南京地区2012～2013年G9型轮状病毒VP7基因特征的分析

A组轮状病毒是引起成人和婴幼儿急性腹泻的主要病原。了解轮状病毒流行株的型别,对主要中和抗原VP7的编码基因进行遗传变异分析,可为当地轮状病毒疫苗的应用和开发提供指导。我们对2012年10月至2013年12月南京地区908例腹泻门诊患者的粪便标本进行轮状病毒检测,采用RT-PCR方法对随机抽取的50份阳性标本进行G分型,并对其中19份G9型轮状病毒的VP7基因序列测序分析。结果发现轮状病毒阳性率11.34%(103/908),其中以G9型为主,占78.0%(39/50),其次是G2、G1和G3型。对G9型轮状病毒VP7基因核苷酸序列进行分析,显示主要分为G9-VI亚型和G9-III亚型,以G9-VI亚型为主,且属于中国和日本G9型轮状病毒亚簇,部分毒株在A、B、C、F四个中和抗原表位中有变异,这可能有助于G9型轮状病毒的流行,值得引起注意。     

引起产科新生儿腹泻暴发的轮状病毒株VP4 VP7编码基因与其毒力关系的探讨

克隆并测定了引起产科新生儿腹泻暴发的P2[6]、G4型轮状病毒(BN株)VP4的VP8片段和VP7编码基因的核苷酸序列,并据此推导出其氨基酸序列。与相应标准株和地方株(包括有毒株和无毒株)比较的结果表明,所测VP8序列与相同型别(P2[6])的标准株M37(无毒株)和ST3(无毒株)、地方株N16(无毒株)和VE7156(有毒株)之间的同源性为92.8％～98.6％,胰酶作用位点各毒株间相同;位于aa49、aa50、aa52、aa53、aa78处的氨基酸在有毒株与无毒株间(包括BN株)不同,但分别保守。VP7基因与同型(G4)标准株ST3(A亚型/无毒株)和VA70(B亚型/有毒株)、意大利地方株PV5249(A亚型/有毒株)和北京地方株CR117(有毒株)、同型猪有毒株Gott之间的同源性为91.4％～97.8％,其中与A亚型的同源性为95.5％～96.3％,而与B亚型的同源性为91.4％,提示VP7为G4A亚型,位于aa38、aa78、aa145、aa238位点的氨基酸在有毒株与无毒株之间不同,但分别保守。分析了虽为P2[6]型却反常地引起新生儿腹泻暴发毒株(BN)的VP8与VP7基因的变异情况,并对轮状病毒毒力与VP4、VP7基因变异的相互关系进行了讨论,为慎重确定轮状病毒疫苗候选毒株提供理论依据。     

G5型人A组轮状病毒LL36755株的VP4、VP6和NSP4编码基因的分子特征

最近在亚洲首次发现并报道了感染人的G5型人A组轮状病毒LL36755株,为进一步探讨其进化来源,克隆了G5型人A组轮状病毒LL36755株的VP4、VP6、NSP4编码基因,并分析其基因序列的分子特征。结果发现卢龙株LL36755为罕见的G5P[6]型,其VP6的亚群为SGⅡ型,NSP4的基因型为B型。系统进化树分析表明,卢龙株LL36755的VP7、VP4编码基因与猪来源的毒株关系密切,而VP6、NSP4编码基因与人来源的毒株紧密相联系。可以推断新的人腹泻A组轮状病毒LL36755株是猪的VP7,VP4编码基因与人的VP6,NSP4编码基因的自然重组;而且该毒株不是G5的原型,很可能是人类轮状病毒与猪轮状病毒毒株的自然重组后逐步进化而来。     

