禽白血病病毒J亚群env基因的克隆和序列分析

应用多聚酶链反应（PCR）的方法增出ADOL－4817毒株的囊膜蛋白env基因,并克隆进大肠杆菌。经核酸序列分析证明,env基因的大小为1746bp,其中gp85和gp37mh 1554bp组成,可翻译成517个氨基酸,分子量为57.7kD。根据糖基化位点N－X－S／T的特点,发现ADOL－4817的env蛋白有15个潜在的糖基化位点。同源性分析证明,ADOL－4817的env基因与其它ALV－J的env基因序列同源性为88.8％－92.4%,而与外源性ALVs的相应序列的同源性仅为40.5％－51.4％,然而,与内源性的EAV－HP毒株的类env基因的同源性高达91.2％;另外,ADOL－4817毒株的gp37d C末端多了13个氨基酸,这些结果提示,ALV－J的env基因存在广泛的变异性,env基因可能来源于内源性和外源性ALVs的重组。     

蛋鸡J亚群白血病病毒的分离鉴定及序列分析

通过接种鸡胚成纤维细胞((CEF)及特异性单抗的间接荧光抗体反应(IFA),从中国商品代蛋鸡群中首次分离到J亚群白血病病毒(ALV-J).对其env基因编码的氨基酸序列及3'-末端(3'-Ter)序列与国内外来源于白羽肉鸡的毒株作了比较分析.结果显示,这两株病毒的gp85基因编码的氨基酸序列与国外5个毒株同源性仅为83.4%～87.3%,与国内来源于白羽肉鸡的8株病毒同源性也仅为86.4%～89.6%.gp37基因编码的氨基酸序列与5个国外毒株同源性为91.8%～97.0%,与8个国内毒株同源性为93.9%～95.9%.另外,国内来源于白羽肉鸡的各毒株的3'-Ter序列在"E"区均有明显缺失,但本次分离的来源于蛋鸡群的毒株在"E"区没有缺失突变.与所列出的13株国内外毒株相比,这两个毒株在3'-Ter的缺失最少,较接近于原型株HPRS-103.显然这两株病毒的来源不同于国内白羽肉鸡.     

我国地方品种鸡分离到的一个禽白血病病毒新亚群的鉴定

为探明我国地方品种鸡群禽白血病病毒(Avian leukosis virus,ALV)的特点,通过接种DF-1细胞及细胞培养上清液p27抗原的检测,从芦花鸡中分离得到三株外源性ALV禽白血病病毒,分别是JS11C1、JS11C2和JS11C3,并对其进行亚群鉴定分析。用PCR方法扩增env基因测序,并与已知鸡源各亚群ALV的囊膜蛋白(gp85)作氨基酸同源性比较。这三株ALV的env基因的gp85大小为1 005bp,编码335个氨基酸;env基因的gp37大小为609bp,编码203个氨基酸。三个毒株之间gp85的同源性为91.9%～97.0%。与A、B、C、D和E五个经典亚群在GenBank中已发表的18个毒株的gp85的同源性仅在77.7%～84.6%间,显著低于鸡群中常见的A、B、E各亚群内的同源性范围(分别为88.2%～98.5%,91.6%～98.8%和97.9%～99.4%),而与J亚群参考株的同源性更是只有34.2%～36.5%。上述结果表明,芦花鸡分离到的三株病毒可能是不同于鸡源ALV已知6个亚群的一个新亚群,按国际上对ALV亚群分类的习惯,初步将其定名为K亚群。     

鸡内源性类J亚群禽白血病病毒gp85基因的克隆及分析

为深入探讨J亚群禽白血病病毒(Avian leukosis virus subgroup J,ALV-J)的亚群特性,利用ALV-J gp85基因两侧的序列片段为引物,从正常SPF蛋鸡、商品肉鸡和DF1细胞基因组中完整地扩增了内源性类ALV-J gp85基因。肉鸡和DF1细胞内源性类ALV-J gp85基因同源性达99．9％;SPF蛋鸡内源性类ALV-J gp85基因与肉鸡和DF1细胞的内源性类ALV-J gp85基因之间同源性达95．6％、95．3％。三种不同来源的内源性类ALV-J gp85基因DNA与IMC10200株ALV-J的gp85基因的同源性分别为91．8％、94．1％、94．0％;与ALV-J原型株HPRS-103gp85基因的同源性分别为95．6％、98．3％、99．9％。内源性类ALV-J gp85序列与外源性ALV-J gp85基因具有相似或一致的ORF和Jameson-Worrlf抗原表位优势。     

