HPV病毒检测分型芯片的研制和优化

研制和优化寡核苷酸芯片以初步实现对多种常见HPV(Human papillomavirus)病毒的分型检测.应用生物学软件对四型常见HPV病毒(6、11、16、18型)的全基因组序列进行分析,设计具有型特异性、熔解温度(Tm)相近的～60 mer寡核苷酸探针,对玻片片基进行优化处理后,点样制备成寡核苷酸基因芯片.将含HPV全长基因序列的质粒作为阳性标准品,利用梯度限制性荧光标记技术对其进行荧光标记,标记好的样品与芯片杂交.结果显示HPV样品与相应的型特异性探针杂交有明显的荧光信号,而与阴性对照探针和空白对照探针没有杂交信号.通过对芯片片基处理和样品荧光标记方法的优化,可以提高芯片检测的杂交特异性和荧光信号强度.     

百合病毒的DNA芯片检测技术研究

根据已知的黄瓜花叶病毒,百合无症病毒、百合斑驳病毒基因核苷酸序列,设计引物和探针,制备寡核苷酸芯片。用Cy3标记核苷酸引物,不对称RT-PCR扩增产物与芯片上的寡核苷酸探针杂交,荧光扫描仪检测并分析信号。研究制备的基因芯片能够检测侵染百合的3种重要病毒核酸的特异性荧光信号,该项技术具有特异、灵敏、快速的优点。     

百合病毒的DNA芯片检测技术研究

根据已知的黄瓜花叶病毒,百合无症病毒、百合斑驳病毒基因核苷酸序列,设计引物和探针,制备寡核苷酸芯片.用Cy3标记核苷酸引物,不对称RT-PCR扩增产物与芯片上的寡核苷酸探针杂交,荧光扫描仪检测并分析信号.研究制备的基因芯片能够检测侵染百合的3种重要病毒核酸的特异性荧光信号,该项技术具有特异、灵敏、快速的优点.     

基因芯片技术检测重要人兽共患病病毒方法的建立

为了建立能对25种重要人兽共患病病毒进行筛查及鉴定用的基因芯片技术,本实验首先设计针对每种病毒的寡核苷酸探针并进行探针特异性的生物信息学验证.然后探索病毒核酸随机扩增方法,优化杂交动力学条件,建立本芯片标准的数据处理分析方法.最后用细胞培养的病毒和模拟临床标本验证芯片的敏感性与特异性．结果表明,锚定随机PCR扩增法适合于本芯片病毒核酸的扩增;芯片杂交前用0.25% NaBH4进行封闭,最优杂交条件为51 ℃,2 h及50%甲酰胺浓度;芯片具有较好的敏感性及检测特异性．初步结果表明,本实验所建立的基因芯片技术可应用于对25种重要人兽共患病病毒进行筛查及鉴定．     

近交系小鼠双色荧光正相杂交芯片技术体系的建立和优化

目的探讨采用单核苷酸多态性（SNP）检测方法-双色荧光正相杂交芯片技术对近交系小鼠遗传质量监测及相关影响因素。方法运用基于芯片的双色荧光正相杂交检测SNP技术,进行芯片杂交动力学研究,考察信号值（Cy3,Cy5）和ratio值（Cy5/Cy3）与PCR产物点样浓度、PCR产物长度和荧光标记探针长度之间的关系,研究PCR产物点样浓度、PCR产物长度和荧光标记探针长度对SNP分型的影响。结果采用正反标记实验后,Ratio值随着PCR产物点样浓度的增加呈稳定趋势;PCR双链产物长度对信号值影响比较大,点样时其长度不宜太长,最好不超过450 bp;随荧光标记探针长度的增加,基因分型能力明显下降,长度为15 bp最佳,长度超过20 bp时,已基本没有区分能力。结论PCR产物点样浓度、PCR产物长度和荧光标记探针长度是双色荧光正相杂交SNP分型系统的重要影响因素,采取适当的PCR产物点样浓度、PCR产物长度和荧光标记探针长度,并采用正反标记实验,可以取得稳定、准确的基因分型效果。为进一步进行近交系小鼠遗传质量监测的研究奠定基础。     

