Tightly associated lipids may anchor SV40 large T antigen in plasma membrane

Simian virus 40 (SV40) large T antigen, a multifunctional protein necessary for lytic growth and cell transformation, is located mainly in the nucleus and in small amounts on the cell surface (surface T). Surface T may have a passive role in SV40 tumour rejection by cytotoxic T cells as a component of SV40-TSTA (tumour-specific transplantation antigen). The unusual induction of this immune response by immunizing mice with soluble T antigen led us to investigate the in vitro binding of T antigen to the surface of living cells in more detail. Our results show that native surface T and a minor subset of large T antigen having a high cell surface binding affinity in vitro, behave like integral membrane proteins. Several viral proteins including SV40 T antigen and cellular proteins seem to be linked to fatty acids (acylation). To analyse whether this mechanism is involved in the stable attachment of in vitro-bound T antigen to the plasma membrane of living target cells, we determined the degree of labelling of this molecule by using target cells prelabelled with 3H-fatty acid. Here we report that T antigen extracted from unlabelled SV40-transformed cells (SV80) becomes 3H-labelled after in vitro binding to the cell surface of 3H-palmitate-prelabelled HeLa cells. These results suggest that T antigen attached externally to living cells, may be anchored by tightly linked lipids.     

Structure of the replicative helicase of the oncoprotein SV40 large tumour antigen

The oncoprotein large tumour antigen (LTag) is encoded by the DNA tumour virus simian virus 40. LTag transforms cells and induces tumours in animals by altering the functions of tumour suppressors (including pRB and p53) and other key cellular proteins. LTag is also a molecular machine that distorts/melts the replication origin of the viral genome and unwinds duplex DNA. LTag therefore seems to be a functional homologue of the eukaryotic minichromosome maintenance (MCM) complex. Here we present the X-ray structure of a hexameric LTag with DNA helicase activity. The structure identifies the p53-binding surface and reveals the structural basis of hexamerization. The hexamer contains a long, positively charged channel with an unusually large central chamber that binds both single-stranded and double-stranded DNA. The hexamer organizes into two tiers that can potentially rotate relative to each other through connecting alpha-helices to expand/constrict the channel, producing an 'iris' effect that could be used for distorting or melting the origin and unwinding DNA at the replication fork.     

A cellular protein that competes with SV40 T antigen for binding to the retinoblastoma gene product

Tumour-suppressor genes, such as the human retinoblastoma susceptibility gene (Rb), are widely recognized as being vital in the control of cell growth and tumour formation. This role is indicated, in part, by the suppression of tumorigenicity of human tumour cells after retrovirus-mediated Rb replacement. How Rb acts to bring about this suppression is not clear but one clue is that the Rb protein forms complexes with the transforming oncoproteins of several DNA tumour viruses, and that two regions of Rb essential for such binding frequently contain mutations in tumour cells. These observations suggest that endogenous cellular proteins might exist that bind to the same regions of Rb and thereby mediate its function. We report here the identification of one such human cellular Rb-associated protein of relative molecular mass 46,000 (46K) (RbAP46). Two lines of evidence support the notion that RbAP46 and simian virus 40 T antigen have homologous Rb-binding properties: first, several mutated Rb proteins that failed to bind to T also did not associate with RbAP46; and second, both T antigen and T peptide (amino acids 101-118) were able to compete with RbAP46 for binding to Rb. The apparent targeting of the RbAP46-Rb interaction by oncoproteins of DNA tumour viruses strongly suggests that formation of this complex is functionally important.     

p53 and DNA polymerase alpha compete for binding to SV40 T antigen

The large T antigen (T) of simian virus 40 is a multifunctional protein required for both viral DNA replication and cellular transformation. T antigen forms specific protein complexes with the host protein p53 in both virus-infected and transformed cells. p53 has recently been shown to be an oncogene, but its normal function is not clear. We previously established a radioimmunoassay to study the newly described complex between T antigen and DNA polymerase alpha, and have noted a similarity between the antigenic changes induced in T by the binding of both p53 and polymerase. We now extend this analysis to a larger collection of anti-T antibodies and formally establish that p53 and DNA polymerase alpha can compete for binding to the SV40 T antigen. At a critical concentration of the three components it is possible to detect a trimeric complex of T, p53 and DNA polymerase alpha. Our observations have important implications for the control by these nuclear oncogenes of viral and cellular DNA synthesis and viral host range in both normal and transformed cells. We present a model for the action of p53 in growth control.     

Phosphorylation of large tumour antigen by cdc2 stimulates SV40 DNA replication

Simian virus 40 large tumour antigen (T) is a replication origin binding protein required for viral DNA synthesis. Unphosphorylated T antigen is deficient in promoting DNA replication in vitro but can be activated by phosphorylation at residue threonine 124 by the cdc2 protein kinase. This observation demonstrates that T is regulated by phosphorylation and provides a model for cdc2 function in the control of DNA replication.     