犬瘟热病毒TN株血凝基因的克隆与序列分析

用RT PCR方法对分离的TN野毒株H基因进行了扩增 ,并将其克隆到pGEM T载体上 ,进行核苷酸序列测定。结果TN野毒株H基因ORF全长 1 ,81 5bp ,编码 60 4个氨基酸。与GenBank中己报道的 7个CDV毒株相比 ,H基因核苷酸序列的同源性在 92 %～ 99%之间 ,推导的H蛋白氨基酸序列的同源性在 91 %～ 99%之间。TN株H蛋白潜在的N 联糖基化位点为 8个 ,而Onderstepoort弱毒株H蛋白为 4个 ;其中N端第 1 9～ 2 1、 30 9～ 31 1、 5 8     

我国1999-2003年间ALV-J野毒株gp85基因变异趋势

通过接种鸡胚成纤维细胞(CEF)、间接免疫荧光试验(IFA)和聚合酶链式反应(PCR),连续五年从全国各地的送检病料中分离到14株J亚群白血病病毒(ALV-J).为了动态观察ALV-J囊膜表面结构蛋白(GP85)的变异情况,对这14株野毒株的囊膜糖蛋白基因(env)进行了克隆和测序,将它们与HPRS-103株的GP85的氨基酸序列进行了比较,结果表明ALV-J的囊膜表面结构蛋白发生了很大的变异,而且这些变异主要集中在高变区hr1、hr2和vr3;这些野毒株GP85的氨基酸序列的同源性在86.6%～100%之间(从同一鸡场中分离到的两株ALV-J即BJ00302与BJ0303的同源性为100%,其它毒株之间的同源性均小于100%);有义突变与沉默突变的比例显示这3个高变区极有可能是免疫选择压作用的位点.     

蛋鸡J亚群禽白血病的分子生物学诊断

根据J亚群白血病病毒(ALV-J)原型株HPRS-103的序列设计了一对针对外源性ALV-J引物H5和H7,从发生ML病死鸡的肿瘤、骨髓、肝脏、脾脏和输卵管组织中提取DNA作为模板,经PCR扩增得到长度为545bp的片段,对其序列进行测定后,与ALV-J原型株HPRS-103的序列进行了比较,发现其核苷酸同源性为97．4％,所编码氨基酸的同源性为96．1％。该片段含有ALV-J gp85编码基因的部分序列和ALV-J pol基因的部分序列,从分子水平上证实了蛋鸡发生J亚群禽白血病,进一步证明了此前根据病理学观察、免疫组化及免疫荧光诊断的结果。这是首次从分子水平上证明蛋用型鸡发生J亚群禽白血病。     

我国部分地区H9亚型禽流感病毒血凝素基因序列比较与遗传发生关系分析

为从分子水平掌握我国H9亚型AIV的遗传变异情况和流行规律,本研究汇集近年来从我国12个省、市、自治区的发病鸡群中分离到的23株H9亚型禽流感病毒,通过RT-PCR方法和核苷酸序列测定获得了23个毒株的HA基因cDNA核苷酸序列。核苷酸和推导的氨基酸序列同源性比较结果表明,这些毒株HA基因的核苷酸序列同源性为94．1％～100％,氨基酸序列同源性为95．4％～100%;将这23个毒株和来自亚洲及世界其它地区的另外31株的HA基因cDNA序列同源性进行比较发现,分离自香港的HK170499株与日本的2个毒株关系较近;氨基酸序列分析发现,CKGS199、CKTJ196、CKTJ296、CKSH300和CKBJ197五个毒株各发生了一个潜在的糖基化位点的丢失。54株H9亚型AIVHA基因55bp～1152bp的氨基酸序列分析发现,裂解位点尽管有10种基序,但本研究中的23株和近年来从我国大陆和香港地区的分离的毒株则均为RSSR↓GLF;构成受体结合位点的191位氨基酸有一个规律,即所有中国大陆毒株与部分香港毒株都为N,其它毒株均为H,141aa～143aa处的糖基化位点有与191aa类似的规律,即：凡是191aa为N的毒株,该处均为NVS（CKBJ194除外）,凡是191aa为H的毒株,则该处均为NVT;遗传发生关系分析,中国大陆毒株处于欧亚谱系的第一支。本研究结果表明近年来我国鸡群中H9N2亚型禽流感病毒的感染流行可能有一个共同的来源,这为制定防治该亚型禽流感流行的有效对策提供了重要的科学依据。     

