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.     

芦笋超雄株STS双分子标记的开发及应用北大核心CSCD

芦笋超雄株的获得是芦笋全雄系育种的关键,但是传统的全雄系材料需要通过杂交后代的分离情况来鉴定,极大增加了育种的周期和成本。因此,设计和开发芦笋超雄株植株性别鉴定标记具有重要的实践价值。本研究首先构建了968株芦笋两性株自交群体。在此基础上,根据Y染色体特异区基因SOFF和X染色体特异区基因WIP2/NTT设计开发了性别鉴定的STS双分子标记YSM和XSM。通过对单株性别鉴定结果表明,该STS双分子标记检测后出现293 bp单一条带的为超雄株,共有58株;出现245 bp单一条带的为雌株,共有550株;而出现245 bp和293 bp双条带的为雄株,共有360株,分别将293 bp和245 bp大小的条带进行测序后发现,两个序列和设计引物所用目的序列一致性均为100%。对开花后鉴定为雄株的418株单株逐一测交,对测交组合F_(1)的雌、雄性鉴定分析,发现有58个测交组合F_(1)全部为雄株,证明他们的父本为超雄株;有360个测交组合F_(1)出现雌雄株分离,证明他们的父本为雄株。这和STS分子标记鉴定结果完全一致,说明本研究的STS双分子标记可以准确鉴定芦笋雌株、雄株及超雄株性别。这为育种者进行芦笋全雄分子标记辅助育种提供了强有力的技术支撑。     

谭清苏铁性别连锁的RAPD和SCAR分子标记

利用RAPD(Random amplified polymorphic DNA)分子标记技术,寻找谭清苏铁（Cycas tanqingii）中与性别相关的分子标记,筛选了160个10bp的随机引物,产生了2500多个RAPD条带。只有引物S0465 (CCCCGGTAAC)产生了一条大约500bp的雌性特异RAPD标记,该分子标记出现在所有的供试雌性植株中,而所有的供试雄性植株都不具有该标记。对该特异片段进行了克隆和序列测定,并根据序列分析结果将RAPD标记转化为重复性和特异性更好的特异特征序列扩增区域（SCAR）分子标记,并命名为STQC-S465-483。分子标记的建立可用于谭清苏铁幼苗性别的早期鉴定,为谭清苏铁就地保护和迁地保护提供技术支持。     

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%。     

分子标记辅助选择不同甜瓜性别植株

运用A和G基因鉴定甜瓜的性别类型,为甜瓜其他性状的分子标记辅助育种提供方法。根据已发表的甜瓜CmACS-7(A基因)与WIP1+Gyno-hAT(G基因)基因结构设计PCR引物,对47个重组自交系群体家系及14份甜瓜材料进行检测验证。引物CmACS-7扩增产物在383 bp进行酶切,基因型为AA不能被酶切,扩增产物均被酶切的为基因型aa,酶切位点可分辨共显性基因型;针对WIP1+Gyno-hAT基因结构设计2对引物同时扩增,扩增条带197 bp和184 bp区别G(g)基因基因型。利用自主设计的引物可用于甜瓜苗期筛选雌雄异花同株、全雌系、雄全同株和完全花植株的分子标记辅助选择育种。     

戴冕鹤性别的分子鉴定

戴冕鹤Grus nigricllis为单态性鸟,很难通过外观和形态区分性别.本文采用非损伤性采样羽毛提取DNA,利用P2-P8引物对CHD基因进行特异性扩增,分别用HaeIII和Asp700I处理PCR产物,然后经过限制性片段长度多态性分析,HaeIII处理后的PCR产物,雄性出现2条带,雌性出现3条带;Asp700I处理后的PCR产物,雄性出现1条带,雌性出现3条带,表明可以准确鉴定戴冕鹤的性别.本文建立了从非损伤采样的羽毛提取DNA,利用PCR和限制性片段长度多态性准确鉴定戴冕鹤性别的方法,为人工繁殖戴冕鹤时合理配置雌雄比例、提高繁殖率奠定了基础.     

