膜芯片检测A组轮状病毒的初步研究

建立表面带正电荷的尼龙膜为基片的基因芯片,采用RT-semi-nested PCR方法,对A组轮状病毒RNA实现高度扩增,并通过5'端带地高辛标记的上游引物实现扩增产物的标记.通过同膜芯片上探针的杂交和免疫显色,实现对A组轮状病毒的检测.结果表明,膜芯片对探针的固定效果、杂交吸脱和检测结果可靠,空白对照和阴性对照均为阴性,探针均显示为阳性信号,并且信号强弱与探针浓度关系不大,而主要与探针本身同互补链的结合相关.以上结果说明已经初步建立了快速检测A组轮状病毒的膜基因芯片检测技术.     

多功能悬浮点阵技术快速检测肠道致病菌的初步应用研究

目的建立以多功能悬浮点阵技术为基础的临床常见肠道致病菌的快速检测方法。方法以细菌16S rDNA基因保守区序列设计1对通用引物,采用不对称PCR扩增7种临床常见肠道致病菌标准菌株,多功能悬浮点阵技术对不同菌株的PCR产物进行检测以验证相应菌种探针的特异性,最后对48份粪便标本进行肠道致病菌高通量快速检测。结果 7种临床常见肠道致病标准菌株的不对称PCR得到了大量单链产物,其产物用多功能悬浮点阵技术的检测特异性为100%,48份粪便标本不对称PCR产物可与相应探针发生特异性结合,且在多功能悬浮点阵技术的相应检测信号大于阴性对照3倍以上,5种细菌的多功能悬浮点阵技术检测结果与培养鉴定结果符合率100%,48份标本PCR产物均与志贺菌属探针发生杂交反应(阳性率100%)。结论 16S rDNA可以作为细菌快速鉴定的靶序列,不对称PCR产物可以显著提高与悬浮芯片杂交检测的灵敏度,多功能悬浮点阵技术在鉴定细菌方面具有简单快速、高通量、高检出率等特点,可以作为细菌快速鉴定的一种新方法,但无法鉴别志贺菌属和大肠埃希菌属。     

检测PCR产物的新途径—非扩增性单链尾引物技术

PCR技术已成为核酸研究和临床实验室获取特异性基因序列的基本工具。随着它在基因诊断领域中的广泛应用,传统上用凝胶电泳分析PCR扩增产物的手段,已难以满是这一技术快速、敏感、特异的检测要求。近年来,许多以固相亲和检测为基础的非凝胶方法相继问世,但这些方法由于是通过固相表面的亲和介质与变性的单链PCR产物结合,再与标记探针杂交来实现检测,变性后扩增产物互补链的复性会由于竞争大大削弱检测探针的敏感性。本文介绍的单链尾引物技术,以一种在PCR引物中安置非扩增性单链尾的独特     

重要肠道病原菌多重PCR-基因芯片检测方法研究

目的:建立并初步评价一种针对重要肠道病原菌的多重PCR 基因芯片检测方法。方法：对筛选出的特异引物进行多重PCR优化,将引物分别按种属内混合和种属间混合的方案排查引物间的竞争性抑制现象,再将不同菌属的模板混合,用相对应的混合引物扩增,探寻高效特异的引物组合。分别掺入和不掺入荧光素,验证其对混合PCR反应的影响,并与芯片杂交,探寻多重PCR扩增效率对芯片杂交的影响。分析不同数量引物组合产生的杂交结果,筛选出无交叉反应的最优引物组合。结果:种属内引物混合均得到特异性扩增结果。种属间混合霍乱弧菌和空肠弯曲菌得到部分预期条带,随着混合引物数量的增加,交叉抑制现象也增多。杂交信号强度随多重PCR扩增效率的增加而增强。反应中掺入荧光素的扩增条带产量低于无荧光素的产物。可将35对混合引物拆成3个体系分别标记样品,以避免假阴性结果。结论:PCR反应中掺入荧光素降低扩增效率和杂交效率,但并不影响对杂交结果的判读和数据分析。基因芯片杂交信号强度取决于多重PCR的扩增效率。肠道病原菌多重PCR 基因芯片检测方法具有较高的特异性,混合PCR可以分别按照种属内和种属间的引物组合方案用于多病原的筛检。该基因芯片检测可以采用3个引物体系完成样品标记。     

