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。     

体外鉴定汉坦病毒包膜糖蛋白G2与β3整合素的相互作用

根据汉坦病毒76—118株M基因和β3整合素基因序列设计引物,分别以质粒M56和Hela细胞cDNA为模板通过PCR扩增和基因重组获得G2蛋白膜外区81-140片段的GST融合表达质粒以及β3整合素膜外区23～133片段FLAG融合表达质粒。通过SDS—PAGE检测G2片段在BL21表达菌中诱导表达及纯化的效果,Wester blot检测β3整合素片段在真核细胞中的表达。将在BL21裂解上清中表达的G2蛋白N端81～140位氨基酸片段（G2N81～140）纯化后与经过GST蛋白预处理的含有β3整合素片段的细胞裂解上清进行孵育,同时以未做任何转染的HEK293细胞裂解上清和无关蛋白GST～TLM作为阴性对照,通过GST Pull—down验证G2蛋白与β3整合素之间的相互作用。结果显示在Pull—down所获蛋白复合物中检测到β3整合素27-133位氨基酸片段产物的存在。结果表明G2蛋白与β3整合素之间可能存在有直接的相互作用,为β3整合素作为汉坦病毒细胞膜受体提供了进一步证据。     

KDP胞外502～764位氨基酸基因合成、表达及功能鉴定

应用基因搭桥法及 Taq酶聚合反应合成了编码人血管内皮生长因子受体 - ( h VEGFR- ,KDR)第 50 2～ 764位 2 62个氨基酸的基因片段 .DNA序列分析表明 ,合成的 786bp的基因片段与文献报道的 KDR相应 c DNA序列完全一致 .将该基因与原核融合蛋白表达载体 p GEX- 3X重组 ,在大肠杆菌 JM1 0 9中表达了 GST- KDR2 62融合蛋白 ,表达量约占菌体总蛋白的 35% .表达产物依次经包涵体分离、变性、复性、亲合层析纯化和 Xa因子酶解 ,获得了 KDR2 62目的蛋白纯品 .GST-KDR2 62融合蛋白和纯化产物经 Western blot分析 ,两者均可被 VEGF1 65特异性识别 ,前者分子量约 56k D,后者分子量约 30 k D;这两种蛋白用 VEGF1 65及其抗体进行的 ELISA分析结果均显示阳性 ,并有剂量依赖关系 ,而用 Xa因子酶解 GST- KDR2 62融合蛋白获得的 GST和空载体诱导产物对照均为阴性 .以上结果表明表达的 KDR2 62蛋白可特异性地与 VEGF结合 .     

猪链球菌2型次黄嘌呤核苷酸脱氢酶单克隆抗体的制备及其识别表位分析

用纯化的硫氧还蛋白-IMPDH融合蛋白免疫BALB/c小鼠,取其脾细胞与SP2/0骨髓瘤细胞融合,对杂交瘤细胞及时筛选,阳性孔经4次有限稀释法克隆,成功获得1A8、1F2、2D2和2D12共4株能稳定传代并分泌抗IMPDH的单克隆抗体(McAb)的杂交瘤细胞株.4株腹水型单克隆抗体间接ELISA效价分别为100x211、100x211、100x210和100x28,经Western-blot分析表明,4株单抗与硫氧还蛋白-IMPDH融合蛋白均具有特异性反应,并且通过4种IMPDH全基因分片段缺失表达的融合蛋白,分析了4株单抗所识别抗原决定簇的差异性,发现1A8、1F2,2D2识别表位的编码基因集中在IMPDH基因片段的627 bp～790 bp之间,2D12识别表位的编码基因则集中在IMPDH基因片段的411 bp～790 bp之间.猪链球菌2型中IMPDH单克隆抗体的获得及相应表位分析为研究IMPDH蛋白的生物学活性及免疫学活性奠定了基础.     

抗GPC3 C端抗体辅助杀伤肝癌细胞HepG2的活性检测及抗原表位鉴定

目的：检测制备的7株抗磷脂酰肌醇蛋白聚糖3（GPC3）蛋白C端单克隆抗体是否具有辅助杀伤肝癌细胞的活性,并研究其识别的抗原表位。方法：用细胞增殖法检测制备的抗体是否具有抗体依赖细胞介导的细胞毒性（ADCC）活性;用生物信息软件分析GPC3蛋白C端（359～580残基）的结构及抗原特征,并据此将其分为4个截短片段,将克隆的各基因片段分别连接到原核表达载体pGEX-4T-1中,进行蛋白表达和纯化,用间接ELISA和Western印迹分析GPC3C端单克隆抗体的表位识别情况。结果与结论：制备的7株单克隆抗体对肝癌细胞HepG2均具有不同程度的辅助杀伤作用,其中5号单克隆抗体的辅助杀伤效果最好;表达并纯化了GPC3C端4个截短片段的重组蛋白;间接ELISA和Western印迹检测结果表明,7株抗体均特异性结合GPC3蛋白的473～525残基区段。     

HBV前S1蛋白与HepG2细胞膜蛋白结合位点鉴定

为鉴定HepG2细胞膜蛋白识别HBV包膜蛋白preS1区的位点.通过删除突变的方法构建preS1的不同区域片段与GST融合的重组表达质粒,将表达质粒转入E.coli BL21菌株中原核表达,以生物素标记HepG2细胞膜蛋白,pull down试验分析HepG2细胞膜蛋白识别preS1的位点.结果表明,21～33位氨基酸是HepG2细胞膜蛋白识别preS1的主要位点.通过对HepG2细胞膜蛋白与preS1结合的位点的分析,为进一步研究preS1在HBV早期感染中的作用和HBV包膜蛋白受体打下基础.     