2018–2020年人轮状病毒锦州地方株VP4及VP7基因特征

【背景】人A组轮状病毒(Rotavirus Group A,RVA)是婴幼儿胃肠炎的主要病原体及发展中国家婴幼儿死亡的重要原因,目前无特效药物治疗,疫苗预防是唯一可行的预防感染方法。外衣壳蛋白VP7和VP4是疫苗设计的主要靶点,针对该基因加强RVA地方株分子流行病学监测十分必要。【目的】对锦州地方流行RVA株VP7和VP4基因进行型别鉴定和序列特征分析。【方法】收集锦州地区2018-2020年RVA感染腹泻患儿的粪便标本,提取病毒RNA,通过RT-PCR扩增VP7、VP4基因片段并测序,得到7株RVA VP7和VP4序列。使用在线基因分型工具Rota C V2.0对测序结果进行分型分析。应用BLAST、DNAStar、MEGA X、Bio Edit等生物软件与临床流行株及疫苗株进行系统发育分析及氨基酸序列比对分析。【结果】分型结果表明7株锦州地方株均为G9P[8]型,系统发育分析证实其VP7和VP4基因分别属于G9-Ⅵ和P[8]-3谱系,核苷酸序列相似性分别为99.32%-100%与99.41%-100%。JZ株VP7与疫苗株Rotavac和Rotasiil相比,在抗原表位区7-1a、7-1b、7-2中分别存在4个和3个氨基酸替换。JZ株VP4与疫苗株Rotarix和Rota Teq VP4氨基酸序列相比,发现7个和4个氨基酸替换,位于抗原表位区8-1和8-3。【结论】2018-2020年在辽宁锦州地区检测到7株G9P[8]型RVA株,VP7和VP4序列相似性高于99%,G9P[8]型可能是辽宁省锦州地区2018-2020年婴幼儿轮状病毒腹泻的主要流行基因型之一。与同基因型疫苗株比较,位于JZ株VP7和VP4抗原表位区的氨基酸位点差异对于野毒株免疫逃逸机制的研究具有意义。     

2018-2019年福州腹泻住院儿童A组轮状病毒全基因组分析

了解2018-2019年福州市五岁以下腹泻住院儿童标本中A组轮状病毒(RVA)基因组特征.通过反转录-聚合酶链式反应(RT-PCR)对49份RVA阳性标本进行核酸扩增,对扩增到的40份标本进行全基因组二代测序,获得G1P[8]型RVA毒株7株,G9P[8]型RVA毒株33株.根据VP7节段分型,40株RVA毒株中有30株G9-Ⅵ亚型、3株G9-Ⅲ亚型和7株G1-Ⅰ亚型;根据VP4节段分型,40株RVA毒株均属于P[8]-3亚型.全基因组核苷酸序列分析表明,除了VP7节段外,序列差异比较大的有NSP4和NSP1两个节段.本研究获得11株G9P[8]型Waa-ike株(G9-P[8]-I1-R1-C1-M1-A1-N1-T1-E1-H1),22株NSP4节段重配的G9P[8]-E2株(G9-P[8]-I1-R1-C1-M1-A1-N1-T1-E2-H1),在测序的33株G9P[8]型RVA毒株中G9P[8]-E2重配株占66.7％.7株G1P[8]型RVA毒株均为Wa-like株.研究结果表明,2018-2019年福州地区流行的RVA毒株中G9P[8]-E2重配株已经成为优势株,为了更全面了解福州地区RVA毒株的遗传变异情况,后续还需加大标本量持续进行监测.     

我国1998～1999年流行的婴幼儿腹泻轮状病毒的分型研究

轮状病毒是世界范围内引起婴幼儿腹泻的主要病原。根据病毒外壳蛋白VP4和VP7抗原性的不同可区分为不同型：P（VP4,protease sensitive）型和G（VP7,glycoprotein）型。1998－1999年在中国8个城市（长春、秦皇岛、北京、杭州、福州、广州、成都、昆明）采集了急性腹泻患儿的1093份非细菌性腹泻粪便标本,先进行A组轮状病毒（HRV）的筛选,其中阳性标本433份（39.6％）,电泳型长型占优势（96％）。对HRV标本,再利用血清型特异的MAbELISA和／或RT－PCR进行G分型。结果表明,在1998－1999年,在上述8城市非细菌性腹泻行季节,以HRV G1型为主要流行株,占阳性的83.4％,其次为G3（12.0%）、G4（3.5%)和G2(3.2%）。此外,有3份（0.7％）HRV标本未能分型,12（2.8％）份标本为混合感染,还结合1982－1996年全国12个地区1382份HRV标本的分型资料,分析了我国HVR G血清型的流行规律。实验中又抽样选取了124份GHRV标本,用RT－PCR进行P分型,其中P[8]型76份（61.3％）,P[4]型14份（11.3%）,P[6]型12份(9.7%),P[9]型8份(6.4%)。另外15份（12.1%)未能分出P型,有待进一步检定,实验中HRV分离株除了觉见的P[8]G1(51.4%)、P[4]G2(4.6%)毒株外,还检测到P[8]G3(11.0%)、P[8]G4(6.4%) 和其它较少见的病毒型。以上结果为我国轮状病毒疫苗的应用和开发提供了较系统、清晰的流行病学背景资料。     

