"Hit-and-run" transformation by adenovirus oncogenes

According to classical concepts of viral oncogenesis, the persistence of virus-specific oncogenes is required to maintain the transformed cellular phenotype. In contrast, the "hit-and-run" hypothesis claims that viruses can mediate cellular transformation through an initial "hit," while maintenance of the transformed state is compatible with the loss ("run") of viral molecules. It is well established that the adenovirus E1A and E1B gene products can cooperatively transform primary human and rodent cells to a tumorigenic phenotype and that these cells permanently express the viral oncogenes. Additionally, recent studies have shown that the adenovirus E4 region encodes two novel oncoproteins, the products of E4orf6 and E4orf3, which cooperate with the viral E1A proteins to transform primary rat cells in an E1B-like fashion. Unexpectedly, however, cells transformed by E1A and either E4orf6 or E4orf3 fail to express the viral E4 gene products, and only a subset contain E1A proteins. In fact, the majority of these cells lack E4- and E1A-specific DNA sequences, indicating that transformation occurred through a hit-and-run mechanism. We provide evidence that the unusual transforming activities of the adenoviral oncoproteins may be due to their mutagenic potential. Our results strongly support the possibility that even tumors that lack any detectable virus-specific molecules can be of viral origin, which could have a significant impact on the use of adenoviral vectors for gene therapy.     

The efficiency of adenovirus transformation of rodent cells is inversely related to the rate of viral E1A gene expression.

While the products of the type 5 adenovirus E1A and E1B genes can initiate pathways leading to a transformed rodent cell, little is known about how the rate of viral early gene expression influences the efficiency of this process. An adenovirus mutant [E1a(r) virus] that expresses its viral E1A and E1B genes at as much as a 100-fold-reduced rate relative to wild-type virus in infected CREF or HeLa cells transforms CREF cells at an 8-fold-higher efficiency than wild-type virus. Additional studies show that the reduction in viral E1A gene expression is solely responsible for this transformation phenotype, and at this low rate of viral E1A gene expression both E1A gene products must be expressed. Unlike previously characterized viruses which transform CREF cells at frequencies greater than wild-type virus, the foci obtained following E1a(r) virus infection were indistinguishable from those arising from wild-type virus by several criteria (morphological characteristics and anchorage-independent growth). Surprisingly, an analysis of viral early gene expression from a panel of wild-type- and E1a(r) virus-transformed CREF cell lines showed similar average rates of both viral E1A and E1B gene expression. By using an adenovirus-transformed cell line that is cold-sensitive for maintenance of the transformed cell phenotype, we show that both wild-type and the E1a(r) viruses can transform these cells at equally high efficiencies at the nonpermissive temperature of 32 degrees C. Our findings suggest that the process leading to a fully transformed cell involves multiple stages, with an early stage being facilitated by a reduced rate of viral E1A gene expression.     

Isolation of coronavirus envelope glycoproteins and interaction with the viral nucleocapsid.

The two envelope glycoproteins and the viral nucleocapsid of the coronavirus A59 were isolated by solubilization of the viral membrane with Nonidet P-40 at 4 degrees C followed by sucrose density gradient sedimentation. Isolated E2 consisted of rosettes of peplomers, whereas E1, the membrane glycoprotein, was irregular and amorphous. Under certain conditions significant interactions occurred between components of Nonidet P-40-disrupted virions. Incubation of the Nonidet P-40-disrupted virus at 37 degrees C resulted in formation of a complex between one of the viral glycoproteins, E1, and the viral nucleocapsid. This was caused by a temperature-dependent conformational change in E1, resulting in aggregation of E1 and interaction with the viral RNA in the nucleocapsid. E1 also bound rRNA. The E1-nucleocapsid complexes can be distinguished on sucrose and Renografin density gradients from native viral nucleocapsids. The separation of the membrane glycoprotein E1 from the peplomeric glycoprotein E2 permitted preparation of antisera against these isolated proteins. A model is proposed for the arrangement of the three major structural proteins in the coronavirus A59 virion in relation to the viral envelope and RNA.     

人乳头瘤病毒16型长控制区上YY1结合位点的破坏可增强病毒诱导细胞永生化能力

细胞转录调节因子 Ｙ Ｙ１ 可抑制人乳头瘤病毒１６ 型（ Ｈ Ｐ Ｖ １６） 癌基因启动子 Ｐ９７ 的活性, Ｙ Ｙ１ 位点的突变和缺失不仅可诱导 Ｐ９７ 活性增强而且可在全基因组内增强 Ｅ６ 癌基因转录,同时使病毒对啮齿类动物纤维细胞的转化能力增强。为了观测人乳头瘤病毒１６ 型长控制区（ Ｈ Ｐ Ｖ１６ Ｌ Ｃ Ｒ） 序列上 Ｙ Ｙ１ 蛋白特异性结合位点破坏在完整基因组范围内对人原代包皮角源细胞永生化能力的影响,将 Ｈ Ｐ Ｖ １６ Ｙ Ｙ１ 位点突变株和野毒株转染至人原代包皮角源细胞。筛选结果表明,突变株可诱导形成永生化细胞,永生化能力明显高于野毒株。对４ 株永生化细胞系 Ｄ Ｎ Ａ检测发现,均含有呈整合状态的 Ｈ Ｐ Ｖ １６ Ｄ Ｎ Ａ,其中３ 株的 Ｅ１／ Ｅ２ 区域有缺失。 Ｒ Ｎ Ａ 检测显示,４株细胞内均有 Ｅ６／ Ｅ７ ｍ Ｒ Ｎ Ａ 的转录。这表明, Ｈ Ｐ Ｖ １６ Ｌ Ｃ Ｒ 上 Ｙ Ｙ１ 蛋白特异性结合位点的破坏,可在完整基因组范围内增强病毒使人原代包皮角源细胞永生化的能力。     