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。     

PEDV S蛋白B细胞抗原表位的筛选和鉴定

以猪流行性腹泻病毒(porcine epidemic diarrhea virus,PEDV)S基因的免疫优势区S1(1～2367bp)为靶基因,利用基于gⅢ表达外源多肽的fd丝状噬菌体展示系统,构建S1基因噬菌体展示肽库,以纯化病毒制备的兔抗PEDV多克隆血清为靶蛋白,对S1基因噬菌体展示肽库进行3轮生物淘选,结果获得3个高亲和力的序列,分别命名为S1P1(248～280位氨基酸)、S1P2(442～499位氨基酸)和S1P3(697～742位氨基酸).ELISA和蛋白质印迹结果显示,S1P1、S1P2和S1P3短肽都能被兔抗PEDV多克隆血清识别,其中S1P3反应性最强.为了进一步揭示S1P1、S1P2和S1P3短肽的抗原性,制备了3个短肽GST融合蛋白和它们串连后GST融合蛋白的单因子血清,间接免疫荧光试验(IFA)结果证实,抗S1P2-GST、S1P3-GST和S1P123-GST融合蛋白的单因子血清能够识别Vero细胞培养物中天然的PEDV.     

SARS 冠状病毒 S 蛋白受体结合结构域的表达及其表位作图

严重急性呼吸综合征 (SARS) 是一种新出现的人类传染病,该病的病原是 SARS 冠状病毒 (SARS-CoV). S 蛋白是 SARS 冠状病毒的一种主要结构蛋白,它在病毒与宿主细胞受体结合以及诱导机体产生中和抗体中起重要作用 . 研究表明 S 蛋白与受体结合的核心区域为第 318 ~ 510 氨基酸残基的片段 . 首先克隆并用 pGEX-6p-1 载体融合表达了该受体结合结构域,并且通过蛋白质印迹分析表明,该受体结合结构域融合蛋白能被 SARS 康复患者血清和 S 蛋白特异的单克隆抗体所识别 . 为了对这一区域进行抗原表位作图,进一步设计了一套 23 个覆盖受体结合结构域的长 16 个氨基酸残基的部分重叠短肽,并进行了 GST 融合表达 . 用免疫动物血清和单克隆抗体 D3D1 对 23 个融合蛋白进行蛋白质印迹和 ELISA 免疫反应性分析,结果鉴定出两个抗原表位 SRBD3(F334PSVYAWERKKISNCV349) 和表位 D3D1 (K447LRPFERDI455). 其结果对进一步分析 S 蛋白结构与功能以及诊断试剂和基因工程疫苗的研究有一定意义 .     

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。     

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基因的克隆和序列分析

应用多聚酶链反应（PCR）的方法扩增出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1746 bp,其中gp85和gp37由1554 bp组成,可翻译成517个氨基酸,分子量为57.7 D。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gp37在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。     

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。     

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.     

Japanese encephalitis virus fusion protein with protein A expressed in Escherichia coli confers protective immunity in mice.

A complementary DNA (cDNA) that codes C-terminal, one-third of envelope glycoprotein (E) and N-terminal 65 amino acids of NS1 protein of Japanese encephalitis (JE) virus was inserted into Escherichia coli expression vector pRIT2T. The inserted gene was expressed as a fusion protein with protein A, and the expressed protein was intraperitoneally injected into mice. The immunized mice produced anti-JE antibodies measured by the hemagglutination-inhibition and neutralization tests as well as ELISA and were protected from the lethal challenge of JE virus by intraperitoneal inoculation.     

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.     

Induction of complement-dependent and -independent neutralizing antibodies by recombinant-derived human cytomegalovirus gp55-116 (gB).

The human cytomegalovirus (HCMV) envelope glycoprotein complex gp55-116 was expressed in both Escherichia coli and cells infected with a recombinant vaccinia virus. E. coli produced a single protein of Mr 100,000 which approximated the size of the nonglycosylated gp55-116 precursor found in HCMV-infected cells. Cells infected with the recombinant vaccinia virus contained three intracellular forms of Mr 160,000, 150,000, and 55,000 which were detected by a monoclonal antibody reactive with gp55. Comparison of the immunological properties of these recombinant proteins indicated that several of the HCMV gp55-116 monoclonal antibodies and sera from patients infected with HCMV reacted with the vaccinia virus-derived proteins whereas a more restricted group of monoclonal antibodies recognized the E. coli-produced protein. Immunization of mice with either E. coli or vaccinia virus recombinant HCMV gp55-116 resulted in production of virus-neutralizing antibodies. In contrast to the almost exclusive production of complement-dependent neutralizing antibodies following immunization with recombinant vaccinia virus, the E. coli-derived protein induced complement-independent neutralizing antibodies.     

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.