P53-transformation-related protein: kinetics of synthesis and accumulation in SV40-infected primary mouse kidney cell cultures

Establishment of a conditionally immortalized mouse optic nerve astrocyte line

Optic nerve astrocytes play a major role in axonal degeneration and regeneration. Astrocyte lines are an important tool to elucidate the responsible cellular mechanisms. In this study, we established a conditionally immortalized mouse optic nerve astrocyte line. Astrocytes were cultured from explants derived from postnatal day 4-5 H-2k^b-tsA58 transgenic mouse optic nerves. Cells were cultured in defined astrocyte culture medium under permissive (33 °C) or non-permissive (38.5 °C) temperatures with or without interferon-ɤ (IFN-ɤ). Astrocytes were characterized by immunocytochemistry staining using antibodies against glial fibrillary acidic protein (GFAP) and neural cell adhesion molecule (NCAM). Cell proliferation rates were determined by cell growth curves and percentage of Ki67 positive cells. Karyotyping was performed to validate the mouse origin of established cell line. Conditional immortalization was assessed by western blot-determined expression levels of SV40 large T antigen (TAg), p53, GFAP and NCAM in non-permissive culture conditions. In addition, phagocytic activity of immortalized cells was determined by flow cytometry-based pHrodo fluorescence analysis. After 5 days in culture, cells migrated out from optic nerve explants. Immunocytochemistry staining showed that migrating cells expressed astrocyte makers, GFAP and NCAM. In permissive conditions, astrocytes had increased expression levels of TAg and p53, exhibited a greater cell proliferation rate as well as a higher percentage of Ki67 positive cells (n = 3, p < 0.05) compared to cells cultured in non-permissive conditions. One cell line (ImB1ON) was further maintained through 60 generations. Karyotyping showed that ImB1ON was of mouse origin. Flow cytometry-based pHrodo fluorescence analysis demonstrated phagocytic activity of ImB1ON cells. Quantitative PCR showed mRNA expression of trophic factors. Non-permissive culture conditions decreased expression of TAg and p53 in ImB1ON, and increased the expression of NCAM. A conditionally immortalized mouse optic nerve astrocyte line was established. This cell line provides an important tool to study astrocyte biological processes.

Disruption of LT-antigen/p53 complex by heat treatment correlates with inhibition of DNA synthesis during transforming infection with SV40

Transforming infection of Go/G1-arrested primary mouse kidney cell cultures with simian virus 40 (SV40) induces cells to re-enter the S-phase of the cell cycle. In Go-arrested cells, no p53 is detected, whereas in cells induced to proliferate by infection, a gradual accumulation of p53 complexed to SV40 large T-antigen is observed in the nucleus. Heat treatment of actively proliferating SV40-infected cells leads to inhibition of DNA synthesis and growth arrest. To determine the fate of p53 after heat treatment, proliferating infected cells were exposed to mild heat (42.5°C) for increasing lengths of time. The results presented here show that after ninety minutes of treatment, the arrest of DNA synthesis by heat correlates with the disruption of the p53/LT-antigen complex. Longer treatments induce, in addition, a reduction in the solubility of p53, which was recovered tightly associated with the nuclear fraction. This contrasted with large T-antigen, whose solubility remained unaffected by heat treatment. Although the total amount of p53 in the nucleus remained constant, as shown by immunoblot analyses, p53 was no longer detectable after immunoprecipitation or by immunofluorescent staining techniques. These results suggest that heat treatment had either induced conformational changes in its antigenic sites, or had sequestered the sites through aggregation or binding to insoluble nuclear components.Key words: p53, heat shock, LT-antigen/p53 complex, S-phase.

The adenovirus oncoprotein E1a stimulates binding of transcription factor ETF to transcriptionally activate the p53 gene

Expression of the tumor suppressor protein p53 plays an important role in regulating the cellular response to DNA damage. During adenovirus infection, levels of p53 protein also increase. It has been shown that this increase is due not only to increased stability of the p53 protein but to the transcriptional activation of the p53 gene during infection. We demonstrate here that the E1a proteins of adenovirus are responsible for activating the mouse p53 gene and that both major E1a proteins, 243R and 289R, are required for complete activation. E1a brings about the binding of two cellular transcription factors to the mouse p53 promoter. One of these, ETF, binds to three upstream sites in the p53 promoter and one downstream site, whereas E2F binds to one upstream site in the presence of E1a. Our studies indicate that E2F binding is not essential for activation of the p53 promoter but that ETF is. Our data indicate the ETF site located downstream of the start site of transcription is the key site in conferring E1a responsiveness on the p53 promoter.