慢病毒载体介导SV40LT致人脐静脉内皮细胞永生化

为成功分离与鉴定人原代脐静脉内皮细胞,用猿猴病毒40大T抗原(SV40LT)异位表达建立永生化人脐静脉内皮细胞系。将含SV40LT cDNA片段的慢病毒载体,转染人原代脐静脉内皮细胞,连续传代培养。通过形态、细胞免疫组织化学、RT-PCR及管状成形试验进行原代及转染后细胞形态学和功能学鉴定及检测SV40大T抗原表达。结果SV40LT转染后的人脐静脉内皮细胞为扁平多角形或短梭状,呈单层铺路石状镶嵌排列。特异性表达Ⅷ因子、KDR、SV40LT表达,并具有管状成型能力。说明成功分离与鉴定永生化的脐静脉内皮细胞系,为后续血管靶向治疗奠定了基础。     

ATP-dependent assembly of double hexamers of SV40 T antigen at the viral origin of DNA replication

Simian virus 40 (SV40) replicates in nuclei of human and monkey cells. One viral protein, large tumour (T) antigen, is required for the initiation of DNA replication. The development of in vitro replication systems which retain this property has facilitated the identification of the cellular components required for replication. T antigen recognizes the pentanucleotide 5'-GAGGC-3' which is present in four copies within the 64 base-pairs (bp) of the core origin. In the presence of ATP it binds with increased affinity forming a distinctive, bilobed structure visible in electron micrographs. As a helicase, it unwinds SV40 DNA bidirectionally from the origin. We report here that in vitro and in the presence of ATP, T antigen assembles a double hexamer, centred on the core origin and extending beyond it by 12 bp in each direction. The assembly of this dodecamer initiates an untwisting of the duplex by 2-3 turns. In the absence of ATP, a tetrameric structure is the largest found at the core origin. In the absence of DNA, but in the presence of ATP or its non-hydrolysable analogues, T antigen assembles into hexamers. This suggests that ATP effects an allosteric change in the monomer. The change alters protein-protein interactions and allows the assembly of a double hexamer, which initiates replication at the core origin.     

N-Acetoxy-acetylaminofluorene reacts preferentially with a control region of intracellular SV40 chromosome

Many chemical carcinogens or their metabolites react with DNA; thus it is of interest to determine what effect chromosomal structure has on these reactions. The chromosome of simian virus 40 (SV40) is well suited for such studies; like chromatin of eukaryotic cells, it is organized into nucleosomes. The nucleotide sequence of SV40 is known, together with much about the pattern of viral gene expression and DNA replication, and the structure of the viral chromosome. We have investigated the binding of the ultimate carcinogen, N-acetoxy-acetylaminofluorene (AAAF), to specific regions of the SV40 chromosome in situ in the intact infected cell. The results, reported here, indicate that a region containing regulatory functions on the intracellular SV40 chromosome has unique structural properties which render it more susceptible to attack by AAAF than the rest of the SV40 genome. The preferential binding of AAAF to regulatory regions of chromatin may have implications for the mechanism of action of this and similar carcinogens.     

Structure of domain 1 of rat T lymphocyte CD2 antigen.

The CD2 antigen is largely restricted to cells of the T-lymphocyte lineage and has been established as an important adhesion molecule in interactions between human T lymphocytes and accessory cells. In the adhesion reaction, CD2 on T cells binds to LFA-3 on other cells, with binding through domain 1 of CD2. CD2 can also be a target for the delivery of mitogenic signals to T lymphocytes cultured with combinations of anti-CD2 antibodies. Two predictions that are contradictory have been made for the structure of CD2 domain 1. One suggests an immunoglobulin (Ig) fold, on the basis of sequence patterns conserved in the Ig-superfamily (IgSF), whilst the other proposes a pattern of alternating alpha-helices and beta-strands, on the basis of secondary structure predictions. Thus CD2 domain 1 is an important test case for the validity of IgSF assignments based on sequence patterns. We report here the expression of domain 1 of rat CD2 in an Escherichia coli expression system and have determined a low-resolution solution structure by NMR spectroscopy.     

A transforming mutation in the pleckstrin homology domain of AKT1 in cancer

Although AKT1 (v-akt murine thymoma viral oncogene homologue 1) kinase is a central member of possibly the most frequently activated proliferation and survival pathway in cancer, mutation of AKT1 has not been widely reported. Here we report the identification of a somatic mutation in human breast, colorectal and ovarian cancers that results in a glutamic acid to lysine substitution at amino acid 17 (E17K) in the lipid-binding pocket of AKT1. Lys 17 alters the electrostatic interactions of the pocket and forms new hydrogen bonds with a phosphoinositide ligand. This mutation activates AKT1 by means of pathological localization to the plasma membrane, stimulates downstream signalling, transforms cells and induces leukaemia in mice. This mechanism indicates a direct role of AKT1 in human cancer, and adds to the known genetic alterations that promote oncogenesis through the phosphatidylinositol-3-OH kinase/AKT pathway. Furthermore, the E17K substitution decreases the sensitivity to an allosteric kinase inhibitor, so this mutation may have important clinical utility for AKT drug development.