应用多重标记引物增强寡核苷酸芯片的荧光信号强度

寡核苷酸芯片技术是一种高通量发掘和采集生物信息的强大技术平台,目前已广泛应用于生物科学领域 . 为改善寡核苷酸芯片的分析性能,对影响芯片杂交结果的因素,如片基表面的化学处理、探针的长度、间隔臂的长度、杂交条件等,进行了深入的研究和优化 . 对寡核苷酸芯片而言,仍有待解决的问题是如何产生更强的荧光信号来改善其检测灵敏度 . 利用两种类型的多个荧光分子标记的引物,来增强二维寡核苷酸芯片平面上的荧光信号强度 . 两种引物分别命名为：多标记线性引物和多标记分支引物 . 通过增加标记在目标 DNA 片段上的荧光分子数,可以显著增强寡核苷酸芯片上相应捕获探针的信号强度 . 实验表明,使用多标记引物能将所用的寡核苷酸微阵列的检测限 ( 以能够检测的最低模板量计算 ) 降低至单荧光标记引物的 1/100 以下,多重标记技术是一种有效增强微型化探针矩阵检测灵敏度的信号放大方法 .     

动物遗传工程

94201 5用于诊断植物类病毒病的常规含生物素寡核苷酸诊断剂[俄]/Lebedeva,I.V.…∥Bioorg.Khim.-1993,19(9).一894N904[译自DBA,1994,13(4),94-02126] 通过使生物素标记的26-聚体寡核苷酸探针与病毒RNA位点(与马铃薯纺锤形块茎病毒和菊矮化病毒的位点相同)杂交,设计出用于诊断     

两种DNA探针杂交检测结核分支杆菌方法的研究

为改进结核杆菌DNA探针的特异性与实用性,研制了以生物素标记的两种对结核分支杆菌特异的DNA探针:一个5’端标记的20bp的寡核苷酸探针和一个采用PCR方法合成的188bp长链探针。两种探针分别与结核分支杆菌的全染色体DNA,以及基因组上IS6110序列的一段317bp的PCR扩增产物进行斑点杂交,以碱性磷酸酶(AP)催化的染色反应检测,测试了两个探针的敏感性和特异性。系统地比较研究了两种探针杂交检测条件:探针的浓度选择,杂交温度与洗膜温度的选择,以及杂交与洗膜温度对检测的敏感性与特异性的影响。寡核苷酸探针和188bp探针杂交检测纯化结核分支杆菌基因组DNA的敏感性分别为100ng与6ng,杂交检测PCR产物的敏感性分别是400pg与50pg。两探针的最佳杂交浓度均为40～160ng/ml,最佳杂交温度分别是42℃与68℃,最佳洗膜温度分别是60℃与60～68℃之间。两种探针均仅与结核分支杆菌及BCG有杂交信号,而与其它受试分支杆菌及非分支杆菌杂交结果都呈阴性。它们的特异性都很强,但188bp探针的敏感性约是寡核苷酸探针的7～16倍,而且188bp探针检测本底较低,是检测结核分支杆菌的较佳选择     

2型登革病毒检测基因芯片的研制

利用长片断PCR扩增含几乎全长的2型登革病毒cDNA,酶切PCR扩增产物,通过建立2型登革病毒。DNA文库获取芯片探针用点样仪将探针制备成2型登革病毒检测基因芯片,杂交时采用限制性显示(Restriction Display RD)技术标记样品,Scan Array芯片扫描仪检测杂交信号．杂交结果显示,样品和2型登革病毒基因芯片杂交的敏感性强、特异性高．     

3种菊花病毒/类病毒实时荧光定量RT-PCR检测体系的构建与准确性评价

菊花容易受到病毒感染而造成品质下降,目前国内对菊花病毒的检测主要根据外观表现或者定性PCR检测,无法准确判定病毒载量。为构建一种可同时用于检测菊花B病毒(Chrysanthemum virus B,CVB)、番茄不孕病毒(Tomato aspermy virus,TAV)和菊花褪绿斑驳类病毒(Chrysanthemum chloritic mottle viroid,CChMVd)的实时荧光定量RT-PCR检测方法,本研究分别以保守区域作为靶标设计相应的引物探针,通过优化扩增体系中CVB、TAV、CChMVd 3种病毒/类病毒探针浓度、引物浓度、Mg²⁺浓度、dNTPs浓度,摸索扩增程序中反转录时间、退火温度和扩增循环数,构建了一种可同时用于CVB、TAV、CChMVd的3重实时荧光定量RT-PCR检测体系,优化后的扩扩增体系中CVB、TAV和CChMVd的探针浓度分别为100 nmol/L、120 nmol/L和80 nmol/L,引物浓度分别为200 nmol/L、240 nmol/L和160 nmol/L,Mg²⁺浓度为3.0 mmol/L;dNTPs浓度200μmol/L;最适反转录时间为25 min,退火温度为60℃,循环数为40。敏感性实验结果表明,该反应体系对3种病毒/类病毒的敏感性为1.0×¹⁰3拷贝/mL,敏感性好;定量线性范围为1.0×¹⁰3拷贝/mL~1.0×¹⁰10拷贝/mL,线性范围宽;特异性好,对菊花矮化类病毒、烟草花叶病毒和黄瓜花叶病毒核酸检测结果为阴性;对1.0×¹⁰4拷贝/mL的低浓度参考品平行检测10次,定量结果lg值偏差(CV%)为4.81%,重复性好。在南京农业大学"中国菊花种质资源保存中心"基地随机选择菊花20株进行本研究试剂检测,检出6例CVB病毒株和4例TAV病毒株,其病毒载量为2.5×¹⁰4拷贝/mL~5.5×¹⁰7拷贝/mL,随机选择1株CVB病毒株定量PCR,产物进行TA克隆后经测序与NCBI Blast比对,其与MH678704.1的同源性为100%。因此,本研究建立了一种能同时检测CVB、TAV、CChMVd 3种菊花常见病毒/类病毒的灵敏、快速、可定量的检测方法。     