一种鉴别临床常见致病性葡萄球菌方法的建立与初步评价

目的建立一种鉴别临床常见致病性葡萄球菌的聚合酶链反应-限制性片段长度多态性（PCRRFLP）方法。方法采用经全自动微生物鉴定系统和分子生物学方法准确鉴定的金黄色葡萄球菌、表皮葡萄球菌、溶血葡萄球菌各3株,提取细菌DNA,PCR扩增tuf基因,扩增产物Alu I、Hinf I双酶切后进行琼脂糖凝胶电泳,分析不同葡萄球菌酶切后带型的差异。收集临床分离葡萄球菌142株,采用建立的PCRRFLP对其进行分类鉴别,随机选择分类鉴别的葡萄球菌各20株,PCR扩增16S r DNA,扩增产物测序,将结果与Gen Bank数据库进行比对,初步评价该方法的准确性。结果金黄色葡萄球菌,表皮葡萄球菌,溶血葡萄球菌均能扩增出长668 bp DNA片段。扩增产物经Alu I、Hinf I双酶切后电泳条带不同,金黄色葡萄球菌出现三条带（108 bp/192 bp/217 bp）,表皮葡萄球菌出现两条带（192 bp/304 bp）,溶血葡萄球菌出现两条带（192 bp/217 bp）。PCR-RFLP结果显示,142株葡萄球菌中金黄色葡葡球菌、表皮葡葡球菌和溶血葡葡球菌分别为67、29和46株。随机挑选的20株不同种葡萄球菌16S r DNA测序结果与Gen Bank数据库对应序列的相似性均〉99%,说明建立的PCR-RFLP方法能准确区分三种常见葡萄球菌。结论 PCRRFLP能准确鉴别临床常见的致病性葡萄球菌,为葡萄球菌病的分子诊断奠定了基础。     

鸵鸟性别鉴定的分子标记方法

鸵鸟(Struthiocamelus)属于平胸总目鸟类,雌雄鸵鸟在性成熟前外部形态相同,很难通过外观和形态来鉴定性别,给早期分群饲养造成了很大的困难。实验利用鸵鸟羽毛提取基因组DNA,之后利用EE0.6和CHD基因中2个引物组合对3对已知性别和9只未知性别鸵鸟的性别基因片段进行特异性扩增。结果显示,这对引物组合在雄性鸵鸟的DNA中未扩增出片段,在雌性鸵鸟DNA中扩增出1条片段,可以对鸵鸟的性别作出准确鉴定,从而解决幼雏期鸵鸟难以从外貌上区分其性别的问题。     

葎草性别相关SRAP分子标记的鉴定

葎草是一种研究雌雄异株植物性别分化分子机制的理想材料。本研究以葎草雌、雄基因池为模板,采用序列相关扩增多态性(SRAP)分子标记技术筛选与性别相关的分子标记,从256对引物组合中筛选出了50对可以稳定扩增出特异条带的引物组合,聚丙烯酰胺凝胶电泳结果显示,50对引物组合共扩增出671条带,247条呈现多态性,多态率为36.81%。后以葎草5个雄性单株、5个雌性单株为材料,采用琼脂糖凝胶电泳对引物组合me15+em11,me14+em16,me13+em12和me7+em10扩增结果再次进行验证,结果表明尽管扩增条带有所不同,但是雌、雄性特异条带是比较稳定的。对本研究中获得性别相关特异条带进行克隆、测序及染色体定位,将会有助于研究葎草性染色体演化的分子机制。     

银杏雌雄基因组DNA间的差异性分析

本研究应用RAPD技术,应用300个10bp随机单引物及200对随机双引物组合,检测了雌雄异株银杏基因组DNA的多态性。结果表明:雌雄基因组间具有极高的相似性,在检测到的3450个标记中,仅获得1个与银杏雄性基因组相关的RAPD标记。以该标记为探针,与雌雄银杏基因组DNA的Southern杂交分析,其杂交信号在两性之间表现为限制性片段长度多态性,该结果为寻找银杏早期性别鉴定的探针以及在细胞和分子水平进一步研究其性别问题奠定了基础。     

Development of male-specific SCAR marker in date palm (Phoenix dactylifera L.)