我国1999—2003年间ALV—J野毒株gp85基因变异趋势

通过接种鸡胚成纤维细胞（CEF）、间接免疫荧光试验（IFA）和聚合酶链式反应（PCR）,连续五年从全国各地的送检病料中分离到14株J亚群白血病病毒（ALV-J）。为了动态观察ALV-J囊膜表面结构蛋白（GP85）的变异情况,对这14株野毒株的囊膜糖蛋白基因（env）进行了克隆和测序,将它们与HPRS-103株的GP85的氨基酸序列进行了比较,结果表明：ALV-J的囊膜表面结构蛋白发生了很大的变异,而且这些变异主要集中在高变区hr1、hr2和vr3;这些野毒株GP85的氨基酸序列的同源性在86．6％～100％之间（从同一鸡场中分离到的两株ALV-J即BJ00302与BJ0303的同源性为100％,其它毒株之间的同源性均小于100％）;有义突变与沉默突变的比例显示这3个高变区极有可能是免疫选择压作用的位点。     

河南省有偿供血者HIV-1外膜蛋白env基因序列分析及表型预测

应用套式聚合酶链反应(nested-PCR)从60例河南省HIV-1抗体阳性有偿献血者的外周血单核细胞的DNA样品中扩增全长env基因并对扩增产物测序,共扩增到21个全长env基因,序列分析发现其中15个env基因有完整的可读框(ORF),14个为B'亚型,与国际参考株RL42的基因离散率为4.87%±0.31%,1个为B亚型,与国际参考株HXB2的基因离散率为5.43%。根据核苷酸序列推导出相应的氨基酸序列,并且分析及比较了重要的功能结构域。发现这15个序列的N糖基化位点和数目没有显著变化;CD4受体结合位点高度保守;根据V3环氨基酸序列及净电荷数目,预测大多数分离株使用CCR5辅助受体;V3环四肽序列以典型欧美B亚型GPGR最多,占40%;gp120/gp41剪切位点高度保守,预测所有gp160前体都能有效剪切;四种广谱中和抗体2G12I、gG1b12、4E10及2F5的识别位点高度保守,表明大多数分离株对这四种中和抗体敏感。有必要进一步阐明env基因型与相关功能的关系,这将为疫苗研究和药物开发提供依据。     

Expression of Endogenous Retrovirus ev/J gp85 Gene and Analysis of Its Immunoreactivity in Comparison with Exogenous Viral Protein

The envelope gene gp85 of ev/J,a new family of endogenous avian retroviral sequences identified recently, has the most extensive nucleotide sequence identity ever described with ALV-J avian ieukosis virus. This report described expression of ev/J envelope gene gp85 derived from commercial meat-type chicken using the Invitrogen Bac-to-Bac baculovirus expression system. The antigenicity and immunoreactivity of the recombinant endogenous gp85 gene product (SU) were analyzed by indirect immunofluorescence, Western blot, indirect and blocking Enzyme-Linked ImmunoSorbent Assay (ELISA) using JE9 monoclonal antibody (MAb) against the envelope protein of ALV-J (ADOL-4817), positive mouse antiserum against the ev/J gp85 SU and sera from chicken naturally infected with ALV-J. The results showed that the ev/J gp85 SU can bind specifically to JE9 MAb and antiserum from chicken naturally infected with ALV-J, and the binding reactivity between exogenous ALV-J gp85 SU and natural positive chicken serum against exogenous ALV-J can be blocked by positive mouse serum against the ev/J gp85 SU. It is concluded that recombinant endogenous gp85 gene product (SU) has close immunological relatedness to the envelope protein of exogenous ALV-J (ADOL-4817 and IMC<,10200> strain).     

禽白血病病毒J亚群env基因产物的抗原性分析

用PCR扩增方法将ALV Jenv基因不同片段进行了克隆 ,并构建了env基因片段GST融合蛋白载体。用Westernblot实验证明 ,大肠杆菌表达的不同env基因片段的GST融合蛋白能与相应的单克隆抗体产生特异性反应性 ,单克隆抗体JE9和G2识别的抗原位点位于gp85的氨基酸 6 5～ 1 5 5区域 ,而I45识别的抗原表位位于env基因的另一区域 (1 5 6～ 2 3 3位氨基酸 )。ALV J氨基酸多肽而非糖基化位点决定ALV J的亚群特异性     

Expression of endogenous retrovirus ev/J <Emphasis Type="Italic">gp85</Emphasis> gene and analysis of its immunoreactivity in comparison with exogenous viral protein

