The retinoblastoma protein alters the phosphorylation state of polyomavirus large T antigen in murine cell extracts and inhibits polyomavirus origin DNA replication.

The retinoblastoma tumor suppressor protein (pRb) can associate with the transforming proteins of several DNA tumor viruses, including the large T antigen encoded by polyomavirus (Py T Ag). Although pRb function is critical for regulating progression from G1 to S phase, a role for pRb in S phase has not been demonstrated or excluded. To identify a potential effect of pRb on DNA replication, pRb protein was added to reaction mixtures containing Py T Ag, Py origin-containing DNA (Py ori-DNA), and murine FM3A cell extracts. We found that pRb strongly represses Py ori-DNA replication in vitro. Unexpectedly, however, this inhibition only partially depends on the interaction of pRb with Py T Ag, since a mutant Py T Ag (dl141) lacking the pRb interaction region was also significantly inhibited by pRb. This result suggests that pRb interferes with or alters one or more components of the murine cell replication extract. Furthermore, the ability of Py T Ag to be phosphorylated in such extracts is markedly reduced in the presence of pRb. Since cyclin-dependent kinase (CDK) phosphorylation of Py T Ag is required for its replication function, we hypothesize that pRb interferes with this phosphorylation event. Indeed, the S-phase CDK complex (cyclin A-CDK2), which phosphorylates both pRb and Py T Ag, alleviates inhibition caused by pRb. Moreover, hyperphosphorylated pRb is incapable of inhibiting replication of Py ori-DNA in vitro. We propose a new requirement for maintaining pRb phosphorylation in S phase, namely, to prevent deleterious effects on the cellular replication machinery.

The subcellular locations of p15(Ink4b) and p27(Kip1) coordinate their inhibitory interactions with cdk4 and cdk2.

In dividing cells, p27(Kip1) is predominantly bound to cyclin D-cdk4 without inhibiting this kinase. Upon being induced by TGF-beta or with a conditional expression system in lung epithelial cells, p15(Ink4b) binds to and inhibits the cyclin D-dependent kinases, prevents p27 binding to these cdk complexes, and promotes p27 binding and inhibition of cyclin-cdk2. In vitro, however, p15 prevents p27 binding only if it has access to cyclin D-cdk4 first. We present evidence that the different subcellular location of p15 and p27 ensures the prior access of p15 to cdk4. In the cell, p15 is localized mostly in the cytoplasm, whereas p27 is nuclear. p15 prevails over p27 or a p27 construct consisting of the cdk inhibitory domain tagged with a nuclear localization signal. However, when p15 and p27 are forced to reside in the same subcellular location, either the cytoplasm or the nucleus, p15 no longer prevents p27 from binding to cdk4. These properties allow p15 and p27 to coordinately inhibit cdk4 and cdk2.

Kip/Cip and Ink4 Cdk inhibitors cooperate to induce cell cycle arrest in response to TGF-beta.

G1 progression in mammalian cells requires the activity of the cyclin D-dependent kinases Cdk4 and/or Cdk6 and the cyclin E-dependent kinase Cdk2. Proliferating Mv1Lu mink lung epithelial cells and human keratinocytes contain high levels of the universal Cdk inhibitor p27Kip1 distributed in complexes with Cdk2, Cdk4, and Cdk6. Addition of the antimitogenic cytokine transforming growth factor-beta (TGF-beta) elevates expression of the Cdk4/6-specific inhibitor p15Ink4B and induces the release of p27 from Cdk4 and Cdk6. In Mv1Lu cells, this release of p27 coincides with increased binding of p27 to Cdk2. Recombinant p15 inhibits p27 binding to Cdk4 in vitro, and p15 overexpression induces the transfer of p27 from Cdk4 to Cdk2 in vivo, suggesting that the release of Cdk4-bound p27 in TGF-beta-treated cells is caused by the surge in p15 levels. In keratinocytes, TGF-beta increases not only p15 but also p21Cip1, which binds to Cdk2. These events correlate with Cdk2 inhibition and cell cycle arrest and occur without a loss of G1 Cdk components. The results suggest that TGF-beta induces G1 arrest in these two epithelial cell types by inhibiting various cyclin-Cdk kinases through the cooperative action of an Ink4 Cdk inhibitor and a Cip/Kip Cdk inhibitor. Subsequent to cell cycle arrest, Cdk2 and Cdk4 levels decline as part of a second set of events that may represent a program of cell adaptation to the quiescent state.

Cloning of p57KIP2, a cyclin-dependent kinase inhibitor with unique domain structure and tissue distribution.

