基因芯片技术检测3种肠道病原微生物方法的建立

目的:建立一种运用多重PCR和基因芯片技术检测和鉴定伤寒沙门氏菌、痢疾杆菌和单核细胞增生利斯特菌的方法。方法:分别选取伤寒沙门氏菌染色体ViaB区域中编码调控Vi抗原表达的基因(vipR)、痢疾杆菌编码侵袭质粒抗原H基因(ipaH)和单核细胞增生利斯特菌溶血素基因(hlyA)设计引物和探针,探针3'端进行氨基修饰,下游引物标记荧光素Cy3。在优化的PCR和杂交反应条件下,进行三重PCR扩增,产物与包括3种致病菌特异性探针的基因芯片杂交。在评价基因芯片的特异性和灵敏度之后,对临床样本进行检测。结果:只有3种目的致病菌的PCR产物在相应探针位置出现特异性信号,其他阴性细菌均无信号出现;3种致病菌的检测灵敏度均可达到103CFU/mL;检测30例临床样本的结果与常规细菌学培养结果一致。结论:所建立的可同时检测伤寒沙门氏菌、痢疾杆菌和单核细胞增生利斯特菌的基因芯片方法快速、准确,特异性高,重复性好,为3种肠道致病菌的快速检测和鉴定提供了新方法和新思路。     

从水稻Ac/Ds插入突变体扩增Ds侧翼序列的最适TAIL-PCR引物

温度非对称交互PCR(TAIL PCR)技术已广泛应用于从多种生物体系克隆侧翼于已知序列的DNA片段的分子操作中 ,并极大地促进了反向遗传学研究。但是 ,可能由于不同物种间基因组大小和序列存在显著差异 ,在采用该技术进行转座元件Ds水稻插入突变体鉴定过程中 ,常因TAIL PCR反应的稳定性差而影响突变体筛选效率。有鉴于此 ,根据Ds核苷酸序列设计了分别对应或互补于Ds插入元件两端长度不同的 12个特异引物组成 32个组合 ,在大量预试验基础上与 6个不同简并性 (32～256 )的随机简并引物分别组合进行TAIL PCR反应 ,较系统地研究了引物特性对以水稻基因组DNA为模板的TAIL PCR反应效率的影响。结果发现 ,第一反应采用长序列特异引物(36～ 4 0mer)可显著提高扩增特异性 ,随机简并引物的简并度对反应的影响显著。还选择出两个适于从水稻Ds插入突变体基因组高效扩增出Ds插入侧翼片段的最优特异引物组合和最适简并引物。应用本研究结果可显著地提高TAIL PCR技术筛选水稻插入突变体的效率     

痘病毒科不同病毒属特异的PCR检测方法的建立

目的:建立可准确、快速地鉴别诊断可感染人的不同属痘病毒的特异PCR方法。方法:设计针对正痘病毒属、副痘病毒属和传染性软疣病毒属的多对特异引物,并制备相应的DNA模板,针对不同的模板优化引物与反应条件,分别进行检测筛选,建立病毒属特异的单独与多重PCR方法。结果:单一模板的PCR扩增反应中,正痘病毒的检测敏感性可达101拷贝/μL(引物为OPEaL-F1880/OPEaL-R2057),副痘病毒的检测敏感性可达101拷贝/μL(引物为PP2/PP3),传染性软疣病毒的检测敏感性为100 pg/μL体系(引物为MCV1/MCV2);混合模板的PCR扩增反应中,各属特异的引物均可获得预期大小的特异片段。结论:我们建立的PCR诊断方法,可用于痘病毒科不同病毒属感染的实验室特异快速鉴别诊断。     