用反向斑点杂交方法检测猪常见致病菌

目的:建立检测猪常见致病菌的反向斑点杂交方法。方法:将23S rRNA基因芯片用的针对12种细菌的25～30 mer探针加长到30～38 mer,2对通用引物序列不变。用地高辛标记下游引物,以尼龙膜为载体制备膜芯片,检验探针/膜杂交的特异性和敏感性;另外设计1条大肠杆菌K88基因探针、一段带K88探针的报告基因和1对报告基因的反向PCR引物,在PCR体系中增加封口的K88报告基因和反向引物对,被检样品扩增后进行膜杂交。结果:修改的13条探针与参考目标菌株在膜上成特异性杂交,对52个参考菌株和野外分离株的检测准确率为92%;膜杂交的敏感性与玻片芯片接近,最小检出量为100 fg DNA;在尼龙膜上增加K88探针,与3重PCR产物杂交,可以检测到大肠杆菌K88毒力基因。结论:建立的反向斑点杂交方法简便快速,检测成本低,可用于仪器设备不足的实验室,同时可以加入检测如大肠杆菌K88等致病基因,提高基于保守基因的芯片的诊断能力。     

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．     

副溶血性弧菌全基因组DNA芯片的研制和芯片质量的评价

摘要 目的 研制副溶血性弧菌全基因组芯片,建立芯片杂交方法,并对芯片质量进行评价。方法 利用副溶血性弧菌全基因组序列,挑选出4770条基因,PCR扩增各基因并将PCR产物纯化,点样制备芯片;设计了两个质控杂交组合,采用双色荧光杂交策略,对芯片质量进行评价;PCR方法验证部分芯片结果。结果 芯片杂交与理论预期结果以及PCR验证结果完全一致。结论 成功的研制了一批质量良好的副溶血性弧菌全基因组DNA芯片,并建立了基于DNA芯片的副溶血性弧菌比较基因组学技术平台,建立了一套系统的芯片数据分析的标准方法。     

应用寡核苷酸微阵列检测肺癌样品中的P53和K-ras基因点突变

对影响寡核苷酸微阵列检测点突变的敏感性和特异性的各种因素,如杂交液、杂交温度、标记引物浓度及其比例等,进行了研究。采用不对称PCR扩增有利于敏感性提高;多重不对称PCR不影响杂交的特异性,且敏感性有所增加。对30例肺癌标本进行寡核苷酸微阵列检测,发现12例标本发生了P53基因点突变,K-ras突变有5例。与测序结果相比,P53基因突变符合率达到80%。由于检测样本较少且检测位点不完全,因而未得到K-ras和P53基因突变与肿瘤的种类、病期及吸烟之间的明显相关性。     

副溶血性弧菌全基因组DNA芯片的研制和质量评价

【目的】研制副溶血性弧菌全基因组芯片,建立芯片杂交方法,并对芯片质量进行评价。【方法】利用副溶血性弧菌全基因组序列,挑选出4770条基因,PCR扩增各基因并将PCR产物纯化,点样制备芯片;设计了两个质控杂交组合,采用双色荧光杂交策略,对芯片质量进行评价;PCR方法验证部分芯片结果。【结果】芯片杂交与理论预期结果以及PCR验证结果完全一致。【结论】成功的研制了一批质量良好的副溶血性弧菌全基因组DNA芯片,并建立了基于DNA芯片的副溶血性弧菌比较基因组学技术平台,建立了一套系统的芯片数据分析的标准方法。     

小鼠细胞因子相关基因表达检测寡核苷酸芯片的制备及分析

生物芯片技术用于基因表达谱研究是近年来发展起来的一项新技术 ,该方法本质上是基于对一玻璃片或膜表面上固定的ｃＤＮＡ或寡核苷酸的分子杂交 ,这一新技术可同时测定成千上万个基因的作用方式 ,几周获得的信息用其它方法可能要几年才能得到 ,是以定量方式同时监测大量基因相对表达的强有力的新方法[1 ,2 ] 。国内外目前主要采用ｃＤＮＡ芯片进行基因表达的检测 ,芯片制备所用的ＤＮＡ探针一般为已知基因ｃＤＮＡ克隆的ＰＣＲ扩增产物或ＥＳＴ的扩增产物[3～ 8] 。对基因的表达检测来说 ,ｃＤＮＡ芯片技术是一条非常适用的检测方法 ,但在有…     

A Unique Protease Cleavage Site Predicted in the Spike Protein of the Novel Pneumonia Coronavirus (2019-nCoV) Potentially Related to Viral Transmissibility

正Dear Editor,In December 2019, a novel human coronavirus caused an epidemic of severe pneumonia(Coronavirus Disease 2019,COVID-19) in Wuhan, Hubei, China(Wu et al. 2020; Zhu et al. 2020). So far, this virus has spread to all areas of China and even to other countries. The epidemic has caused 67,102 confirmed infections with 1526 fatal cases     

Curcuminoids as inhibitors of thioredoxin reductase: A receptor based pharmacophore study with distance mapping of the active site