胶体金法与RT-PCR法测定A群轮状病毒及G血清型分型

目的了解婴幼儿A群轮状病毒腹泻的流行病学特征。方法收集浙江省苍南县人民医院2009年1-12月份的婴幼儿腹泻粪便标本,采用胶体金免疫层析法和逆转录-聚合酶链反应法进行轮状病毒抗原检测和血清型分型,分析G血清型分型。结果 828份婴幼儿腹泻粪便轮状病毒阳性率为33.45%。在轮状病毒腹泻患儿中,1岁以内占49.82%,2岁以内占89.89%。本地区轮状病毒腹泻呈现季节高峰,11月至次年1月为轮状病毒腹泻流行期。毒株分型显示G3型为流行优势株（51.6%）,其次是G1型（26.6%）;另有13.7%为混合感染,包括G1＋G3型（10.5%）、G2＋G3型（2.4%）和G1＋G9型（0.8%）。结论 2009年浙江省苍南县婴幼儿轮状病毒腹泻的主要血清型是G3和G1,G3为优势毒株。 更多还原     

婴幼儿腹泻A群轮状病毒G和P的基因分型研究

目的研究浙江萧山医院婴幼儿童腹泻标本中人轮状病毒（Human Rotavims）毒株的感染情况及G和P基因型流行特点。方法收集该院2009年8月至2010年8月腹泻儿童15233份粪便标本采用酶联免疫吸附试验、逆转录-巢式聚合酶链反应进行轮状病毒病原检测,将128份阳性标本进行VP7和VP4基本分型。结果15233份婴幼儿腹泻标本中有2706份标本为轮状病毒阳性,阳性率17．8％;男孩和女孩检出率差异无统计学意义,以6-12月龄段检出率最高;对128份阳性标本进行G血清分型和P基因分型,G1型53份（41．4％）、G3型38份（29．7％）、G1G3型17份（13．3％）、G未分型20份（15．6％）;P[8]型72份（56．3％）、P[4]型16份（12．5％）、P[8]P[4]型3份（2．3％）、P未分型37份（28．9％）,G血清型和P基因型的组合以G1P[8]为主,占29．7％（38／128）。结论浙江萧山医院A群轮状病毒G血清以G1型为主,其次为G3型,P基因型以P[8]型为主。     

腹泻犬中细小病毒携带情况以及VP2基因进化分析

为了解四川省部分地区腹泻犬中细小病毒的感染情况以及VP2基因的遗传变异情况。从四川省部分地区收集了50例疑似CPV感染的腹泻犬粪便,对标本采用PCR扩增VP2,并对VP2基因全序列进行测序分析。PCR检测阳性标本19份。序列分析显示,15份扩增出VP2基因全序列标本均为CPV-2a型,聚类分析显示全部序列聚类在同一分支,本次研究的四川省部分地区流行的CPV均为CPV-2a型。可推测目前四川省部分地区所常见的CPV流行株依然以CPV-2a型为主。本次试验所扩增的15份CPV阳性标本与国内外传统毒株有着极高的同源性,提示目前四川省部分地区CPV还未出现重大的变异情况。     

云南蝙蝠轮状病毒的分离与鉴定

蝙蝠是携带人兽共患病毒最多的一种哺乳动物,调查蝙蝠携带病毒的病原生态学本底对防范蝙蝠病毒威胁人类健康具有重要意义。本研究采集云南省部分地区蝙蝠进行病毒宏基因组学分析,在一组食虫蝙蝠样品中发现了A群轮状病毒(Group A rotaviruses,RVA)序列,经过进一步RT-PCR筛查验证及病毒的分离鉴定,最终从勐远县的1只三叶蹄蝠中分离出一株轮状病毒。扩增该毒株的VP7与VP4基因进行分型与系统进化分析,结果表明其VP7基因为G3型,与来自阿根廷的1株马轮状病毒的同源性最高,为93%;其VP4基因为P[10]型,与来自泰国的1株人轮状病毒同源性最高,为94.8%。通过与本实验室之前分离的首株蝙蝠G3P[3]型轮状病毒MSLH14的比较,确定该毒株为一株新的蝙蝠轮状病毒,命名为RVA/Bat-tc/MYAS33/2013/G3P[10],简称MYAS33。本研究结果进一步证明了蝙蝠轮状病毒的多样性,突显了蝙蝠作为轮状病毒潜在宿主的重要性。     