Genetics of control mechanisms that underlies sex differentiation in date palm is not known. Sex of the plants becomes known only at the time of first flowering, which takes around 5 years. In comparison, molecular diagnosis (if available/feasible) promises quick and reliable identification of sex types very early when plantlets are growing in seedbeds. To develop such an assay, genomic DNA from 45 individual plants (25 female and 20 male) belonging to different varieties of date palm was subjected to PCR amplification using 100 random amplified polymorphic DNA (RAPD) and 104 intersimple sequence repeat (ISSR) primers. Initially, two bulk genomic DNA samples (each made by pooling DNA from ten male and female plants, separately) were used. A primer showing sex-specific band in bulked samples was further used for amplification of the genomic DNA of the individual samples of that bulk. Only one RAPD primer, OPA-02, amplified a fragment of ~1.0 kb in all the individual samples of male genotypes, whereas this fragment was absent in all the female genotypes. This male-specific fragment was cloned and sequenced (GenBank accession no. JN123357), and a sequence-characterized amplified region (SCAR) primer pair was designed that amplified a 406-bp fragment in both female and male genotypes and a unique fragment of 354 bp in only male genotypes. The SCAR marker was further validated using 25 female and ten male date palm plants belonging to different varieties collected from different locations.     

A novel molecular genetic marker for gender determination of pigeons

The absence of conspicuous sexual dimorphism in pigeons often makes it difficult to determine their sex on the basis of external morphology. We identified a novel female-specific DNA marker in pigeons, presenting the possibility of pigeon gender determination using a PCR-based method. One-hundred and twenty random primers were used for RAPD fingerprinting in order to find any sex-specific fragments in pigeons. One of these primers, OPC-20, produced a female-specific band in the DNA fingerprints. This DNA fragment was isolated from the gel and inserted into a vector for nucleotide sequencing. A novel female-specific 732 bp sequence was obtained. A pair of primers (DoveOPC20F & R) was designed, based on the cloned sequence, for amplifying the female-specific band by PCR for pigeon gender determination. Sex-specific bands in the gel were observed in all females but not in males. The PCR products in the gel were then transferred onto nylon membranes and hybridized with a DIG-labeled probe of the cloned female-specific DNA fragment. Clear hybridization signals were found only in all of the female pigeons; the same result was obtained from dot blot hybridization. This demonstrates that the sex of pigeons can be accurately and rapidly identified by PCR.     

Isolation and characterization of a female-specific DNA marker in the giant freshwater prawn Macrobrachium rosenbergii

In this study, a female-specific DNA marker in the freshwater prawn Macrobrachium rosenbergii was identified through amplified fragment length polymorphism (AFLP). The AFLP-derived sequence-characterized amplified region (SCAR) marker was tested in over 200 individuals, giving reproducible sex identification. Further molecular characterization of the sex-marker's genomic region (～ 3 kb long) revealed the presence of tandem and inverted repeats. The ～ 3-kb sequence was identified both in male and female prawns, but with subtle differences: a deletion of 3 bp (present in female prawn but absent in male prawn) identified upstream of the SCAR marker sequence and two female-specific single-nucleotide polymorphisms, both indicating that male prawns are homozygous, whereas female prawns are heterozygous in this locus. Fluorescent in situ hybridization showed the ～ 3-kb sequence to be unique: to the best of our knowledge, this is the first report of a unique sex-specific sequence observed in situ in crustaceans. The sex-specific marker identified in M. rosenbergii may have considerable applied merit for crustacean culture in that it will enable the determination of genetic sex at early developmental stages when phenotypic differences are not identifiable.     