全基因组扩增策略在基因芯片分析SARS冠状病毒实验中的应用

针对SARS冠状病毒的分子生物学检测是控制SARS流行的关键环节。为评价全基因组扩增对SARS微量样本检测的影响 ,采用 6 mer随机引物反转录 ,用加接头的随机引物合成第二链 ,再以接头序列为引物扩增并掺入荧光标记 ,最后与带有 70 mer探针的基因芯片杂交。此非特异方法基本覆盖了样本中的全部DNA ,结果发现SARS冠状病毒全基因组的扩增效果对基因芯片杂交结果的均匀性有较大影响 ,PCR循环次数增多会导致扩增均匀性的降低。分析了不同的引物对全基因组扩增均匀性的影响 ,探讨了全基因组扩增策略的缺陷。     

绵羊胚胎性别鉴定试剂盒的研究

根据绵羊Y-染色体的特异序列和常染色序列分别设计了确定公羊Y-染色体特异序列的3对特异性引物和内标基因的4对特异性引物。单重PCR扩增绵羊基因组DNA,筛选出了3对Y-染色体特异引物和3对羊DNA特异内标引物。将不同的绵羊Y-染色体特异引物与内标引物组合,利用多重PCR扩增绵羊基因组DNA,筛选出了1个可用于羊早期胚胎性别鉴定的PCR引物组合:A0/C1。按照最优PCR扩增DNA条件配制了绵羊PCR性别鉴定试剂盒并成功应用于绵羊血液、已知性别的绵羊成纤维细胞和胚胎,表明本研究建立的体系完全可用于绵羊早期的胚胎性别鉴定。     

食源性致病菌多重PCR快速检测方法建立与应用

利用PCR技术,建立多组多重食源性致病菌PCR快速检测方法。设计受试菌特异性引物,反应体系中加入多对引物和多种DNA模板,采用正交试验优化PCR反应条件,进行特异性引物的PCR扩增。建立了多组多重食源性致病菌PCR快速检测方法,方法中所检测受试菌株和模拟样品均出现特异性扩增条带,结果与实际相符。所建立多组多重PCR快速检测体系符合设计要求,可以应用于食源性突发公共卫生事件的应急检测和日常样品检测工作。     

从水稻Ac/Ds插入突变体扩增Ds侧翼序列的最适TAIL-PCR引物

温度非对称交互PCR(TAIL-PCR)技术已广泛应用于从多种生物体系克隆侧翼于已知序列的DNA片段的分子操作中,并极大地促进了反向遗传学研究。但是,可能由于不同物种间基因组大小和序列存在显差异,在采用该技术进行转座元件Ds水稻插入突变体鉴定过程中,常因TAIL-PCR反应的稳定性差而影响突变体筛选效率。有鉴于此,根据Ds核苷酸序列设计了分别对应或互补于Ds插入元件两端长度不同的12个特异引物组成32个组合,在大量预试验基础上与6个不同简并性(32～256)的随机简并引物分别组合进行TAIL-PCR反应,较系统地研究了引物特性对以水稻基因组DNA为模板的TAIL-PCR反应效率的影响。结果发现,第一反应采用长序列特异引物(36～40mer)可显提高扩增特异性,随机简并引物的简并度对反应的影响显。还选择出两个适于从水稻Ds插入突变体基因组高效扩增出Ds插入侧翼片段的最优特异引物组合和最适简并引物。应用本研究结果可显地提高TAIL-PCR技术筛选水稻插入突变体的效率。     

啮齿动物螺杆菌多重PCR检测方法的建立

目的建立一种可同时检测肝、胆汁、啮齿类三种螺杆菌的多重PCR方法。方法根据已公布的肝、胆汁、啮齿类三种螺杆菌16SrRNA基因序列设计三对特异性引物进行多重PCR并对反应条件进行优化。结果三对引物能分别扩增出特异性的417 bp、364 bp、324 bp目的条带。最佳退火温度为52℃,镁离子浓度为2.0mmol/L,dNTP浓度为200μmol/L,引物浓度为0.625μmol/L。在此条件下多重PCR同时检测的肝、胆汁、啮齿类三种螺杆菌敏感度均为10 fg。结论本实验建立的多重PCR是一种敏感、特异、高效的方法,为同时检测啮齿动物中肝、胆汁、啮齿类三种螺杆菌奠定了良好的基础。     