表达轮状病毒G2和G3型vp7基因重组腺病毒的免疫效果

为探索以非复制型腺病毒为表达载体的多价轮状病毒(Rotavirus,RV)基因工程疫苗的可行性,在前期工作的基础上,对表达我国G2和G3型RV流行毒株vp7基因的重组腺病毒的免疫效果进行了研究。分别用表达G2和G3型vp7基因的重组腺病毒rvAdG2VP7、rvAdG3VP7经滴鼻和灌胃两种途径免疫Balb/c小鼠,对免疫后小鼠的血清抗体、黏膜抗体和相关的细胞因子水平进行了检测和比较。结果表明,用表达G2和G3型vp7基因的重组腺病毒经滴鼻和灌胃两种途径免疫小鼠后,均可诱导机体产生较强的RV特异性免疫反应,包括体液免疫、细胞免疫和黏膜免疫,并能产生中和抗体。但免疫反应以Th2类为主,Th1类反应也占有相当的比例。本研究为新型RV基因工程疫苗的深入研究奠定了基础。     

Molecular characterization of two strains of porcine group C rotavirus

Group C rotaviruses are an important cause of acute gastroenteritis in humans and animals. Fecal samples were collected from a porcine herd in July, 2009. Group C rotavirus RNA was detected using RT-PCR for the VP6 gene. The identified strain was further characterized by sequencing and phylogenetic analysis of the partial VP4, and complete VP6 and VP7 gene sequences. The partial VP4 and complete VP6 gene sequences of the CUK-5 strain were most closely related to those of the CUK-6 strain of group C rotaviruses. Phylogenetic analysis of the VP7 gene of the 2 strains (CUK-5 and CUK-6) and reference strains of group G rotavirus by the neighbor-joining method also confirmed that CUK-5 and CUK-6 belonged to type G5 and G1 strains, respectively. This study provides useful data for the prediction of newly appearing variants of porcine group C rotaviruses in neighboring countries through comparisons with GCRVs and fundamental research for vaccine development.     

轮状病毒基因重配株血清型鉴定方法的研究

Ａ组轮状病毒中根据基因９的不同目前至少已发现有１３个不同Ｇ血清型,其中能引起人类致病的有Ｇ１－Ｇ４,Ｇ８,Ｇ９和Ｇ１２型。建立可靠的血清型鉴定技术对于轮状病毒疫苗的研制和分子流行病学的研究具有重要意义。本文首次报导了一种鉴定轮状病毒Ｇ血清型的新方法,利用已知有关轮状病毒ＶＰ７基因的序列资料,设计合成了一套鉴定轮状病毒Ｇ血清型的寡核苷酸探针,利用地高辛标记上述探针。待检品经反转录ＰＣＲ扩增后与上述一套寡核苷酸探针分别进行杂交得以确定其血清型。这一方法与目前常用的套式ＰＣＲ方法相比更适合于大量样品的操作而且结果可靠。用这一方法对本实验室组建的四株基因重配疫苗株进行实验,其结果与套式ＰＣＲ方法完全一致。     

Distribution of human rotaviruses, especially G9 strains, in Japan from 1996 to 2000

A 4-year (1996-2000) survey of rotavirus infection involving 2,218 diarrheal fecal specimens of children collected from five regions of Japan was conducted. A total of 642 (28.9%) specimens were found to be rotavirus positive. A changed prevalence pattern of rotavirus G serotype was found with an increase of G9 and G2 and a decrease of G1, although G1 remained the prevailing serotype. Serotype G9 was unexpectedly determined to be the prevailing serotype in Sapporo (62.5%) and Tokyo (52.9%) in 1998-1999, and in Saga (78.4%) in 1999-2000. G9 strains isolated from 1998-1999 belonged to the P[8]-NSP4-Wa-group with long RNA pattern, while, G9 strains isolated from 1999-2000 belonged to three groups, the P[8]-NSP4-Wa-group with long RNA pattern, the P[4]-NSP4-KUN-group with short RNA pattern and a mixed-type group (P[4]/P[8]-NSP4-KUN/Wa-group with long RNA pattern). Both sequence and immunological analysis of VP7 revealed that the G9 strains from 1999-2000 were much more closely related to the G9 strains isolated worldwide in the 1990s, including G9 strains found in Thailand in 1997. However, the G9 strains from 1998-1999 were distinct from these and more closely related to the G9 prototype strains F45, AU32 and WI61 discovered in Japan and the US in the 1980s. Thus the G9 strains isolated in 1998-1999 had progenitors common to the G9 prototype strains, while the strains isolated in 1999-2000 did not directly evolve from them but were related to global G9 strains that have emerged in recent years. These data supported our previous report that G9 rotavirus might exist as two or more subtypes with diverse RNA patterns, P-genotype and NSP4 genogroup combinations (Y.M. Zhou et al., J. Med. Virol. 65: 619-628, 2001) and suggested that G9 rotavirus prevalent in Japan during two successive years belonged to different subtypes. The nucleotide sequences presented in this paper were submitted to DDBJ, EMBL and GenBank nucleotide sequence databases. The accession numbers are: 00-Ad2863VP7 (AB091746), 00-OS2986VP7 (AB091747), 00-SG2509VP7 (AB091748), 00-SG2518VP7 (AB091749), 00-SG2541 (AB091750), 00-SG2864 (AB091751), 00-SP2737VP7 (AB091752), 99-SP1542VP7 (AB091753), 99-SP1904VP7 (AB091754), 99-TK2082VP7 (AB091755) and 99-TK2091VP7 (AB091756).     

