EB病毒潜伏膜蛋白2A在小鼠B细胞淋巴瘤模型中增强Myc诱导的细胞周期进程

<正>myc基因表达升高是许多人类癌症的共同特性。Epstein-Barr病毒(EBV)与淋巴系统恶性肿瘤有关,但在淋巴瘤中Myc与EB病毒之间的相互作用尚不清楚。EBV潜伏膜蛋白2A(LMP2A)可充当B细胞受体(BCR)的类似物,给受感染的B细胞提供存活信号。与单独表达人myc基因的小鼠(λ-myc小鼠)相比,共表达myc和LMP2A的小鼠(LMP2A/λ-myc小鼠)能加速B细胞淋巴瘤的发生。该研究发现LMP2A的一个新作用,即通过Myc促进细胞周期G1-S转换,且以蛋白酶体依赖的方式下调细胞周期蛋白依赖激酶     

EB病毒编码的蛋白质在癌变过程中的作用

EB病毒是一种与人类肿瘤有密切关系的DNA病毒.在病毒感染的不同时期有不同病毒编码蛋白质的表达,因此研究所表达不同抗原的致瘤作用将有助于研究EB病毒的致瘤机制.本文仅就EB病毒编码蛋白LMP1、EBNA1、EBNA2、BARF0和BARF1在癌变中作用的研究进展作一综述.     

EBV LMP1通过诱导c-myc表达活化端粒酶hTERT

利用原代人胚鼻咽上皮细胞和Tet on LMP1HNE2等良好的细胞体系,采用报道基因法和Westernblot法等,分别检测Epstein Barr病毒(EBV)潜伏膜蛋白1(LMP1)诱导的c myc反式激活活性和蛋白表达水平,从LMP1诱导细胞内c myc表达的角度,探讨LMP1诱导端粒酶表达的分子机制。结果表明,LMP1促使细胞内c myc反式激活活性增强,c Myc蛋白表达量升高;导入反义LMP1表达质粒阻断LMP1表达后,c myc反式激活活性下降。将端粒酶hTERT启动子上c myc结合位点突变后,LMP1不能诱导端粒酶hTERT表达。因而认为,EB病毒LMP1通过诱导c myc表达而活化端粒酶hTERT。     

EB病毒诱导的胸腺恶性T细胞淋巴瘤细胞体外长期培养研究

建立含有EB病毒的T细胞淋巴瘤细胞系,为探讨EB病毒的致瘤机理,研究EB病毒在T细胞淋巴瘤发生过程中的作用提供手段.在TPA协同EB病毒诱导胸腺恶性T细胞淋巴瘤动物模型的基础上,联合应用IL-2,将诱导的肿瘤组织进行体外细胞培养,成功地分离获得一株在体外长期存活的淋巴细胞TET.T细胞亚群分类实验证实TET细胞为CD4阳性的T淋巴细胞,PCR和原位杂交可检测到EB病毒的EBERs、LMP1和BARF1,并有LMP1蛋白的表达.TET细胞的获得,有望在体外建立转化细胞系,为体外研究EB病毒的致瘤机理及防治提供理想的实验材料.     

EB病毒诱导胸腺恶性T细胞淋巴瘤的研究

为研究EB病毒在恶性T细胞淋巴瘤发生中的作用,将EB病毒感染的人胚胸腺细胞移植于Scid鼠皮下,于移植后第3日起在移植处对侧皮下注射TPA50ng／只,每周1次。于移植后第4周起,移植处皮下有结节状隆起形成,并逐渐增大。于6－15周内行病理学检查和免疫组织化学染色,证实为T细胞淋巴瘤8例。其中实验组胸腺细胞＋EBV的成瘤率为25％（1／4）,胸腺细胞＋EBV＋TPA组的成瘤率为53.8%（7／13）,对照组胸腺细胞＋TPA的成瘤率为0（0／5）。PCR和 闰杂交在诱导肿瘤可可检测到EB病毒的基因EBERs、LMP1和BARF1,并有病毒基因LMP1蛋白编码产物的表达。EB病毒可感染人胚胸腺细胞,并使其发生恶性转化,EB病毒可能在恶性T细胞淋巴瘤的发生中起病因作用。     