A highly reliable sex diagnostic PCR assay for mass screening of papaya seedlings

Female plants of several dioecious angiosperms are commercially valued for production of fruits or seeds, viz. papaya, nutmeg, pistachio, kiwi fruit and jojoba. To make the cultivation profitable it is necessary to grow more female than male plants. To discriminate between male and female plants, sex-specific molecular markers have been identified in a few dioecious species such as Silene and pistachio. However, accurate and convenient sex diagnostic methods for early sexing of seedlings are not available to date. For the first time, we report here a PCR-based Seedling Sex Diagnostic Assay (SSDA) specially designed for early sexing of papaya seedlings. We have developed a male-specific SCAR marker in papaya by cloning a male-specific RAPD (831 bp) fragment and designing longer primers. The potential of this SCAR marker is further exploited to develop a simplified and highly accurate sex diagnostic assay by (1) including an internal PCR control, (2) following a single-step DNA extraction procedure and (3) optimising the PCR conditions to simultaneously amplify male-specific and control bands from the crude leaf extract. This diagnostic approach would be of great commercial significance to papaya growers as well as to seed companies and plant nurseries for early identification of female seedlings of dioecious species. In principle, this experimental design could be easily applied to molecular analysis of any agriculturally important trait for which specific DNA probes could be identified and hence opens new avenues of research in the field of genetic diagnostics of plants.     

Sex identification of pigs using polymerase chain reaction amplification of the amelogenin gene

The amelogenin (AMEL) gene exists on both sex chromosomes of various mammalian species and the length and sequence of the noncoding regions differ between the two chromosome-specific alleles. Because both forms can be amplified using a single primer set, the use of AMEL in polymerase chain reaction (PCR)-based methods has facilitated sex identification in various mammalian species, including cattle, sheep and humans. In this study, we designed PCR primers to yield different-sized products from the AMEL genes on the X (AMELX) and Y (AMELY) chromosomes of pigs. PCR amplification of genomic DNA samples collected from various breeds of pigs (European breeds: Landrace, Large White, Duroc and Berkshire; Chinese breeds: Meishan and Jinhua and their crossbreeds) yielded the expected products. For all breeds, DNA from male pigs produced two bands (520 and 350 bp; AMELX and AMELY, respectively), whereas samples from female pigs generated only the 520 bp product. We then tested the use of PCR of AMEL for sex identification of in vitro-produced (IVP) porcine embryos sampled at 2 or 5 to 6 days after fertilization; germinal vesicle (GV)-stage oocytes and electroactivated embryos were used as controls. More than 88% of the GV-stage oocytes and electroactivated embryos yielded a single 520 bp single band and about 50% of the IVP embryos tested produced both bands. Our findings show that PCR analysis of the AMEL gene is reliable for sex identification of pigs and porcine embryos.     

应用多重PCR技术检测性器官异常患者的性别决定基因

采用针对人SRY基因及X与Y染色体同源序列的两对引物进行多重聚合酶链反应技术检测204例新生儿脐血DNA,男性均显示590bp、 355bp及280bp 3条扩增带,女性只有590bp1条扩增带,性别鉴定准确率为100%。又检测47例性器官异常患,13例社会性别为女性者只出现590bp扩增带,与核型性别结果一致。 34例社会性别为男性者中,有2例SRY基因检测结果阴性,只出现590bp带,核型为46,XX,证明这两例患者社会性别不相符,经病理证实后应诊断为女性假两性畸形。 Abstract:This investigation adapted multiplex PCR technique with two pairs of primer to determine sex according to the human SRY gene and X,Y chromosome analogical sequence.We detected bellybutton blood DNA from 204 newborns.Male revealed three bands:590bp,355bp and 280bp,and females only had one band which was 590bp,the accuracy of sex determination was 100%.47 sexual abnormal patients were tested.The results showed that 13 cases,whose social sex were female,had one 590bp band which consistent with their chromosome type sex.In the rest 34 cases,whose social sex were male,2cases showed,on the contrary,only one 590bp band and their chromosome type were 46,XX.This proved that the two patients did not consistent with their social sex,and pathological analysis showed that they were female pseud-hermaphroditism.     