The envelope gene gp85 of ev/J, a new family of endogenous avian retroviral sequences identified recently, has the most extensive nucleotide sequence identity ever described with ALV-J avian leukosis virus. This report described expression of ev/J envelope gene gp85 derived from commercial meat-type chicken using the Invitrogen Bac-to-Bac baculovirus expression system. The antigenicity and immunoreactivity of the recombinant endogenous gp85 gene product (SU) were analyzed by indirect immunofluorescence, Western blot, indirect and blocking Enzyme-Linked ImmunoSorbent Assay (ELISA) using JE9 monoclonal antibody (MAb) against the envelope protein of ALV-J (ADOL-4817), positive mouse antiserum against the ev/J gp85 SU and sera from chicken naturally infected with ALV-J. The results showed that the ev/J gp85 SU can bind specifically to JE9 MAb and antiserum from chicken naturally infected with ALV-J, and the binding reactivity between exogenous ALV-J gp85 SU and natural positive chicken serum against exogenous ALV-J can be blocked by positive mouse serum against the ev/J gp85 SU. It is concluded that recombinant endogenous gp85 gene product (SU) has close immunological relatedness to the envelope protein of exogenous ALV-J (ADOL-4817 and IMC₁₀₂₀₀ strain). Foundation items: Natural Science Foundation of China (30460098); China Postdoctoral Science Foundation funded project (2005038585).     

J亚群鸡白血病病毒AH09/2株的gp85基因的克隆与原核表达

利用PCR方法扩增出J亚群禽白血病病毒(ALV-J)AH09/2株的gp85基因全长930 bp DNA片段。经T载体克隆测序并连接到pGEX-6p-1载体上,构建了重组表达质粒pGEX-6P-1-gp85,在IPTG的诱导下进行表达。Western-blot结果分析表明,gp85融合蛋白表达产物分子量大小约61 kDa,并能与ALV-Jenv基因单抗发生特异性反应。这些结果为深入研究GP85蛋白的生物学功能及研制ALV-J检测ELISA试剂盒奠定了基础。     

禽白血病病毒J亚群囊膜蛋白env基因的克隆和表达

禽白血病病毒J亚群（ALV－J）是90年代鉴定出的ALV的新亚群,其囊膜蛋白env基因序列别与ALV A－E亚群的有相当大的差别。为ALV－J env基因及春表达产物的特点,用PCR方法扩增出ADOL－4817毒株的env基因,并克隆进TA载体,经电泳鉴定大小为1.7kb。将克隆出的env基因与杆状病毒pBlue-Bac4表达质粒DNA连接,构建成转移性载体pBac4817env,通过与Bac-N-Blue杆状病毒DNA共转染,区得了重组病毒rBac4817env-2。该重组杆状病毒感染Sf9细胞,能高效表达env基因产物,免疫荧光分析结果证明,单克隆抗体G2或多价兔抗env gp37血清能识别Sf9细胞,能高效表达env基因表达的特异性抗原;Western blotting分析结果表明,表达的重组基因产物的分子量大小约为90kD-94kD。用这些重组基因产物免疫鸡可以诱导鸡导鸡产生出高滴度的抗ALV－J特异性抗体。这一结果提示,这种杆状病毒表达的重组基因产物有助于ALV－J env基因生物学特性的深入研究。     

The Unique Envelope Gene of the Subgroup J Avian Leukosis Virus Derives from ev/J Proviruses, a Novel Family of Avian Endogenous Viruses

A new subgroup of avian leukosis virus (ALV), designated subgroup J, was identified recently. Viruses of this subgroup do not cross-interfere with viruses of the avian A, B, C, D, and E subgroups, are not neutralized by antisera raised against the other virus subgroups, and have a broader host range than the A to E subgroups. Sequence comparisons reveal that while the subgroup J envelope gene includes some regions that are related to those found in env genes of the A to E subgroups, the majority of the subgroup J gene is composed of sequences either that are more similar to those of a member (E51) of the ancient endogenous avian virus (EAV) family of proviruses or that appear unique to subgroup J viruses. These data led to the suggestion that the ALV-J env gene might have arisen by multiple recombination events between one or more endogenous and exogenous viruses. We initiated studies to investigate the origin of the subgroup J envelope gene and in particular to determine the identity of endogenous sequences that may have contributed to its generation. Here we report the identification of a novel family of avian endogenous viruses that include env coding sequences that are over 95% identical to both the gp85 and gp37 coding regions of subgroup J viruses. We call these viruses the ev/J family. We also report the isolation of ev/J-encoded cDNAs, indicating that at least some members of this family are expressed. These data support the hypothesis that the subgroup J envelope gene was acquired by recombination with expressed endogenous sequences and are consistent with acquisition of this gene by only one recombination event.     