Highly sensitive fluorescent-labeled probes and glass slide hybridization for the detection of plant RNA viruses and a viroid

In this study, a modified method of the conventional RNA dot-blot hybridization was established, by replacing ~(32)p labels with CY5 labels and replacing nylon membranes with positive-charged glass slides, for detecting plant RNA viruses and a viroid. The modified RNA dot-blot hybridization method was named glass slide hybridization. The optimum efficiency of RNA binding onto the surfaces of activated glass slide was achieved using aminosilane-coated glass slide as a solid matrix and 5×saline sodium citrate (SSC) as a spotting solution. Using a CY5-labeled DNA probe prepared through PCR amplification, the optimized glass slide hybridization could detect as little as 1.71 pg of tobacco mosaic virus (TMV) RNA. The sensitivity of the modified method was four times that of dot-blot hybridization on nylon membrane with a ~(32)P-labeled probe. The absence of false positive within the genus Potyvirus [potato virus A, potato virus Y (PVY) and zucchini yellow mosaic virus] showed that this method was highly specific. Furthermore, potato spindle tuber viroid (PSTVd) was also detected specifically. A test of 40 field potato samples showed that this method was equivalent to the conventional dot-blot hybridization for detecting PVY and PSTVd. To our knowledge, this is the first report of using dot-blot hybridization on glass slides with fluorescent-labeled probes for detecting plant RNA viruses and a viroid.     

Array-based nano-amplification technique was applied in detection of hepatitis E virus

A rapid method for the detection of Hepatitis E Virus (HEV) was developed by utilizing nano-gold labeled oligonucleotide probes, silver stain enhancement and the microarray technique. The 5'-end -NH(2) modified oligonucleotide probes were immobilized on the surface of the chip base as the capture probe. The detection probe was made of the 3'-end -SH modified oligonucleotide probe and nano-gold colloid. The optimal concentrations of these two probes were determined. To test the detection sensitivity and specificity of this technique, a conservative fragment of the virus RNA was amplified by the RT-PCR/PCR one step amplification. The cDNA was hybridized with the capture probes and the detection probes on microarray. The detection signal was amplified by silver stain enhancement and could be identified by naked eyes.100 fM of amplicon could be detected out on the microarray. As the results, preparation of nano-gold was improved and faster. Development time also was shortened to 2 min. Thus, considering high efficiency, low cost, good specificity and high sensitivity, this technique is alternative for the detection of HEV.     

Identification of HCV-1b by Low-Density cDNA Microarray-Based Assay

A rapid and sensitive microarray assay for the detection of HCV-1b was developed in our laboratory and a cDNA fragment library for HCV-1b cDNA microarray probes was constructed. The full-length cDNAs of HCV-1b were digested with restriction endonuclease Sau3A I and the fragments were cloned with the pMD18-T vectors. Positive clones were isolated and identified by sequencing. The cDNA microarray was prepared by spotting the gene fragment on the surface of an amido-modified glass slide using the robotics system and samples were fluorescent labeled by the restriction display PCR (RD-PCR) technique, In the present study, modified protocols were used for probe selection and hybridization temperature. The detection of a microarray was validated by the hybridization and the sequence analysis. A total of 22 different specific gene fragments of HCV-1b ranging from 250 to 750 bp were isolated and sequenced, and these fragments were further used as probes in the microarray preparation. The diagnostic validity of the microarray method was evaluated after the washing and scanning process. The results of hybridization and sequence data analysis showed a significant specificity and sensitivity in the detection of HCV-1b RNA. The method of preparing microarray probes by construction of cDNA fragments library was effective, rapid, and simple; the optimized microarray was sensitive in the clinical detection of HCV-1b. The RD-PCR technique for the sample labeling was useful for significantly increasing the sensitivity of the assay. The cDNA microarray assay can be widely used in the clinical diagnosis of HCV-1b.     