Curcumin is the yellow pigment of turmeric that interacts irreversibly forming an adduct with thioredoxin reductase (TrxR), an enzyme responsible for redox control of cell and defence against oxidative stress. Docking at both the active sites of TrxR was performed to compare the potency of three naturally occurring curcuminoids, namely curcumin, demethoxy curcumin and bis-demethoxy curcumin. Results show that active sites of TrxR occur at the junction of E and F chains. Volume and area of both cavities is predicted. It has been concluded by distance mapping of the most active conformations that Se atom of catalytic residue SeCYS498, is at a distance of 3.56 from C13 of demethoxy curcumin at the E chain active site, whereas C13 carbon atom forms adduct with Se atom of SeCys 498. We report that at least one methoxy group in curcuminoids is necessary for interation with catalytic residues of thioredoxin. Pharmacophore of both active sites of the TrxR receptor for curcumin and demethoxy curcumin molecules has been drawn and proposed for design and synthesis of most probable potent antiproliferative synthetic drugs.     

Comparative morphology of the carpel in the Liliaceae: Hewardieae, Petrosavieae, and Tricyrteae

The young pistils in the melanthioid tribes, Hewardieae, Petrosavieae and Tricyrteae, are uniformly tricarpellate and syncarpous. They lack raphide idioblasts. All are multiovulate, with bitegmic ovules. The Petrosavieae are marked by the presence of septal glands and incomplete syncarpy. Tepals and stamens adhere to the ovary in the Hewardieae and the Petrosavieae but not in the Tricyrteae. Two vascular bundles occur in the stamens of the Hewartlieae and Tricyrtis latifolia. Ventral bundles in the upper part of the ovary of the Hewardieae are continuous with compound septal bundles and placental bundles in the lower part. Putative ventral bundles occur in the alternate position in the Tricyrteae and putative placental bundles in the opposite. position in the Petrosavieae. The dichtomously branched stigma in each carpel of the Tricyrteae is supplied by a bifurcated dorsal bundle.     

Enterovirus 71 3C proteolytically processes the histone H3 N-terminal tail during infection

Highlights
1. The N-terminal tail of histone H3 is specifically cleaved during EV71 infection.
2. Viral protease 3C is identified as a protease responsible for proteolytically processing the N-terminal H3 tail.
3. Our finding reveals a new epigenetic regulatory mechanism for Enterovirus 71 in virus-host interactions.     

Detection of EBV and HHV6 in the Brain Tissue of Patients with Rasmussen’s Encephalitis

Rasmussen’s encephalitis (RE) is a rare pediatric neurological disorder, and the exact etiology is not clear. Viral infection may be involved in the pathogenesis of RE, but conflicting results have reported. In this study, we evaluated the expression of both Epstein-Barr virus (EBV) and human herpes virus (HHV) 6 antigens in brain sections from 30 patients with RE and 16 control individuals by immunohistochemistry. In the RE group, EBV and HHV6 antigens were detected in 56.7% (17/30) and 50% (15/30) of individuals, respectively. In contrast, no detectable EBV and HHV6 antigen expression was found in brain tissues of the control group. The co-expression of EBV and HHV6 was detected in 20.0% (6/30) of individuals. In particular, a 4-year-old boy had a typical clinical course, including a medical history of viral encephalitis, intractable epilepsy, and hemispheric atrophy. The co-expression of EBV and HHV6 was detected in neurons and astrocytes in the brain tissue, accompanied by a high frequency of CD8⁺ T cells. Our results suggest that EBV and HHV6 infection and the activation of CD8⁺ T cells are involved in the pathogenesis of RE.     

Perinatal Vertical Transmission of Chikungunya Virus in Ruili,a Town on the Border between China and Myanmar

正Dear Editor,Chikungunya virus (CHIKV), an arbovirus in the family of Togaviridae, genus Alphavirus, is transmitted by the A.aegyptii or A. albopictus mosquito, and causes disease in humans characterized by fever, rash, and arthralgia (Silva and Dermody 2017; Suhrbier 2019). It was first reported in 1953 in Tanzania, and caused only a few outbreaks and sporadic cases in Africa and Asia in last century. However, in the epidemic in 2004, CHIKV acquired mutations that conferred enhanced transmission by the A. albopictus mosquito(Schuffenecker et al. 2006). Since then, it has successively caused outbreaks in Africa, the Indian Ocean, South East Asia, the South America, and Europe (Zeller et al. 2016).     

Development of a Novel Reverse Transcription Loop-Mediated Isothermal Amplification Method for Rapid Detection of SARS-CoV-2

In conclusion, the novel visual RT-LAMP assay is a simple, rapid, and sensitive approach for detection of SARS-CoV-2, and it is ready for application in primary care and community hospitals or health care centers, and even patients' own houses in response to the current SARS-CoV-2 epidemic because the assay does not require sophisticated equipment and skilled personnel. Furthermore, it is also ready to be used in fields for screening samples from wild animals and environments to facilitate the identification of potential intermediate hosts that mediate the cross-species transmission of SARS-CoV-2 from bats to humans.