穿山甲标本和甲片的DNA提取及PCR扩增

为验证经处理后的穿山甲(Manis spp.)标本和甲片是否可以用于种间分子鉴定标记的开发及个体识别工作,本文在样品的预处理、消化、提取后纯化等方面对传统提取方法进行了改进,分别从穿山甲剥制标本、干皮标本及甲片中提取总DNA;然后用Cyt b基因扩增通用引物、12S rRNA基因全序列扩增引物、RAPD引物及微卫星引物进行了PCR扩增,并对部分扩增结果进行了序列测定.结果表明,除剥制标本的脚底皮张组织外,其他样品基本都可以提取出DNA.以此为模板的PCR扩增中,2种线粒体基因引物扩增出明显目的条带,RAPD引物扩增出种间特异条带,测序结果可用于种间特异性引物及SCAR引物的开发;微卫星引物在甲片样品中扩增稳定,可用于个体识别工作.     

西瓜枯萎病菌的快速检测与鉴定

通过西瓜枯萎病菌与其他专化型枯萎病菌及瓜类几种重要病原菌的比较基因组分析,获得了西瓜枯萎病菌的基因组特异序列。在此基础上,设计出特异引物,筛选可扩增出西瓜枯萎病菌特异性DNA条带的引物。将特异性引物和尖孢镰刀菌专化型的通用引物W106R/W106S结合,建立双重PCR检测体系。该双重PCR检测体系可以在一次PCR反应中快速、准确的检测出西瓜枯萎病菌,为通过分子方法快速鉴定西瓜枯萎病菌提供技术支持。     

Multiplex amplification enabled by selective circularization of large sets of genomic DNA fragments

We present a method to specifically select large sets of DNA sequences for parallel amplification by PCR using target-specific oligonucleotide constructs, so-called selectors. The selectors are oligonucleotide duplexes with single-stranded target-complementary end-sequences that are linked by a general sequence motif. In the selection process, a pool of selectors is combined with denatured restriction digested DNA. Each selector hybridizes to its respective target, forming individual circular complexes that are covalently closed by enzymatic ligation. Non-circularized fragments are removed by exonucleolysis, enriching for the selected fragments. The general sequence that is introduced into the circularized fragments allows them to be amplified in parallel using a universal primer pair. The procedure avoids amplification artifacts associated with conventional multiplex PCR where two primers are used for each target, thereby reducing the number of amplification reactions needed for investigating large sets of DNA sequences. We demonstrate the specificity, reproducibility and flexibility of this process by performing a 96-plex amplification of an arbitrary set of specific DNA sequences, followed by hybridization to a cDNA microarray. Eighty-nine percent of the selectors generated PCR products that hybridized to the expected positions on the array, while little or no amplification artifacts were observed.     

Multiplex amplification of all coding sequences within 10 cancer genes by Gene-Collector

Herein we present Gene-Collector, a method for multiplex amplification of nucleic acids. The procedure has been employed to successfully amplify the coding sequence of 10 human cancer genes in one assay with uniform abundance of the final products. Amplification is initiated by a multiplex PCR in this case with 170 primer pairs. Each PCR product is then specifically circularized by ligation on a Collector probe capable of juxtapositioning only the perfectly matched cognate primer pairs. Any amplification artifacts typically associated with multiplex PCR derived from the use of many primer pairs such as false amplicons, primer-dimers etc. are not circularized and degraded by exonuclease treatment. Circular DNA molecules are then further enriched by randomly primed rolling circle replication. Amplification was successful for 90% of the targeted amplicons as seen by hybridization to a custom resequencing DNA micro-array. Real-time quantitative PCR revealed that 96% of the amplification products were all within 4-fold of the average abundance. Gene-Collector has utility for numerous applications such as high throughput resequencing, SNP analyses, and pathogen detection.     

