小麦条锈菌国际鉴别寄主Vilmorin23的抗条锈病基因YrV23微卫星标记

Vilmorin23是小麦条锈菌国际鉴别寄主和国际上重要抗源材料。采用SSR技术,利用由Vilmorin23为基因供体转育而成的小麦抗条锈近等基因系Taichung29*6/YrV23,选用YrV23所在2B染色体上的55对SSR引物,对Taichung29*6/ YrV23及其轮回亲本Taichung29和抗性基因供体Vilmorin23的基因组DNA进行PCR扩增和聚丙烯酰胺凝胶电泳分析。结果显示,引物Xwmc356在近等基因系与轮回亲本间扩增出特异性DNA片段,经F₂代群体150个抗、感单株检测证实,该片段位点与抗条锈病基因YrV23有连锁关系,遗传距离为9.4 cM。Xwmc356可作为抗条锈基因YrV23的SSR标记。      

利用PCR鉴定四川雉鹑性别

四川雉鹑是我国特有珍稀濒危雉类,为国家Ⅰ级保护动物.本文通过设计引物,扩增四川雉鹑W染色体上雌性特异基因HINTW,利用PCR产物有无对其进行性别鉴定,发现在四川雉鹑中雄性个体无阳性产物,而雌性扩增出500 bp和300 bp 2条条带.应用通用引物扩增四川雉鹑基因组CHD基因,其中雄性个体扩增出约500 bp的条带,而雌性个体则扩增出500 bp和750 bp 2条条带,通过其Z/W染色体上基因片段长度差异可进行性别鉴定.上述两种方法对9个四川雉鹑的性别鉴定结果均一致.     

大鼠Y染色体探针的制备与鉴定

目的:研究制备地高辛标记的大鼠性别决定基因Y区(Y染色体,SRY)探针,用于检测雄性大鼠来源的细胞在雌性受鼠体内的SRY基因表达情况.方法:按已知的雄性大鼠Y染色体上性别决定基因(SRY)的序列,请上海博亚公司合成oligoDNA,采用PCR技术连接并扩增,地高辛标记的方法制备基因探针.以雌性大鼠为对照,原位杂交法检测大鼠肾组织切片Y染色体阳性细胞情况.结果:用原位杂交法证实在雄性大鼠肾脏内有SRY表达,而雌性大鼠肾脏无Y染色体阳性细胞,证实这种探针具有较高的敏感性和特异性.结论:大鼠性别决定基因SRY探针的制备成功,为进一步研究异体雄性大鼠细胞移植后的分布和表达提供了实验基础.     

中国畲族、锡伯族、壮族和藏族Penta E位点的遗传多态性

应用复合PCR扩增技术和荧光毛细管DNA自动电泳分型的方法,使用国产试剂盒,检测Penta E位点在中国畲族、锡伯族、壮族和藏族中的基因频率分布情况。获得了4个民族各约100名无关个体的Penta E位点的等位片段及基因型频率,共发现20个等位片段,其频率分布在0.0048～0.2396之间。各民族的平均杂合度为0.8838,平均个体识别力0.9748,平均非父排除率0.7635,平均多态信息总量0.8950。研究表明Penta E位点属高杂合度、高识别能力的遗传标记,是法庭科学亲子鉴定和个体识别的理想位点。      

偏执型精神分裂症与4个涉及多巴胺代谢的基因之间的关联分析

精神分裂症是由多基因相互作用导致的复杂疾病。对其易感基因,儿茶酚氧位甲基转移酶基因（COMT）的众多报道充满了矛盾。在对偏执型精神分裂症研究中,我们用多基因座关联分析法研究了4个涉及神经递质多巴胺代谢的基因之间的相互作用。分析结果支持如下假说：COMT-136-BclI对Val^108/158Met有调控作用。当前者的基因型是CC时,后者的易感等位基因型是Met（A）;而当前者的基因型是GG时,后者的易感等位基因型是Val（G）。这一新的假说可以解释此前单基因座分析对Val^108/158Met(COMT)的截然相反的报道,同时也显示了多基因座分析对复杂疾病研究的必要性。      

棉铃虫性染色体两种分子标记的克隆及序列分析

为了建立棉铃虫Helicoverpa armigera性染色体的特异性分子标记,利用RAPD-PCR技术对雌雄棉铃虫基因组DNA进行筛选,从500种随机引物中筛选到1 条引物（Operon编号为AF-18）,可扩增出1条约450 bp 的雌性特异片段。经克隆测序并合成特异引物进行验证,表明该片段为棉铃虫雌性特异分子标记,位于W染色体上。利用家蚕、果蝇等昆虫Kettin基因序列,克隆了棉铃虫的同源基因HaKettin片段,并采用荧光定量PCR技术,以棉铃虫的DH-PBAN基因为参照基因,检测棉铃虫雌雄不同个体间HaKettin基因与DH-PBAN基因的拷贝数之比,结果表明：雄体HaKettin∶DH-PBAN=1.0,雌体HaKettin∶DH-PBAN=0.5,据此推断HaKettin基因位于棉铃虫Z染色体上。     