Identification of an upstream region of the mouse p53 promoter critical for transcriptional expression

We have investigated the transcription factor requirements for basal expression of the mouse p53 promoter by using a combination of reporter and electrophoretic mobility shift assays (EMSAs). We have found that only four regions of the promoter bind transcription factors in EMSAs, suggesting that these are the only important factors for basal transcription. These factors are NF1, USF, ETF-like and a novel factor which we have called PF2. Construction of promoter deletion mutants has shown that the absence of the PF2 site completely inactivates the promoter, whereas deletion of other sites, whilst reducing promoter activity, does not. We suggest that this novel transcription factor (PF2) is critical for expression of the mouse p53 promoter.

Stabilization of the tumor suppressor p53 during cellular transformation by simian virus 40: influence of viral and cellular factors and biological consequences

To understand the process and biological significance of metabolic stabilization of p53 during simian virus 40 (SV40)-induced cellular transformation, we analyzed cellular and viral parameters involved in this process. We demonstrate that neither large T expression as such nor the cellular phenotype (normal versus transformed) markedly influence the stability of p53 complexed to large T in SV40 abortively infected BALB/c mouse fibroblasts. In contrast, metabolic stabilization of p53 is an active cellular event, specifically induced by SV40. The ability of SV40 to induce a cellular response leading to stabilization of p53 complexed to large T is independent from the cellular phenotype and greatly varies between different cells. However, metabolic stability was conferred only to p53 in complex with large T, whereas the free p53 in these cells remained metabolically unstable. Comparative analyses of cellular transformation in various cells differing in stability of p53 complexed to large T upon abortive infection with SV40 revealed a strong correlation between the ability of SV40 to induce metabolic stabilization and its transformation efficiency. Our data suggest that metabolic stabilization and the ensuing enhanced levels of p53 are important for initiation and/or maintenance of SV40 transformation.

Immunological evidence for the association between simian virus 40 115-kDa super T antigen and hsp70 proteins in rat, monkey, and human cells

Immunological evidence was provided that in subclone 7 cell line, which is derived from SV40 transformed cells, 115-kDa super T antigen, a transformation-competent, elongated form of large T antigen was physically complexed with hsp70 proteins. This conclusion was first based on the coimmunoprecipitation from unstressed or heat shocked subclone 7 cells of both super T antigen and hsp70 proteins. This was observed with any one of a set of anti-T monoclonal antibodies reacting to determinants located either in the C-terminal region or in the N terminal region. Reciprocally coimmunoprecipitation of both hsp70 and super T was also observed in the anti-hsp70 peptide serum-immunoprecipitate. The formation of complexes between hsp70 proteins and super T antigen in subclone 7 cells was also confirmed by Western blot experiments. Moreover, when expressed in cell lines originating from human (Hela cells) or monkey (CV1P cells) species following transfection with the relevant plasmid, super T antigen again displayed the ability to associate with hsp70 proteins. Considering that super T antigen was obtained in laboratory experiments as a stable evolutionary variant of SV40 large T antigen, it is suggested that the marked ability of super T antigen to associate with heat shock protein could be selectively advantageous under certain conditions.