Different quasispecies with great mutations hide in the same subgroup J field strain of avian leukosis virus

Blood samples were collected from a local strain of chickens associated with serious tumor cases in Shandong Province.The samples were inoculated into chicken embryo fibroblast and DF-1 cells for virus isolation and identification,respectively.The inoculated cells were screened for three common chicken tumor viruses.Nine strains of avian leukosis virus subgroup J(ALV-J) were identified,and were designated LY1201‐LY1209.The env gene from the LY1201 strain was amplified and cloned.All nine resultant env clones(clones 01-09) were sequenced,and the gp85 and gp37 amino acid regions were subjected to homology analysis.Clones 01 and 03 had 10 amino acid deletions in the gp85 region compared to the other seven clones,suggesting that at least two quasispecies with obvious mutations coexist in the same field strain.Among these nine clones,three had identical gp85 and gp37 sequences,and were recognized as the dominant LY1201 quasispecies.The amino acid sequence homology of gp37 and gp85 among the nine clones was 98.5%-100.0% and 96.6%-100.0% respectively,suggesting that the gp85 region of the env gene can better display the quasispecies diversity of ALV-J than gp37.     

The avian retrovirus env gene family: molecular analysis of host range and antigenic variants.

The nucleotide sequence of the env gp85-coding domain from two avian sarcoma and leukosis retrovirus isolates was determined to identify host range and antigenic determinants. The predicted amino acid sequence of gp85 from a subgroup D virus isolate of the Schmidt-Ruppin strain of Rous sarcoma virus was compared with the previously reported sequences of subgroup A, B, C, and E avian sarcoma and leukosis retroviruses. Subgroup D viruses are closely related to the subgroup B viruses but have an extended host range that includes the ability to penetrate certain mammalian cells. There are 27 amino acid differences shared between the subgroup D sequence and three subgroup B sequences. At 16 of these sites, the subgroup D sequence is identical to the sequence of one or more of the other subgroup viruses (A, C, and E). The remaining 11 sites are specific to subgroup D and show some clustering in the two large variable regions that are thought to be major determinants of host range. Biological analysis of recombinant viruses containing a dominant selectable marker confirmed the role of the gp85-coding domain in determining the host range of the subgroup D virus in the infection of mammalian cells. We also compared the sequence of the gp85-coding domain from two subgroup A viruses, Rous-associated virus type 1 and a subgroup A virus of the Schmidt-Ruppin strain of Rous sarcoma virus. The comparison revealed 24 nonconservative amino acid changes, of which 6 result in changes in potential glycosylation sites. The positions of 10 amino acid differences are coincident with the positions of 10 differences found between two subgroup B virus env gene sequences. These 10 sites identify seven domains in the sequence which may constitute determinants of type-specific antigenicity. Using a molecular recombinant, we demonstrated that type-specific neutralization of two subgroup A viruses was associated with the gp85-coding domain of the virus.     

Nonconserved Tryptophan 38 of the Cell Surface Receptor for Subgroup J Avian Leukosis Virus Discriminates Sensitive from Resistant Avian Species

Subgroup J avian leukosis virus (ALV-J) is unique among the avian sarcoma and leukosis viruses in using the multimembrane-spanning cell surface protein Na⁺/H⁺ exchanger type 1 (NHE1) as a receptor. The precise localization of amino acids critical for NHE1 receptor activity is key in understanding the virus-receptor interaction and potential interference with virus entry. Because no resistant chicken lines have been described until now, we compared the NHE1 amino acid sequences from permissive and resistant galliform species. In all resistant species, the deletion or substitution of W38 within the first extracellular loop was observed either alone or in the presence of other incidental amino acid changes. Using the ectopic expression of wild-type or mutated chicken NHE1 in resistant cells and infection with a reporter recombinant retrovirus of subgroup J specificity, we studied the effect of individual mutations on the NHE1 receptor capacity. We suggest that the absence of W38 abrogates binding of the subgroup J envelope glycoprotein to ALV-J-resistant cells. Altogether, we describe the functional importance of W38 for virus entry and conclude that natural polymorphisms in NHE1 can be a source of host resistance to ALV-J.