联会复合体——原发无精症发病中的重要角色

联会复合体(synaptonemal complex,SC)是一种减数分裂特异性超分子蛋白质结构,与减数分裂I(改罗文)中同源染色体的凝缩、配对、重组和分离密切相关。近年来,联会复合体的研究取得了一系列重要的进展,包括在其组成成分和功能上的一些新发现。在小鼠不育模型中联会复合体及其编码基因的异常可引起精子发生障碍。更重要的是,联会复合体编码基因之一SCP3单个碱基缺失导致的无精症已在人类原发不育患者中得到证实。对联会复合体基因SCP1的进一步研究也正在进行之中。      

一例特殊inv(Y)形成机理的研究

应用双色荧光原位杂交的方法,国内首次报道一例特殊inv(Y)异常的性质,探讨Y染色体倒位结构异常的形成机理以及与习惯性流产临床表型的关系。应用 Biotin-11-dUTP标记的Y染色体短臂断裂点Yp11.3探针（编号889）和CY3标记的Y染色体长臂断裂点Yq12远端异染色质区探针(编号PY3.4),对1例G显带核型分析为[46, XY(90%) / 46, X, inv(Y)(p11.3;q12)]的平衡易位携带者进行双色荧光原位杂交研究。双色FISH结果显示,该易位携带者异常核型比例为22%,稍高于G显带分析中确定的比例。而且,除G显带检测出的倒位类型外,又有两种类型的倒位,其中涉及到常规显带技术难以检测出的染色单体型倒位。3种倒位类型的存在说明该患者inv(Y)断裂点呈不均一性。FISH技术是一种能准确可靠检测出染色体倒位形成的重要手段。      

半滑舌鳎雌性特异AFLP标记CseF783的克隆及其在遗传性别鉴定中的应用

半滑舌鳎性别控制和全雌育种等研究领域中迫切需要一种能够快速鉴定鱼类个体遗传性别的有效方法。文章采用AFLP技术, 利用选择性引物组合(E-ACT/M-CAA)从半滑舌鳎中筛选到一条雌性特异的AFLP标记。对该标记进行二次PCR扩增、琼脂糖凝胶回收、克隆、测序。分析表明, 序列全长为791 bp, 与GenBank中的序列无同源性。以该雌性特异AFLP标记DNA序列为模板, 设计了一对特异的PCR引物, 成功地将其转化为SCAR(Sequence characterized amplified regions)标记, 并在100尾已知性别的半滑舌鳎个体(雌雄各50尾)中进行验证, 结果表明, 该SCAR标记在所有雌性个体中均扩增得到一条长度为324 bp的DNA条带, 而在49尾雄性个体中均扩增不到该DNA条带(有1尾雄性个体例外), 证明该SCAR标记是雌性特异的, 并可用于半滑舌鳎个体遗传性别鉴定。随后, 利用该SCAR标记检测了3日龄半滑舌鳎幼苗, 结果表明, 雌性个体比例为41.7%。     

番茄抗青枯病基因的AFLP分子标记

用番茄高抗青枯病品种“T51A”与高感青枯病品种“T9230”配制杂交组合,接种鉴定其正反交Ｆ₁代及Ｆ₂代分离群体的青枯病发生情况。结果表明,T51A对青枯病的抗性属于细胞质遗传,受1对杂合基因加性控制。用64个EcoRＩ/ＭseＩ引物组合对“T51A”、“T9230”两个亲本及其Ｆ₂代抗病和感病基因池进行AFLP分析,共扩增出约4200条可分辨的带,其中2条为稳定的差异。用“T51A”和“T9230”杂交产生的Ｆ₂代分离群体对2个特异条带与目的基因的遗传连锁性进行分析,发现特异条带AAG/CAT与暂定名为RRS-342的抗青枯病基因紧密连锁,二者之间的遗传距离为6.7 cM。将AAG/CAT片段回收、克隆和测序,成功地将其转化为SCAR标记,可以更加方便地用于对番茄青枯病基因的标记辅助选择。      

Isodicentric Y chromosome: cytogenetic,molecular and clinical studies and review of the literature