鼻咽癌病人和正常人群中EB病毒特异性T细胞对靶抗原的识别和应答

为探讨痘苗病毒表达的Eoskein-Barr病毒（EBV）核抗原1、4（EBNA1、4）和潜伏膜蛋白1、2（LMP1、2）,在不同人群的特异性T细胞杀伤9CTL）中的作用,采集EBV阴性正常人、未经治疗的鼻咽癌（NPC）病人的EBV－IgA/VCA阳性者各10人的周围血淋巴单核细胞（PBMC）,用EBV转化B淋巴细胞,建立类淋巴母细胞（LCL）,用LCL刺激自休的T淋巴细胞作为效应细胞,以LCL感染重组痘苗病毒表达的EBNA1、4和LMP1、2为靶细胞,以^51Cr释放法检测EBV特异性CTL所识别的靶抗原。结果表明,EBV－LMP1、2可能既是EBV特异性T细胞的刺激抗原,又是其识别的靶抗原。将采集的30例试验者的各5 单克隆T细胞株分别检测HLA-Ⅰ型（A、B、C）,按照不同型别寻找相对应的EBNA1、4和LMP1、2的不同合成肽,应用酶免疫吸附斑点法（Elispot）检测EBV特异性CD8^ 的CTL应答。结果显示：10例正常人中9人有特异的LMP2应答,4人有特异的EBNA4应答;10例未治疗的NPC病人中3人有特异的LMP2,2人有特异的EBNA1,3个有特异的EBNA4应答;10例未治疗的NPC病人中3人有特异的EBNA1,3人有特异的EBNA4应答,在10例EBV－IgA/VCAbj ntg k ,6人有特异的LMP2,5人有特异的EBNA4应答。所有的试验者均未发现LMP1的特异性应答。     

EBV LMPl通过诱导c-myc表达活化端粒酶hTERT

利用原代人胚鼻咽上皮细胞和Tet—on—LMP1 HNE2等良好的细胞体系,采用报道基因法和Western blot法等,分别检测Epstein—Barr病毒(EBV)潜伏膜蛋白1(LMPl)诱导的c—myc反式激活活性和蛋白表达水平。从LMPl诱导细胞内c—myc表达的角度,探讨LMPl诱导端粒酶表达的分子机制。结果表明,LMPl促使细胞内c-myc反式激活活性增强,c-Myc蛋白表达量升高;导入反义LMPl表达质粒阻断LMPl表达后。c—myc反式激活活性下降。将端粒酶hTERT启动子上c—myc：结合位点突变后,LMP1不能诱导端粒酶hTERT表达。因而认为,EB病毒LMPl通过诱导c—mvc表达而活化端粒酶hTERT。     

携带绿色荧光报告基因的EBV-LMP1真核表达载体构建与鼻咽癌细胞中的表达

潜伏膜蛋白1(LMP1)是由EB病毒编码的致瘤蛋白,众多研究表明LMP1蛋白可通过NF-κB、p38 MAPK、c-JNK等多条重要信号通路引起鼻咽癌细胞的生物学行为改变。我们从EB病毒阳性的B95-8狨猴淋巴瘤细胞中克隆EB病毒LMP1 c DNA,构建携带绿色荧光基因的真核表达质粒p IRES2-Zs-Green1-LMP1,通过脂质体转染的方法将质粒导入鼻咽癌细胞株CNE1、CNE2中,利用质粒所携带的绿色荧光蛋白表达粗略计算转染的效率,通过免疫细胞化学(ICC)、RT-PCR、Western-Blot检测该质粒的表达。本实验室所构建的p IRES2-Zs-Green1-LMP1表达质粒能在鼻咽癌细胞内表达LMP1蛋白,为后续的实验研究奠定基础。     

