNA studies showed that, while there was no deletion involving 15(q11′13), maternal uniparental disomy for chromosome 15 was present. We compare our findings with the five other cases of familial Robertsonian translocation PWS that have been reported.     

Cytogenetic,epidemiological and clinical profile of children with Down syndrome in Karnataka

Introduction

Down syndrome is one of the best recognized and the most common chromosomal aneuploidy with high life expectancy than other chromosomal aneuploidies. The clinical features are quite distinguishing and easily identifiable, but a karyotype analysis is always better to confirm the diagnosis. It is also needed for calculating the risk of recurrence and for genetic counseling. This study was done to analyze the clinical features, cytogenetic and epidemiological profile of Down syndrome children in Tumkur and Bangalore region of Karnataka.

Genetic analysis of hantaviruses and their rodent hosts in central-south China

Hantaan virus (HTNV) and Seoul virus (SEOV) are two major zoonotic pathogens of hemorrhagic fever with renal syndrome (HFRS) in Asia. Hubei province, which is located in the central-south China, had been one of the most severe epidemic areas of HFRS. To investigate phylogenetic relationships, genetic diversity and geographic distribution of HTNV and SEOV in their reservoir hosts, a total of 687 rodents were trapped in this area between 2000 and 2009. Sequences of partial S- and M-segments of hantaviruses and mitochondrial D-loop gene from 30 positive samples were determined. Our data indicated that SEOV and HTNV were co-circulating in Hubei. Phylogenetic analysis based on partial S- and M-segment sequences revealed two and three previously undefined lineages of SEOV, and a novel genetic lineage of HTNV, respectively. Four inter-lineage reassortment SEOVs carried by Rattus norvegicus and Apodemus agrarius were observed. It suggests that SEOV may cause spillover infections to A. agrarius naturally. The abundance of the phylogenetic lineages of SEOV suggested that central-south China was a radiation center for SEOVs.     

Successful PGD cycles for mosaic Robertsonian translocation carriers provide insights into the mechanism of formation of the derivative chromosomes

Preimplantation genetic diagnosis (PGD) has been carried out for two couples with different mosaic Robertsonian translocations. Two PGD cycles for a mosaic 13;13 homologous Robertsonian translocation carrier resulted in the birth of a healthy child in each cycle, illustrating the importance of scanning G‐banded preparations from homologous Robertsonian carriers for the presence of a normal cell line. One couple was referred for PGD because the male partner carried a mosaic 14;15 Robertsonian translocation with a normal cell line. A single PGD cycle resulted in the birth of a healthy child. Follow‐up studies and extended FISH analysis of the carrier's lymphocytes detected three cell lines, two carrying different 14;15 Robertsonian chromosomes and one normal cell line. The two 14;15 Robertsonian chromosomes had different breakpoints in the proximal short arm regions. We suggest that the presence of the D15Z1 polymorphism on the short arm of one chromosome 14 mediated the post‐zygotic formation of the two different Robertsonian chromosomes. © 2013 Wiley Periodicals, Inc.     

Uniparental isodisomy of chromosome 14 in two cases: An abnormal child and a normal adult

Uniparental disomy (UPD) of a number of different chromosomes has been found in association with abnormal phenotypes. A growing body of evidence for an imprinting effect involving chromosome 14 has been accumulating. We report on a case of paternal UPD of chromosome 14 studied in late gestation due to polyhydramnios and a ventral wall hernia. A prenatal karyotype documented a balanced Robertsonian 14:14 translocation. The baby was born prematurely with hairy forehead, retrognathia, mild puckering of the lips and finger contractures. Hypotonia has persisted since birth and at age one year, a tracheostomy for laryngomalacia and gastrostomy for feeding remain necessary. Absence of maternal VNTR polymorphisms and homozygosity of paternal polymorphisms using chromosome 14 specific probes at D14S22 and D14S13 loci indicated paternal uniparental isodisomy (pUPID). Parental chromosomes were normal. We also report on a case of maternal UPD in a normal patient with a balanced Robertsonian 14:14 translocation and a history of multiple miscarriages. Five previous reports of chromosome 14 UPD suggest that an adverse developmental effect may be more severe whenever the UPD is paternal in origin. This is the second reported patient with paternal UPD and the fifth reported with maternal UPD, and only few phenotypic similarities are apparent. Examination of these chromosome 14 UPD cases of maternal and paternal origin suggests that there are syndromic imprinting effects. © 1995 Wiley-Liss, Inc.     

Some mechanisms of action of vasopressin on animal behavior

The effect of arginine vasopressin on the behavior of rats after its microinjection into the caudal ventrolateral region of the brain stem and corticomedial amygdala was investigated. In the region of the brain stem vasopressin has a predominant inhibitory effect of motor activity and orienting behavior evoked by electrical stimulation of the hypothalamus. In the region of the corticomedial amygdala under the effect of the peptide an alternation of motor inactivation with orienting reflexes, grooming, and genital grooming is observed. In this case an increase of the spontaneous frequency of neuronal impulses occurs in the investigated regions of the brain.Translated from Fiziologicheskii Zhurnal SSSR, imeni I. M. Sechenova, Vol. 73, No. 5, pp. 590–594, May, 1987.