Dicentrics are among the most common structural abnormalities of the human Y chromosome. Predicting the phenotypic consequences of different duplications and deletions of dicentric Y chromosomes is usually complicated by varying degrees of mosaicism (45,X cell lines), which may, in some cases, remain undetected. Molecular studies in patients with dicentric Y chromosomes have been few, and only two studies have attempted to determine the presence of SRY (the putative testis-determining factor gene). We report an 18-year-old female with short stature, amenorrhea, hirsutism, hypoplastic labia minora, and clitoromegaly who has a 45,X/46,X,idic(Y)(p11.32)/47,X,idic(Y)(p11.32),idic(Y) (p11.32) karyotype. Southern analysis using Y-specific probes (Y97, 2D6, 1F5, pY3.4) and polymerase chain reaction (PCR) analysis using primers for ZFY and SRY were positive for all loci tested, indicating that almost all of the Y chromosome was present. Our findings and an extensive review of the literature emphasize the importance of molecular analyses of abnormal Y chromosomes before any general conclusions can be reached concerning the relative effects of the Y-chromosome abnormality and mosaicism on sexual differentiation.     

PCR protocol to detect parental origin and hidden mosaicism inSex chromosome aneuploidies

In this study, we report an accurate method to determine the parental origin of sex chromosome aneuploidies or polyploidies and to detect low percentage mosaicisms. We have amplified by polymerase chain reaction (PCR) five polymorphic markers along the X chromosome (DXS1283E, DYS II, DMD49, AR and DXS52) and three markers along the Y chromosome (SRY, DYZ3 and DYZ1). False-negative results were discarded by the simultaneous amplification of Y markers and of internal controls. We have applied this protocol to a series of 14 Turner syndrome patients with a 45,X karyotype. We have detected sex chromosome mosaicisms in two patients. The parental origin of the syndrome has been determined in the other 12 patients.     

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.     

46,XY女性性反转患者SRY基因的两个新突变类型

Y染色体上的性别决定区域——SRY基因作为睾丸决定因子,可以调控男性性别发育过程。SRY基因是一种转录因子,属于带有高迁移率族蛋白家族,该家族成员包含能与DNA结合的HMG盒基序。已知SRY基因的缺失和点突变是造成XY女性性反转的病因之一。通过筛查10位中国46,XY女性性反转病人SRY基因的开放阅读框区域,探寻新的突变类型。用标准方法从外周血中抽提gDNA,通过聚合酶链式反应扩增SRY基因中部的609bp的DNA片段。扩增后的PCR片段被克隆到pUCm-T载体中,在ABI377-3自动测序仪上完成测序。运用限制性内切酶酶切分析的方法验证DNA测序的结果。结果表明,在两个患者的SRY基因中分别发现了新的核苷酸点突变,并都导致氨基酸替代。一个突变发生在SRY基因的5’端HMG盒外的核苷酸第113位腺嘌呤(A)被鸟嘌呤(G)取代,并导致谷氨酸被甘氨酸替换;另一个突变是第387位核苷酸发生T被A替换,该突变引起第129位的酪氨酸变成终止密码,她父亲的SRY序列被证明是正常的野生型。通过查询文献和人类基因突变数据库(HGMD),这两个突变都是以前未见报道过的新型SRY基因突变,并使因核苷酸替换引起SRY基因突变总数增加到45。     

棕色田鼠性别决定研究进展

哺乳动物性别决定方式属于雄性异配型性别决定, 依赖于Y染色体, SRY基因是性别决定中最重要的基因。文章报道了棕色田鼠指名亚种有Y染色体, 但是Y染色体上没有SRY基因, 性别决定不依赖于SRY基因, 排除了R-spondin 1基因是性别决定基因, 同时讨论了棕色田鼠指名亚种SRY基因缺失后可能的性别决定 机制。     

FISH and PCR analyses in three patients with 45,X/46,X,idic(Y) karyotype: clinical and pathologic spectrum

OBJECTIVE: To delineate the phenotypic spectrum (clinical and gonadal features) from patients with a 45,X/46,X,mar(Y) karyotype based upon of their clinical, histological, cytogenetic and molecular evaluation. SUBJECTS: Three patients with a 45,X/46,X,mar(Y) karyotype. METHODS: Clinical assessment, karyotyping, endocrine evaluation, FISH and PCR analyses of several Y-chromosome loci and direct sequencing of the SRY gene. RESULTS: The patients, two males and one female had varying degrees of impairment of sexual differentiation, with or without testis formation. One patient (reared as female and aged 17 years) had Turner syndrome with bilateral streak gonads. The second patient (2.4 years old) had ambiguous genitalia and presented a dysgenetic testis with a contralateral streak gonad. A third patient (26 years old) had bilateral dysgenetic testes (dysgenetic male pseudohermaphroditism). The ratio of 45,X vs. 46,X,+mar(Y) cells differed between patients and between different tissues. In each case the marker sexual chromosome was identified as a rearranged Y-chromosome (idic(Y)) using FISH and PCR analyses. In all cases the SRY gene was present in all tissues studied. No mutations were identified in this gene in any of the patients. CONCLUSIONS: The extent of male or female differentiation in these patients depends in part on the prevalence, time occurrence, and distribution of the 45,X cell line.     