Effects of sperm DNA damage on the levels of RAD51 and p53 proteins in zygotes and 2-cell embryos sired by golden hamsters without the major accessory sex glands

We previously reported that the male accessory sex gland (ASG) secretion is the main source of antioxidants to safeguard sperm genomic integrity and functional competence. Removal of all ASGs in the golden hamster can reduce male fertility by increasing embryo wastage. This study aims to investigate whether the oxidative DNA-damaged sperm from hamsters without all ASGs (TX) could successfully fertilize oocytes and to qualify the status of DNA repair by the expression of RAD51 and p53 proteins. Here we demonstrated a significantly higher DNA-base adduct formation (8-hydroxy-2'-deoxyguanosine) in sperm from TX males than those from sham-operated males. Comet assays demonstrated that all female pronuclei in both zygotes were intact, but single- and double-strand DNA damage was found in decondensed sperm in TX males only. DNA damage could also be detected in both nuclei of the TX 2-cell embryos. RAD51, a DNA repair enzyme, was found to be evenly distributed in the cytoplasm and nuclei in oocytes/zygotes, while at the 2-cell stage, a strong expression of p53 protein and a larger clear perinuclear area without RAD51 expression were found in TX embryos. In conclusion, we demonstrated for the first time DNA damage in decondensed sperm of zygotes and blastomeres of 2-cell stage embryos sired by TX males, resulting in the activation of DNA repair. Sperm DNA damage could induce the increase in p53 expression and the reduction of RAD51 expression in the TX 2-cell stage embryos.     

Identification of a sex-specific SCAR marker in dioecious Pandanus fascicularis L. (Pandanaceae).

Pandanus fascicularis L. is a dioecious plant native to South Asia with significant numbers in coastal areas. With the aim of distinguishing male genotypes from female genotypes early in the vegetative growth phase, the current study was initiated using molecular markers. Based on the principle of bulked segregant analysis, the sampled plants were separated into 2 bulks depending on their sex. Of the 89 random amplified polymorphic DNA and inter-simple sequence repeat markers used, one decamer (OPO-08) consistently amplified a 1263 bp band in the males that was absent in the females. Its DNA sequence did not exhibit significant similarity to previously characterized sequences, but the presence of mononucleotide and dinucleotide repeats suggested that it was a repeat-rich region. A sequence-characterized amplified region marker (MSSRF-01) designed for this fragment continued to amplify the specific allele in all the male plants. Southern hybridization performed using the sex-specific fragment as a probe yielded results consistent with those previously obtained by polymerase chain reaction. These results strongly suggest that MSSRF-01 is a male-specific molecular marker. With no information available on the presence of sex chromosomes in Pandanus, this marker can be used to differentiate the sexes.     

Development and validation of PCR-based assays for diagnosis of American cutaneous leishmaniasis and identificatio nof the parasite species

In this study, PCR assays targeting different Leishmania heat-shock protein 70 gene (hsp70) regions, producing fragments ranging in size from 230-390 bp were developed and evaluated to determine their potential as a tool for the specific molecular diagnosis of cutaneous leishmaniasis (CL). A total of 70 Leishmania strains were analysed, including seven reference strains (RS) and 63 previously typed strains. Analysis of the RS indicated a specific region of 234 bp in the hsp70 gene as a valid target that was highly sensitive for detection of Leishmania species DNA with capacity of distinguishing all analyzed species, after polymerase chain reaction-restriction fragment length polymorfism (PCR-RFLP). This PCR assay was compared with other PCR targets used for the molecular diagnosis of leishmaniasis: hsp70 (1400-bp region), internal transcribed spacer (ITS)1 and glucose-6-phosphate dehydrogenase (G6pd). A good agreement among the methods was observed concerning the Leishmania species identification. Moreover, to evaluate the potential for molecular diagnosis, we compared the PCR targets hsp70-234 bp, ITS1, G6pd and mkDNA using a panel of 99 DNA samples from tissue fragments collected from patients with confirmed CL. Both PCR-hsp70-234 bp and PCR-ITS1 detected Leishmania DNA in more than 70% of the samples. However, using hsp70-234 bp PCR-RFLP, identification of all of the Leishmania species associated with CL in Brazil can be achieved employing a simpler and cheaper electrophoresis protocol.