肠道非何杰金淋巴瘤与EB病毒感染的相关性研究

目的：研究肠道非何杰金淋巴瘤(NHL)与EB病毒(EBV)感染相关性。方法：利用EBV寡核探针(EBER)原位杂交法检测EB病毒。结果：16例肠道NHL好发部位于小肠下端和结肠,以单发瘤结节多见,常伴有溃疡形成。经免疫组化证实3例为T细胞淋巴瘤(18．75％),13例为B细胞淋巴瘤(81．25％)。：EBV—EBER原位杂交3例有阳性表达,均为T细胞淋巴瘤,阳性细胞占肿瘤细胞的25％～75％。B细胞淋巴瘤未见阳性表达。结论：肠道非何杰金淋巴瘤以B细胞淋巴瘤多发,并以惰性淋巴瘤为多见;而T细胞淋巴瘤多为侵袭性,且与EBV感染的相关性较高,与B细胞淋巴瘤无相关性。     

EB 病毒LMP1 在肿瘤研究中的进展

EB病毒(Epstein-Barr virus,EBV)是具有致瘤潜能的疱疹病毒,与多种恶性肿瘤的发生相关。EB病毒编码的潜伏性膜蛋白1(Latent membrane protein-1,LMP1)作为其主要的致瘤蛋白,能通过细胞内多种信号传导通路,调节和控制细胞的生长、增殖、分化、迁移与凋亡,从而在癌变的发生和发展过程中发挥重要的作用。本文主要就LMP1的结构、生物学功能、介导的信号通路及其与肿瘤关系的相关进展做一阐述。     

Experimental infection of NOD/SCID mice reconstituted with human CD34+ cells with Epstein-Barr virus

Epstein-Barr virus (EBV)-induced lymphoproliferative disease is an important complication in the context of immune deficiency. Impaired T-cell immunity allows the outgrowth of transformed cells with the subsequent production of predominantly B-cell lymphomas. Currently there is no in vivo model that can adequately recapitulate EBV infection and its association with B-cell lymphomas. NOD/SCID mice engrafted with human CD34(+) cells and reconstituted mainly with human B lymphocytes may serve as a useful xenograft model to study EBV infection and pathogenesis. We therefore infected reconstituted mice with EBV. High levels of viral DNA were detected in the peripheral blood of all infected mice. All infected mice lost weight and showed decreased activity levels. Infected mice presented large visible tumors in multiple organs, most prominently in the spleen. These tumors stained positive for human CD79a, CD20, CD30, and EBV-encoded RNAs and were light chain restricted. Their characterization is consistent with that of large cell immunoblastic lymphoma. In addition, tumor cells expressed EBNA1, LMP1, and LMP2a mRNAs, which is consistent with a type II latency program. EBV(+) lymphoblastoid cell lines expressing human CD45, CD19, CD21, CD23, CD5, and CD30 were readily established from the bone marrow and spleens of infected animals. Finally, we also demonstrate that infection with an enhanced green fluorescent protein (EGFP)-tagged virus can be monitored by the detection of infected EGFP(+) cells and EGFP(+) tumors. These data demonstrate that NOD/SCID mice that are reconstituted with human CD34(+) cells are susceptible to infection by EBV and accurately recapitulate important aspects of EBV pathogenesis.     

Epstein-Barr virus gene expression in malignant lymphomas induced by experimental virus infection of cottontop tamarins.

Inoculation of cottontop tamarins with a large dose of Epstein-Barr virus (EBV) leads to the induction of multiple EBV genome-positive lymphomas. These tumors have been characterized as oligoclonal or monoclonal large-cell malignant lymphomas that closely resemble the EBV genome-positive B-cell lymphomas that arise in human allograft recipients. The expression of latent and lytic EBV-encoded proteins was investigated in these virus-induced tamarin lymphomas and in derived cell lines. The tamarin tumors were found to express EBV nuclear antigen 1 (EBNA 1), EBNA 2, EBNA leader protein, and the latent membrane protein (LMP) as determined both by immunohistochemical staining and by immunoblotting. However, within the limits of the immunoblotting assays, no expression of the EBNA 3a protein family could be detected. Assays for lytic-cycle proteins by using both polyclonal human sera and monoclonal antibodies against viral capsid antigen, early antigen, and membrane antigen (gp340/220) showed minimal, if any, expression of these antigens in the lymphoma biopsies. In contrast, the cell lines derived from these lymphomas, even in early passage, expressed abundant levels of the lytic-cycle antigens and also expressed the EBNA 3a protein as well as EBNA 1, EBNA 2, EBNA leader protein, and LMP. This finding suggests that the virus-lymphoma cell interaction, in particular the switch to lytic cycle, is subject to some form of host control in vivo. The expression of EBNA 2 and LMP in these tamarin lymphomas strengthens their resemblance to posttransplant lymphomas in humans, since these human tumors are also EBNA 2 and LMP positive (L. S. Young, C. Alfieri, K. Hennessy, H. Evans, C. O'Hara, K. Anderson, A. Rickinson, E. Kieff, and J. I. Cohen, submitted for publication). Since both proteins are known to be important effector molecules of virus-induced B-cell growth transformation in vitro, their expression in these lymphomas constitutes the best evidence for a direct oncogenic role for EBV in vivo.     