Progression through the cell cycle is catalyzed by cyclin-dependent kinases (CDKs) and is negatively controlled by CDK inhibitors (CDIs). We have isolated a new member of the p21CIP1/p27KIP1 CDI family and named it p57KIP2 to denote its apparent molecular mass and higher similarity to p27KIP1. Three distinct p57 cDNAs were cloned that differ at the start of their open reading frames and correspond to messages generated by the use of distinct splice acceptor sites. p57 is distinguished from p21 and p27 by its unique domain structure. Four distinct domains follow the heterogeneous amino-terminal region and include, in order, a p21/p27-related CDK inhibitory domain, a proline-rich (28% proline) domain, an acidic (36% glutamic or aspartic acid) domain, and a carboxy-terminal nuclear targeting domain that contains a putative CDK phosphorylation site and has sequence similarity to p27 but not to p21. Most of the acidic domain consists of a novel, tandemly repeated 4-amino acid motif. p57 is a potent inhibitor of G1- and S-phase CDKs (cyclin E-cdk2, cyclin D2-cdk4, and cyclin A-cdk2) and, to lesser extent, of the mitotic cyclin B-Cdc2. In mammalian cells, p57 localizes to the nucleus, associates with G1 CDK components, and its overexpression causes a complete cell cycle arrest in G1 phase. In contrast to the widespread expression of p21 and p27 in human tissues, p57 is expressed in a tissue-specific manner, as a 1.5-kb species in placenta and at lower levels in various other tissues and a 7-kb mRNA species observed in skeletal muscle and heart. The expression pattern and unique domain structure of p57 suggest that this CDI may play a specialized role in cell cycle control.

Phosphorylation and active ATP hydrolysis are not required for SV40 T antigen hexamer formation.

ATP induces structural alterations in SV40 large T antigen and promotes changes in its interaction with the viral replication origin. We have analyzed nucleotide-induced changes in T antigen structure in the absence of origin DNA. Most preparations of immunopurified T antigen contain several discrete species ranging in size from monomers through oligomers larger than hexamers. The predominant species consist of monomers and dimers. Incubation of T antigen with ATP or dATP leads to a dramatic and rapid increase in the appearance of T antigen hexamers. Weakly and nonhydrolyzable analogs of ATP are effective as well, indicating that hexamer formation does not require active ATP hydrolysis. After incubation of T antigen with [gamma-35S]ATP, stable association of the labeled nucleotide with all detectable forms occurs. Removal of greater than 80% of the T antigen phosphate residues does not significantly affect the formation of T antigen hexamers, although changes in the distribution and mobility of the other species of T antigen are apparent. Furthermore, T antigen synthesized in and purified from Escherichia coli and, therefore, presumably un- or underphosphorylated, is capable of forming hexamers. Nucleotide-induced T antigen hexamer formation thus appears to require neither protein phosphorylation nor active ATP hydrolysis.

Unusual properties of a replication-defective mutant SV40 large T antigen.

The C11A mutant of SV40 large T antigen is unable to support the replication of viral origin containing DNA (ori-DNA) in vivo or in vitro. The mutation within C11A at residue 522 (pro-->ser) is located within the presumptive ATPase region of T antigen. While C11A T antigen was previously reported to be defective in ATPase and DNA helicase activities, it was shown to be capable of binding specifically to DNA containing the viral replication origin. As the positions of many conditional mutations of SV40 T antigen are located within the ATPase domain we asked whether C11A might also exhibit temperature-sensitive defects. We found that several activities of C11A T antigen are conditionally defective. C11A T antigen was able to hydrolyze ATP, assemble into hexamers, and display ATP-dependent alterations in DNA binding and ori-DNA structure at 33 degrees but not 41 degrees. Wild-type T antigen did not exhibit temperature-sensitive defects in these activities. C11A T antigen was completely unable to unwind ori-DNA at either temperature. This defect in unwinding was trans-dominant; C11A T antigen inhibited ori-DNA unwinding by wild-type T antigen. These data show that a mutant displaying a nonconditional defective phenotype may contain a subset of relevant properties that are temperature sensitive.

Two conditional tsA mutant simian virus 40 T antigens display marked differences in thermal inactivation.