Optimization Strategies for DNA Microarray-Based Detection of Bacteria with 16S rRNA-Targeting Oligonucleotide Probes

The usability of the DNA microarray format for the specific detection of bacteria based on their 16S rRNA genes was systematically evaluated with a model system composed of six environmental strains and 20 oligonucleotide probes. Parameters such as secondary structures of the target molecules and steric hindrance were investigated to better understand the mechanisms underlying a microarray hybridization reaction, with focus on their influence on the specificity of hybridization. With adequate hybridization conditions, false-positive signals could be almost completely prevented, resulting in clear data interpretation. Among 199 potential nonspecific hybridization events, only 1 false-positive signal was observed, whereas false-negative results were more common (17 of 41). Subsequent parameter analysis revealed that this was mainly an effect of reduced accessibility of probe binding sites caused by the secondary structures of the target molecules. False-negative results could be prevented and the overall signal intensities could be adjusted by introducing a new optimization strategy called directed application of capture oligonucleotides. The small number of false-positive signals in our data set is discussed, and a general optimization approach is suggested. Our results show that, compared to standard hybridization formats such as fluorescence in situ hybridization, a large number of oligonucleotide probes with different characteristics can be applied in parallel in a highly specific way without extensive experimental effort.     

Optimization strategies for DNA microarray-based detection of bacteria with 16S rRNA-targeting oligonucleotide probes

The usability of the DNA microarray format for the specific detection of bacteria based on their 16S rRNA genes was systematically evaluated with a model system composed of six environmental strains and 20 oligonucleotide probes. Parameters such as secondary structures of the target molecules and steric hindrance were investigated to better understand the mechanisms underlying a microarray hybridization reaction, with focus on their influence on the specificity of hybridization. With adequate hybridization conditions, false-positive signals could be almost completely prevented, resulting in clear data interpretation. Among 199 potential nonspecific hybridization events, only 1 false-positive signal was observed, whereas false-negative results were more common (17 of 41). Subsequent parameter analysis revealed that this was mainly an effect of reduced accessibility of probe binding sites caused by the secondary structures of the target molecules. False-negative results could be prevented and the overall signal intensities could be adjusted by introducing a new optimization strategy called directed application of capture oligonucleotides. The small number of false-positive signals in our data set is discussed, and a general optimization approach is suggested. Our results show that, compared to standard hybridization formats such as fluorescence in situ hybridization, a large number of oligonucleotide probes with different characteristics can be applied in parallel in a highly specific way without extensive experimental effort.     

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。     

Effects of target length on the hybridization efficiency and specificity of rRNA-based oligonucleotide microarrays

The effect of target size on microarray hybridization efficiencies and specificity was investigated using a set of 166 oligonucleotide probes targeting the 16S rRNA gene of Escherichia coli. The targets included unfragmented native rRNA, fragmented rRNA ( approximately 20 to 100 bp), PCR amplicons (93 to 1,480 bp), and three synthetic single-stranded DNA oligonucleotides (45 to 56 bp). Fluorescence intensities of probes hybridized with targets were categorized into classes I (81 to 100% relative to the control probe), II (61 to 80%), III (41 to 60%), IV (21 to 40%), V (6 to 20%), and VI (0 to 5%). Good hybridization efficiency was defined for those probes conferring intensities in classes I to IV; those in classes V and VI were regarded as weak and false-negative signals, respectively. Using unfragmented native rRNA, 13.9% of the probes had fluorescence intensities in classes I to IV, whereas the majority (57.8%) exhibited false-negative signals. Similar trends were observed for the 1,480-bp PCR amplicon (6.6% of the probes were in classes I to IV). In contrast, after hybridization of fragmented rRNA, the percentage of probes in classes I to IV rose to 83.1%. Likewise, when DNA target sizes were reduced from 1,480 bp to 45 bp, this percentage increased approximately 14-fold. Overall, microarray hybridization efficiencies and specificity were improved with fragmented rRNA (20 to 100 bp), short PCR amplicons (<150 bp), and synthetic targets (45 to 56 bp). Such an understanding is important to the application of DNA microarray technology in microbial community studies.