Papillomavirus E2 induces senescence in HPV-positive cells via pRB- and p21(CIP)-dependent pathways

A hallmark of human papillomavirus (HPV) associated carcinogenesis is the integration of the viral DNA into the cellular genome, usually accompanied by the loss of expression of the viral E2 gene. E2 binds to and represses the viral promoter directing expression of the E6 and E7 oncogenes. The re-introduction and expression of exogenous E2 in HPV-positive cancer cells results in cellular growth arrest, while growth in the context of exogenous E2 can be restored through the expression of exogenous E6 and E7. Here we examine the individual contributions of the viral E6 and E7 genes to this phenotype. E6 alone displays moderate activity, whereas both E7 and adenovirus E1A display high activity in reversing E2-mediated cellular growth suppression. Using defined mutants of E7 and E1A, we show that an intact retinoblastoma interaction domain is required for this function. In addition, we show that the E2-mediated growth arrest of HPV-positive cells results in cellular senescence, and implicate the cyclin/cdk inhibitor p21(CIP) as a downstream E2 effector in this phenotype.     

DNA Replication of Human Papillomavirus Type 31 Is Modulated by Elements of the Upstream Regulatory Region That Lie 5′ of the Minimal Origin

The viral replication factors E1 and E2 of papillomaviruses are necessary and sufficient to replicate plasmids containing the minimal origin of DNA replication in transient assays. Under physiological conditions, the upstream regulatory region (URR) governs expression of the early viral genes. To determine the effect of URR elements on E1 and E2 expression specifically, and on the regulation of DNA replication during the various phases of the viral life cycle, we carried out a systematic replication study with entire genomes of human papillomavirus type 31 (HPV31), a high-risk oncogenic type. We constructed a series of URR deletions, spacer replacements, and point mutations to analyze the role of the keratinocyte enhancer (KE) element, the auxiliary enhancer (AE) domain, and the L1-proximal end of the URR (5′-URR domain) in DNA replication during establishment, maintenance, and vegetative viral DNA amplification. Using transient and stable replication assays, we demonstrate that the KE and AE are necessary for efficient E1 and E2 gene expression and that the KE can also directly modulate viral replication. KE-mediated activation of replication is dependent on the position and orientation of the element. Mutation of either one of the four Ap1 sites, the single Sp1 site, or the binding site for the uncharacterized footprint factor 1 reduced replication efficiency through decreased expression of E1 and E2. Furthermore, the 5′-URR domain and the Oct1 DNA binding site are dispensable for viral replication, since such HPV31 mutants are able to replicate efficiently in a transient assay, maintain a stable copy number over several cell generations, and amplify viral DNA under vegetative conditions. Interestingly, deletion of the 5′-URR domain leads to increased transient and stable replication levels. These findings suggest that elements in the HPV31 URR outside the minimal origin modulate viral replication through both direct and indirect mechanisms.     

Human papillomavirus type 16 E1 E4-induced G2 arrest is associated with cytoplasmic retention of active Cdk1/cyclin B1 complexes

Human papillomavirus type 16 (HPV16) can cause cervical cancer. Expression of the viral E1 E4 protein is lost during malignant progression, but in premalignant lesions, E1 E4 is abundant in cells supporting viral DNA amplification. Expression of 16E1 E4 in cell culture causes G2 cell cycle arrest. Here we show that unlike many other G2 arrest mechanisms, 16E1 E4 does not inhibit the kinase activity of the Cdk1/cyclin B1 complex. Instead, 16E1 E4 uses a novel mechanism in which it sequesters Cdk1/cyclin B1 onto the cytokeratin network. This prevents the accumulation of active Cdk1/cyclin B1 complexes in the nucleus and hence prevents mitosis. A mutant 16E1 E4 (T22A, T23A) which does not bind cyclin B1 or alter its intracellular location fails to induce G2 arrest. The significance of these results is highlighted by the observation that in lesions induced by HPV16, there is evidence for Cdk1/cyclin B1 activity on the keratins of 16E1 E4-expressing cells. We hypothesize that E1 E4-induced G2 arrest may play a role in creating an environment optimal for viral DNA replication and that loss of E1 E4 expression may contribute to malignant progression.