We have characterized the simian virus 40 (SV40) origin-containing DNA (ori-DNA) replication functions of two SV40 conditional mutant T antigens: tsA438 A-V (tsA58) and tsA357 R-K (tsA30). Both tsA mutant T antigens, immunopurified from recombinant baculovirus-infected insect cells, mediated replication of SV40 ori-DNA in vitro to similar extents as did wild-type T antigen in reactions at 33 degrees C. However, at 41 degrees C, the restrictive temperature, while tsA438 T antigen still generated substantial levels of replication products, tsA357 T antigen did not support any detectable DNA synthesis. Furthermore, preincubation for approximately fourfold-longer time periods at 41 degrees C was required to heat inactivate tsA438 T antigen than to heat inactivate tsA357 T antigen. Unexpectedly, results of analyses of the various DNA replication activities of the two mutant T antigens did not correlate with results from ori-DNA replication reactions. In particular, although tsA357 T antigen was incapable of mediating replication at 41 degrees C at all protein concentrations examined, it displayed either wild-type levels or only partial reductions of the several T-antigen replication-associated activities. These data suggest either that tsA357 T antigen is defective in an as yet unidentified replication function of T antigen or that the combination of its partial defects result in a protein that is unable to support replication. The data also show that two conditional mutant T antigens can be markedly different with respect to thermal sensitivity.

Site-specific binding of wild-type p53 to cellular DNA is inhibited by SV40 T antigen and mutant p53.

Wild-type p53 protein was shown to bind specifically to DNA sequences within SV40 (Bargonetti et al. 1991), the human ribosomal gene cluster (RGC) (Kern et al. 1991a), and the murine muscle creatine kinase gene (MCK) (Zambetti et al. 1992). However, a direct comparison of these three sites was not performed. Here we demonstrate, by filter binding and gel mobility-shift assays, that wild-type p53 binds with similar affinities to MCK and RGC sites but less tightly to the SV40 site. We examined the effects of two candidate regulators of p53 function, SV40 large T antigen and oncogenic mutant p53, on the binding of wild-type p53 to RGC DNA. We show that wild-type T antigen prevents p53 from binding to the RGC site under all conditions tested. Moreover, two temperature-sensitive mutant SV40 T antigens, which fail to transform cells at the nonpermissive temperature, prevent p53 from binding to the RGC site at the permissive, but not at the restrictive, temperature. The ability of complexes containing wild-type p53 and tumor-derived mutant p53 proteins to bind to RGC DNA varies according to the position of the mutation. Complexes containing wild-type and either his175 or his273 mutant p53 proteins are completely unable to bind to the RGC DNA sequence. Interestingly, a complex containing wild-type p53 and the trp248 mutant p53 characteristic of Li-Fraumeni syndrome patients displays nearly wild-type levels of binding. Perhaps this mutant allele can be tolerated in these individuals because the wild-type mutant p53 complex maintains the ability to bind to DNA. Our data indicate that the oncogenic potential of both T antigen and some mutant p53 proteins is the result of their ability to block binding of wild-type p53 to DNA.

Thermally inactivated simian virus 40 tsA58 mutant T antigen cannot initiate viral DNA replication in vitro.

The mutation in the temperature-sensitive tsA58 mutant T antigen (Ala-438----Val) lies within the presumptive ATP-binding fold. We have constructed a recombinant baculovirus that expresses large quantities of the tsA58 T antigen in infected insect cells. The mutant T antigen mediated simian virus 40 origin-containing DNA (ori-DNA) synthesis in vitro to nearly the same extent as similar quantities of wild-type T antigen at 33 degrees C. However, if wild-type and tsA58 T antigens were heated at 41 degrees C in replication extracts prior to addition of template DNA, the tsA58 T antigen but not the wild type was completely inactivated. The mutant protein displayed greater thermosensitivity for many of the DNA replication activities of T antigen than did the wild-type protein. Some of the replication functions of tsA58 T antigen were differentially affected depending on the presence or absence of ATP during the preheating period. When tsA58 T antigen was preheated in the presence of ATP at 41 degrees C for a time sufficient to completely inactivate its ability to replicate ori-DNA in vitro, it displayed substantial ATPase and normal DNA helicase activities. Conversely, when preheated in the absence of nucleotide, it completely lost both ATPase and helicase activities. Preheating tsA58 T antigen, even in the presence of ATP, led to drastic reductions in its ability to bind to and unwind DNA containing the replication origin. The mutant T antigen also displayed thermosensitivity for binding to and unwinding nonspecific double-stranded DNA in the presence of ATP. Our results suggest that the interactions of T antigen with ATP that are involved in T-antigen DNA binding and DNA helicase activities are different. Moreover, we conclude, consistent with its phenotype in vivo, that the tsA58 T antigen is defective in the initiation but not in the putative elongation functions of T antigen in vitro.