Detection of bacterial pathogens in municipal wastewater using an oligonucleotide microarray and real-time quantitative PCR

As a first step toward building a comprehensive microarray, two low density DNA microarrays were constructed and evaluated for the accurate detection of wastewater pathogens. The first one involved the direct hybridization of wastewater microbial genomic DNA to the functional gene probes while the second involved PCR amplification of 23S ribosomal DNA. The genomic DNA microarray employed 10 functional genes as detection targets. Sensitivity of the microarray was determined to be approximately 1.0 microg of Esherichia coli genomic DNA, or 2 x 10(8) copies of the target gene, and only E. coli DNA was detected with the microarray assay using municipal raw sewage. Sensitivity of the microarray was enhanced approximately by 6 orders of magnitude when the target 23S rRNA gene sequences were PCR amplified with a novel universal primer set and allowed hybridization to 24 species-specific oligonucleotide probes. The minimum detection limit was estimated to be about 100 fg of E. coli genomic DNA or 1.4 x 10(2) copies of the 23S rRNA gene. The PCR amplified DNA microarray successfully detected multiple bacterial pathogens in wastewater. As a parallel study to verify efficiency of the DNA microarray, a real-time quantitative PCR assay was also developed based on the fluorescent TaqMan probes (Applied Biosystems).     

Detection and enumeration of aromatic oxygenase genes by multiplex and real-time PCR

Our abilities to detect and enumerate pollutant-biodegrading microorganisms in the environment are rapidly advancing with the development of molecular genetic techniques. Techniques based on multiplex and real-time PCR amplification of aromatic oxygenase genes were developed to detect and quantify aromatic catabolic pathways, respectively. PCR primer sets were identified for the large subunits of aromatic oxygenases from alignments of known gene sequences and tested with genetically well-characterized strains. In all, primer sets which allowed amplification of naphthalene dioxygenase, biphenyl dioxygenase, toluene dioxygenase, xylene monooxygenase, phenol monooxygenase, and ring-hydroxylating toluene monooxygenase genes were identified. For each primer set, the length of the observed amplification product matched the length predicted from published sequences, and specificity was confirmed by hybridization. Primer sets were grouped according to the annealing temperature for multiplex PCR permitting simultaneous detection of various genotypes responsible for aromatic hydrocarbon biodegradation. Real-time PCR using SYBR green I was employed with the individual primer sets to determine the gene copy number. Optimum polymerization temperatures for real-time PCR were determined on the basis of the observed melting temperatures of the desired products. When a polymerization temperature of 4 to 5 degrees C below the melting temperature was used, background fluorescence signals were greatly reduced, allowing detection limits of 2 x 10(2) copies per reaction mixture. Improved in situ microbial characterization will provide more accurate assessment of pollutant biodegradation, enhance studies of the ecology of contaminated sites, and facilitate assessment of the impact of remediation technologies on indigenous microbial populations.     

Microarray Multiplex Assay for the Simultaneous Detection and Discrimination of Influenza A and Influenza B Viruses

In this study, we present a microarray approach for the typing of influenza A and B viruses, and the subtyping of H1 and H3 subtypes. We designed four pairs of specific multiplex RT-PCR primers and eight specific oligonucleotide probes and prepared microarrays to identify the specific subtype of influenza virus. Through amplification and fluorescent marking of the multiplex RT-PCR products on the M gene of influenza A and B viruses and the HA gene of subtypes H1 and H3, the PCR products were hybridized with the microarray, and the results were analyzed using a microarray scanner. The results demonstrate that the chip developed by our research institute can detect influenza A and B viruses specifically and identify the subtypes H1 and H3 at a minimum concentration of 1 × 10² copies/μL of viral RNA. We tested 35 clinical samples and our results were identical to other fluorescent methods. The microarray approach developed in this study provides a reliable method for the monitoring and testing of seasonal influenza.     