Differences in recombination frequencies during female and male meioses of the sex chromosomes of the medaka, Oryzias latipes

In the medaka, Oryzias latipes, sex is determined chromosomally. The sex chromosomes differ from those of mammals in that the X and Y chromosomes are highly homologous. Using backcross panels for linkage analysis, we mapped 21 sequence tagged site (STS) markers on the sex chromosomes (linkage group 1). The genetic map of the sex chromosome was established using male and female meioses. The genetic length of the sex chromosome was shorter in male than in female meioses. The region where male recombination is suppressed is the region close to the sex-determining gene y, while female recombination was suppressed in both the telomeric regions. The restriction in recombination does not occur uniformly on the sex chromosome, as the genetic map distances of the markers are not proportional in male and female recombination. Thus, this observation seems to support the hypothesis that the heterogeneous sex chromosomes were derived from suppression of recombination between autosomal chromosomes. In two of the markers, Yc-2 and Casp6, which were expressed sequence-tagged (EST) sites, polymorphisms of both X and Y chromosomes were detected. The alleles of the X and Y chromosomes were also detected in O. curvinotus, a species related to the medaka. These markers could be used for genotyping the sex chromosomes in the medaka and other species, and could be used in other studies on sex chromosomes.     

Polymorphic karyotypes and sex chromosomes in the tufted deer (Elaphodus cephalophus): cytogenetic studies and analyses of sex chromosome-linked genes

Different diploid chromosome numbers have been reported for the tufted deer Elaphodus cephalophus (female, 2n = 46/47; male, 2n = 47/48) in earlier reports. In the present study, chromosomal analysis of seven tufted deer (5 male symbol, 2 female symbol) revealed that the karyotype of these animals contains 48 chromosomes, including a pair of large heteromorphic chromosomes in the male. C-banding revealed these chromosomes to be very rich in constitutive heterochromatin. Chromosome banding and PCR of sex chromosome-linked genes (SRY, ZFX, ZFY) performed on DOP-PCR products of single microdissected X and Y chromosomes confirmed that the large telocentric chromosome without secondary constriction is the X chromosome whereas the subtelocentric chromosome is the Y. The increased size of both, the X and Y chromosome, appears to be at least partially attributable to the presence of substantial amounts of heterochromatin.     

A rapid sex-identification test for the forest musk deer (Moschus berezovskii) based on the ZFX/ZFY gene

We describe a rapid sex-identification method for the forest musk deer (Moschus berezovskii) using PCR based on zinc-finger protein-encoding genes (ZFX/ZFY) located on the X and Y chromosomes. Fragments of the ZFX and ZFY genes were amplified and sequenced. The ZFX and ZFY fragments were identical in length and 94% similar in nucleotide sequence. Specific primers for forest musk deer sex identification were designed on the basis of sequence differences between ZFX and ZFY. All the primers were multiplexed in single-tube PCR. Both male and female forest musk deer showed amplification bands of 447 bp and 212 bp separated in agarose gels. A sex-specific 278-bp band was amplified only from males. These results show that testing by PCR for the presence of the 278-bp sequence is a rapid and reliable method for sex identification.     

Dynamic increase of a 45,X cell line in a patient with multicentric ring Y chromosomes

Because ring Y chromosomes are unstable during cell division most reported patients are mosaics, usually including a 45,X cell line. The phenotype varies from normal males or females with streak gonads to sexual ambiguities. We present here the case of a 23-year-old man who was referred at 11 years for growth delay. The GTG-banded karyotypes of lymphocytes revealed two cell lines: 46,X,dic r(Y) seen in 76% of the metaphases analyzed and 45,X (24%). Karyotypes and FISH were performed eight years later with the following probes: DYZ3 (Y centromere), SRY (sex-region of the Y), DYZ1 (Yq heterochromatin), CEPX/Y (X centromere and Yq heterochromatin), TelVysion Xp/Yp, Xq/Yq (X and Y subtelomeres), pan-telomeric, cosmid clones LLycos130G04 and LLycos37C09 (PARII), and BAC clone RP11-5C5 (Yq11.223). The results showed an increase in the 45,X cell line (60%) and a reduction in the 46,X,dic r(Y) cell line (36.4%). The use of Yq probes showed that the ring Y chromosome was dicentric. In addition, other ring Y structures were observed. The breakpoints occurred in proximal Yp11.32 or in Yp11.31 distal to SRY and in Yq12 distal to the PARII region. Therefore, most of the Y remained intact and all genes, with the exception of those in PARI, are present in double dosage in the dic r(Y). The level of mosaicism was important in defining the phenotype.