Differential immunogenicity of Epstein-Barr virus latent-cycle proteins for human CD4(+) T-helper 1 responses

Human CD4(+) T-helper 1 cell responses to Epstein-Barr virus (EBV) infection are likely to be important in the maintenance of virus-specific CD8(+) memory and/or as antiviral effectors in their own right. The present work has used overlapping peptides as stimulators of gamma interferon release (i) to identify CD4(+) epitopes within four EBV latent-cycle proteins, i.e., the nuclear antigens EBNA1 and EBNA3C and the latent membrane proteins LMP1 and LMP2, and (ii) to determine the frequency and magnitude of memory responses to these proteins in healthy virus carriers. Responses to EBNA1 and EBNA3C epitopes were detected in the majority of donors, and in the case of EBNA1, their antigen specificity was confirmed by in vitro reactivation and cloning of CD4(+) T cells using protein-loaded dendritic cell stimulators. By contrast, responses to LMP1 and LMP2 epitopes were seen much less frequently. EBV latent-cycle proteins therefore display a marked hierarchy of immunodominance for CD4(+) T-helper 1 cells (EBNA1, EBNA3C > LMP1, LMP2) which is different from that identified for the same proteins with respect to CD8(+)-T-cell responses (EBNA3C > EBNA1 > LMP2 > LMP1). Furthermore, the range of CD4(+) memory T-cell frequencies in peripheral blood of healthy virus carriers was noticeably lower and narrower than the corresponding range of latent antigen-specific CD8(+)-T-cell frequencies.     

Virus and cell RNAs expressed during Epstein-Barr virus replication

Changes in Epstein-Barr virus (EBV) and cell RNA levels were assayed following immunoglobulin G (IgG) cross-linking-induced replication in latency 1-infected Akata Burkitt B lymphoblasts. EBV replication as assayed by membrane gp350 expression was approximately 5% before IgG cross-linking and increased to more than 50% 48 h after induction. Seventy-two hours after IgG cross-linking, gp350-positive cells excluded propidium iodide as well as gp350-negative cells. EBV RNA levels changed temporally in parallel with previously defined sensitivity to inhibitors of protein or viral DNA synthesis. BZLF1 immediate-early RNA levels doubled by 2 h and reached a peak at 4 h, whereas BMLF1 doubled by 4 h with a peak at 8 h, and BRLF1 doubled by 8 h with peak at 12 h. Early RNAs peaked at 8 to 12 h, and late RNAs peaked at 24 h. Hybridization to intergenic sequences resulted in evidence for new EBV RNAs. Surprisingly, latency III (LTIII) RNAs for LMP1, LMP2, EBNALP, EBNA2, EBNA3A, EBNA3C, and BARTs were detected at 8 to 12 h and reached maxima at 24 to 48 h. EBNA2 and LMP1 were at full LTIII levels by 48 h and localized to gp350-positive cells. Thus, LTIII expression is a characteristic of late EBV replication in both B lymphoblasts and epithelial cells in immune-comprised people (J. Webster-Cyriaque, J. Middeldorp, and N. Raab-Traub, J. Virol. 74:7610-7618, 2000). EBV replication significantly altered levels of 401 Akata cell RNAs, of which 122 RNAs changed twofold or more relative to uninfected Akata cells. Mitogen-activated protein kinase levels were significantly affected. Late expression of LTIII was associated with induction of NF-kappaB responsive genes including IkappaBalpha and A20. The exclusion of propidium, expression of EBV LTIII RNAs and proteins, and up-regulation of specific cell RNAs are indicative of vital cell function late in EBV replication.     