Detection and Enumeration of Aromatic Oxygenase Genes by Multiplex and Real-Time PCR

Our abilities to detect and enumerate pollutant-biodegrading microorganisms in the environment are rapidly advancing with the development of molecular genetic techniques. Techniques based on multiplex and real-time PCR amplification of aromatic oxygenase genes were developed to detect and quantify aromatic catabolic pathways, respectively. PCR primer sets were identified for the large subunits of aromatic oxygenases from alignments of known gene sequences and tested with genetically well-characterized strains. In all, primer sets which allowed amplification of naphthalene dioxygenase, biphenyl dioxygenase, toluene dioxygenase, xylene monooxygenase, phenol monooxygenase, and ring-hydroxylating toluene monooxygenase genes were identified. For each primer set, the length of the observed amplification product matched the length predicted from published sequences, and specificity was confirmed by hybridization. Primer sets were grouped according to the annealing temperature for multiplex PCR permitting simultaneous detection of various genotypes responsible for aromatic hydrocarbon biodegradation. Real-time PCR using SYBR green I was employed with the individual primer sets to determine the gene copy number. Optimum polymerization temperatures for real-time PCR were determined on the basis of the observed melting temperatures of the desired products. When a polymerization temperature of 4 to 5°C below the melting temperature was used, background fluorescence signals were greatly reduced, allowing detection limits of 2 × 10² copies per reaction mixture. Improved in situ microbial characterization will provide more accurate assessment of pollutant biodegradation, enhance studies of the ecology of contaminated sites, and facilitate assessment of the impact of remediation technologies on indigenous microbial populations.     

Enhanced PCR amplification of VNTR locus D1S80 using peptide nucleic acid (PNA).

Use of the polymerase chain reaction (PCR) to amplify variable numbers of tandem repeat (VNTR) loci has become widely used in genetic typing. Unfortunately, preferential amplification of small allelic products relative to large allelic products may result in incorrect or ambiguous typing in a heterozygous sample. The mechanism for preferential amplification has not been elucidated. Recently, PNA oligomers (peptide nucleic acids) have been used to detect single base mutations through PCR clamping. PNA is a DNA mimic that exhibits several unique hybridization characteristics. In this report we present a new application of PNA which exploits its unique properties to provide enhanced amplification. Rather than clamping the PCR, PNA is used to block the template making it unavailable for interstrand and intrastrand interactions while allowing polymerase to displace the PNA molecules and extend the primer to completion. Preferential amplification is reduced and overall efficiency is enhanced.     

Fabrication and optimization of the multiplex PCR-based oligonucleotide microarray for detection of Neisseria gonorrhoeae, Chlamydia trachomatis and Ureaplasma urealyticum

To detect and identify the pathogens responsible for sexually transmitted diseases (STDs) at the early stage of infection and with a high throughput, a new microarray with a bifunctional probe modification was prepared using Neisseria gonorrhoeae, Chlamydia trachomatis and Ureaplasma urealyticum as a model system. During the fabrication of the microarray, an asymmetric fluorescently labeled multiplex PCR was introduced. The fabrication optimization proved that the best hybridization results would be obtained by spotting N. gonorrhoeae probe at a position near the side of the fluorescently labeled reverse primer within its target gene and spotting each probe at a concentration of 50 microM onto the aldehyde-derived glass slides using spotting solution S1 and using hybridization solution H2 for hybridization. The probes designed by our laboratory could specifically discriminate the pathogens of N. gonorrhoeae, C. trachomatis and U. urealyticum in the presence of the internal control on the microarray simultaneously and separately. By incorporating the key features of DNA microarray with those of multiplex PCR, the microarray provides a fast high throughput platform for multiple infections and multiple samples to be detected and identified simultaneously for STD clinics. It also provides a new platform for other diseases and gene mutations to be detected and identified at a high throughput.