Serotype-specific epitope(s) present on the VP8 subunit of rotavirus VP4 protein.

cDNA clones representing the VP8 and VP5 subunits of VP4 of symptomatic human rotavirus strain KU (VP7 serotype 1 and VP4 serotype 1A) or DS-1 (VP7 serotype 2 and VP4 serotype 1B) or asymptomatic human rotavirus strain 1076 (VP7 serotype 2 and VP4 serotype 2) were constructed and inserted into the pGEMEX-1 plasmid and expressed in Escherichia coli. Immunization of guinea pigs with the VP8 or VP5 protein of each strain induced antibodies that neutralized the rotavirus from which the VP4 subunits were derived. In a previous study (M. Gorziglia, G. Larralde, A.Z. Kapikian, and R. M. Chanock, Proc. Natl. Acad. Sci. USA 87:7155-7159, 1990), three distinct serotypes and one subtype of VP4 outer capsid protein were identified among 17 human rotavirus strains that had previously been assigned to five distinct VP7 serotypes. The results obtained by cross-immunoprecipitation and by neutralization assay with antisera to the VP8- and VP5-expressed proteins suggest that the VP8 subunit of VP4 contains the major antigenic site(s) responsible for serotype-specific neutralization of rotavirus via VP4, whereas the VP5 subunit of VP4 is responsible for much of the cross-reactivity observed among strains that belong to different VP4 serotypes.     

Rotavirus serotype G9 strains belonging to VP7 gene phylogenetic sequence lineage 1 may be more suitable for serotype G9 vaccine candidates than those belonging to lineage 2 or 3

A safe and effective group A rotavirus vaccine that could prevent severe diarrhea or ameliorate its symptoms in infants and young children is urgently needed in both developing and developed countries. Rotavirus VP7 serotypes G1, G2, G3, and G4 have been well established to be of epidemiologic importance worldwide. Recently, serotype G9 has emerged as the fifth globally common type of rotavirus of clinical importance. Sequence analysis of the VP7 gene of various G9 isolates has demonstrated the existence of at least three phylogenetic lineages. The goal of our study was to determine the relationship of the phylogenetic lineages to the neutralization specificity of various G9 strains. We generated eight single VP7 gene substitution reassortants, each of which bore a single VP7 gene encoding G9 specificity of one of the eight G9 strains (two lineage 1, one lineage 2 and five lineage 3 strains) and the remaining 10 genes of bovine rotavirus strain UK, and two hyperimmune guinea pig antisera to each reassortant, and we then analyzed VP7 neutralization characteristics of the eight G9 strains as well as an additional G9 strain belonging to lineage 1; the nine strains were isolated in five countries. Antisera to lineage 1 viruses neutralized lineage 2 and 3 strains to at least within eightfold of the homotypic lineage viruses. Antisera to lineage 2 virus neutralized lineage 3 viruses to at least twofold of the homotypic lineage 2 virus; however, neutralization of lineage 1 viruses was fourfold (F45 and AU32) to 16- to 64-fold (WI61) less efficient. Antisera to lineage 3 viruses neutralized the lineage 2 strain 16- to 64-fold less efficiently, the lineage 1 strains F45 and AU32 8- to 128-fold less efficiently, and WI61 (prototype G9 strain) 128- to 1024-fold less efficiently than the homotypic lineage 3 viruses. These findings may have important implications for the development of G9 rotavirus vaccine candidates, as the strain with the broadest reactivity (i.e., a prime strain) would certainly be the ideal strain for inclusion in a vaccine.