An Epstein-Barr Virus (EBV) mutant with enhanced BZLF1 expression causes lymphomas with abortive lytic EBV infection in a humanized mouse model

Immunosuppressed patients are at risk for developing Epstein-Barr Virus (EBV)-positive lymphomas that express the major EBV oncoprotein, LMP1. Although increasing evidence suggests that a small number of lytically infected cells may promote EBV-positive lymphomas, the impact of enhanced lytic gene expression on the ability of EBV to induce lymphomas is unclear. Here we have used immune-deficient mice, engrafted with human fetal hematopoietic stem cells and thymus and liver tissue, to compare lymphoma formation following infection with wild-type (WT) EBV versus infection with a "superlytic" (SL) mutant with enhanced BZLF1 (Z) expression. The same proportions (2/6) of the WT and SL virus-infected animals developed B-cell lymphomas by day 60 postinfection; the remainder of the animals had persistent tumor-free viral latency. In contrast, all WT and SL virus-infected animals treated with the OKT3 anti-CD3 antibody (which inhibits T-cell function) developed lymphomas by day 29. Lymphomas in OKT3-treated animals (in contrast to lymphomas in the untreated animals) contained many LMP1-expressing cells. The SL virus-infected lymphomas in both OKT3-treated and untreated animals contained many more Z-expressing cells (up to 30%) than the WT virus-infected lymphomas, but did not express late viral proteins and thus had an abortive lytic form of EBV infection. LMP1 and BMRF1 (an early lytic viral protein) were never coexpressed in the same cell, suggesting that LMP1 expression is incompatible with lytic viral reactivation. These results show that the SL mutant induces an "abortive" lytic infection in humanized mice that is compatible with continued cell growth and at least partially resistant to T-cell killing.     

Reducing the complexity of the transforming Epstein-Barr virus genome to 64 kilobase pairs.

Transformation-competent, replication-defective Epstein-Barr virus (EBV) recombinants which are deleted for 18 kbp of DNA encoding the largest EBNA intron and for 58 kbp of DNA between the EBNA1 and LMP1 genes were constructed. These recombinants were made by transfecting three overlapping cosmid-cloned EBV DNA fragments into cells infected with a lytic replication-competent but transformation-defective EBV (P3HR-1 strain) and were identified by clonal transformation of primary B lymphocytes into lymphoblastoid cell lines. One-third of the lymphoblastoid cell lines were infected with recombinants which had both deletions and carried the EBNA2 and EBNA3 genes from the transfected EBV DNA and therefore are composed mostly or entirely from the transfected EBV DNA fragments. The deleted DNA is absent from cells infected with most of these recombinants, as demonstrated by Southern blot and sensitive PCR analyses for eight different sites within the deleted regions. Cell growth and EBNA, LMP, and BZLF1 gene expression in lymphoblastoid cell lines infected with these recombinants are similar to those in cells infected with wild-type EBV recombinants. Together with previous data, these experiments reduce the complexity of the EBV DNA necessary for transformation of primary B lymphocytes to 64 kbp. The approach should be useful for molecular genetic analyses of transforming EBV genes or for the insertion of heterologous fragments into transforming EBV genomes.     

EB病毒转化Hu－TLC－SCID小鼠脾细胞的实验研究

利用ＥＢ病毒转化可产生较高水平人ＩｇＧ和特异性抗２型登革病毒人抗体的Ｈｕ－ＴＬＣ－ＳＣＩＤ小鼠脾细胞,通过免疫组化、免疫荧光和ＰＣＲ法检测转化细胞的人Ｂ细胞表面标志、ＥＢ病毒抗原和ＥＢ病毒基因。结果表明,被转化的Ｈｕ－ＴＬＣ－ＳＣＩＤ小鼠脾细胞能继续产生抗２型登革病毒的特异性人抗体,并具有人Ｂ细胞的、ＳｍＩｇＧ标志及ＥＢ病毒潜伏膜蛋白－１（ＬＭＰ－１）基因,可表达ＬＭＰ－１和ＥＢ病毒核抗原（ＥＢＮＡ）。