Correlation of DNA content, p53, T antigen, and V antigen in simian virus 40-infected human diploid cells

Human diploid fibroblasts (HDF) have a finite life span in cell culture which can be extended when transformed with simian virus 40 (SV40). Flow cytometric analysis of SV40-HDF transformation allowed DNA content changes to be correlated with the appearance, quantity, and distribution of T antigen, p53, and V antigen, three proteins associated with this process. These studies demonstrated a shift in the DNA content to tetraploidy, which was correlated with the age of the SV40-HDF but not the time of infection. A significant increase of the epitope recognized by PAb122 to host p53 and the epitope PAb101 to SV40 T antigen occurred at the same time the tetraploid population appeared. However, an antigen reactive with SV40 V antibody was present at high levels in most of the population early after infection, but the levels declined with time. The percentage of PAb101-T antigen-positive cells increased more rapidly in cells infected at a late passage, and this was concomitant with the shift in DNA content to tetraploid. Analysis of the mean fluorescence of total, gated populations (G1, G2, and greater than G2) demonstrated that a threshold level of p53 and T antigen was reached in each compartment of the cell cycle. As the transformed phenotype appeared, a population of cells was continually released into the supernatant, and although these cells had a DNA pattern similar to the monolayer cells, the T antigen and p53 levels were 3-5 times higher in the tetraploid G2 cells. These studies correlated the expression of proteins associated with viral transformation in HDF which vary with time and shift in DNA content.

Intranuclear distribution of SV40 large T-antigen and transformation-related protein p53 in abortively infected cells

The intranuclear localization of SV40 T-antigen (T-Ag) and the cellular protein p53 was studied in SV40 abortively infected baby mouse kidney cells using two complementary methods of ultrastructural immunocytochemistry in combination with preferential staining of nuclear RNP components and electron microscope autoradiography. Both proteins were revealed in association with peri- and interchromatin RNP fibrils containing the newly synthesized hnRNA. In addition, T-Ag and p53 remained bound, at least in part, to the residual internal nuclear matrix following nuclease and salt extractions of infected cells. The localization of T-Ag was different in SV40 lytically infected monkey kidney cells since, in addition to hnRNP fibrils, the viral protein was also associated with cellular chromatin. However, when lytic infection was performed in conditions of blocked viral DNA replication, T-Ag was no longer associated with the cellular chromatin but remained bound to the hnRNP fibrils. We conclude that the transforming and lytic functions of T-Ag can be distinguished by different subnuclear distributions. The significance of the association of T-Ag and p53 with hnRNP fibrils and the internal nuclear matrix is discussed in relation to the role of these structures in the control of cellular mRNA biogenesis.

The transformation-related protein p53 is not bound to the SV40 T antigen in BALB 3T12 cells expressing T antigen

In most murine cells transformed by the SV40 virus, virtually all of the cellular phosphoprotein p53 is in a complex with the SV40 T antigen. Here, we report that, in SV40-infected T-antigen-positive Balb 3T12 mouse cells, most (approximately 80%) of the p53 is not in complex. Complex formation was determined by measuring the amounts of [35S]methionine-labeled p53 which coprecipitated with T antigen when using monoclonal antibody to T antigen. The amount of complex formation was expressed as a percentage of total p53 present, measured by the amount of p53 precipitated with the monoclonal antibody to the p53. The values were confirmed by Western blotting procedure, in which the steady-state levels of the proteins were measured. In these measurements after complete precipitation with antibody to T antigen, the residual p53 in the supernatant was precipitated by antibody to p53, and this amount was denoted as free p53. There was no significant difference seen between the [35S]methionine-labeled tryptic peptides of complexed and the free p53 (or between complexed and free T antigens) as determined by two-dimensional gel electrophoresis and chromatography. Virus rescue experiments and retransformation by the rescued virus showed that there was no mutation in the SV40 DNA coding for the T antigen which could account for the lack of complex formation. Both p53 and T antigen were underphosphorylated in cells which exhibited reduced complex formation. Tumorigenicity in syngeneic mice and anchorage-independent cell growth in culture of various cloned mouse cells with or without T antigen expression was compared. The changes in the biologic properties were explainable solely on the basis of known or expected effects of expression of the T antigen and were independent of complex formation or of absence of complex formation between p53 and T antigen.

DNA-binding properties of the major structural protein of simian virus 40

We investigated whether the VP1 protein of simian virus 40 binds to DNA. In vitro DNA-binding experiments clearly indicate that VP1 bound strongly to double-stranded and single-stranded DNA, with a higher affinity for the latter; additional experiments show that VP1 did not bind to a specific sequence of simian virus 40 DNA.