The 8-kDa dynein light chain binds to p53-binding protein 1 and mediates DNA damage-induced p53 nuclear accumulation

The tumor suppressor protein p53 is known to undergo cytoplasmic dynein-dependent nuclear translocation in response to DNA damage. However, the molecular link between p53 and the minus end-directed microtubule motor dynein complex has not been described. We report here that the 8-kDa light chain (LC8) of dynein binds to p53-binding protein 1 (53BP1). The LC8-binding domain was mapped to a short peptide segment immediately N-terminal to the kinetochore localization region of 53BP1. The LC8-binding domain is completely separated from the p53-binding domain in 53BP1. Therefore, 53BP1 can potentially act as an adaptor to assemble p53 to the dynein complex. Unlike other known LC8-binding proteins, 53BP1 contains two distinct LC8-binding motifs that are arranged in tandem. We further showed that 53BP1 can directly associate with the dynein complex. Disruption of the interaction between LC8 and 53BP1 in vivo prevented DNA damage-induced nuclear accumulation of p53. These data illustrate that LC8 is able to function as a versatile acceptor to link a wide spectrum of molecular cargoes to the dynein motor.     

A 53 kDa protein binds to the negative regulatory region of JC virus early promoter.

Using gel retardation and photocrosslinking experiments, we have identified proteins of about 53 kDa in size in both rat glioma (C6) and cervical carcinoma (HeLa) cell extracts which bind to the negative regulatory region of JV virus (JCV) early promoter. The glial cell protein binds to its cognate promoter element with lesser affinity when compared to the protein present in HeLa cells. Further, these proteins interacted differentially to an oligonucleotide, containing the neighboring cis-acting domain, which is recognized by nuclear factor 1 (NF1). These findings suggest that the interactions of the 53 kDa HeLa protein may contribute to the negative regulation of JCV early promoter in HeLA cells.     

Germ cell-specific heat shock protein 105 binds to p53 in a temperature-sensitive manner in rat testis.

Heat shock protein (HSP)105 is a testis-specific and HSP90-related protein. The aim of this study was to explore the functions of HSP105 in the rat testis. Signals of HSP105 were detected immunohistochemically in the germ cells and translocated from the cytoplasm to the nucleus at 2 days after experimental induction of cryptorchidism. In cultured testicular germ cells, a significant increase in the expression of HSP105 in response to heat stress (37 degrees C) was detected in the insoluble protein fractions. Several binding proteins were isolated from rat testis using a HSP105 antibody immunoaffinity column, and p53, the tumor suppressor gene product, was copurified with these. Furthermore, immunoprecipitation using antibodies to p53 led to coprecipitation of HSP105 together with p53 after culturing germ cells at 32.5 degrees C, but not at 37 or 42 degrees C. In conclusion, HSP105 is specifically localized in the germ cells and may translocate into the nucleus after heat shock. HSP105 is suggested to form a complex with p53 at the scrotal temperature, and dissociate from it at suprascrotal temperatures. At scrotal temperature, HSP105 may thus contribute to the stabilization of p53 proteins in the cytoplasm of the germ cells, preventing the potential induction of apoptosis by p53.     

Nuclear factor I (NF I) binds to an NF I-type site but not to the CCAAT site in the human alpha-globin gene promoter.

Methylation interference and missing contact analyses demonstrate that nuclear factor I (NF I) recognizes an NF I-like site (5'-GGG(N)6GCCAG-3') within the alpha-globin promoter rather than the adjacent CCAAT box. Consistent with this, mutations within the CCAAT box do not alter significantly the affinity and specificity of the interaction whereas elimination of the 5'-GGG-3' half-site of the recognition sequence reduces the DNA binding strength of NF I by 2 orders of magnitude down to the range of unspecific interaction. On the other hand, the mutated alpha-globin promoter sequence that is no longer bound by NF I, although it retains an intact CCAAT box, interacts specifically with a protein component from nuclear extracts of HeLa cells. From these results we conclude that NF I is not the factor that interacts with the CCAAT box and that the second half of the canonical 5'-TGG(N)6GCCAA-3' NF I binding site cannot be regarded as identical with the CCAAT promoter element, as suggested previously.     

A putative protein inhibitor of activated STAT (PIASy) interacts with p53 and inhibits p53-mediated transactivation but not apoptosis

The p53 protein has recently been reported to be capable of mediating apoptosis through a pathway that is not dependent on its transactivation function. We report here that the PIASy member of the protein inhibitor of activated STAT family inhibited p53's transactivation function without compromising its ability to induce apoptosis of the H1299 nonsmall cell lung carcinoma cell line. The p53 protein bound to PIASy in yeast two-hybrid assays and coprecipitated in complexes with p53 in immunoprecipitates from mammalian cells. PIASy inhibited the DNA-binding activity of p53 in nuclear extracts and blocked the ability of p53 to induce expression of two of its target genes, Bax and p21^Waf1/Cip1, in H1299 cells. The block in p53-mediated induction of Bax and p21 was determined to be at the level of transactivation, since PIASy inhibited p53's ability to transactivate a p21/luciferase reporter construct. PIASy did not effect the incidence of apoptosis in H1299 cells upregulated for p53. PIASy appears to regulate p53-mediated functions and may direct p53 into a transactivation-independent mode of apoptosis.     

HBV DNA can bind to P53 protein and influence p53 transactivation in hepatoma cells

Hepatitis B virus (HBV) may contribute to hepatocarcinogenesis by blocking p53 function. A p53 response element-like binding sequences, TGCCT?TGCCT, was found in HBV genome. To clarify whether HBV DNA can, like some other DNA viruses, bind to P53 protein and form a DNA-protein complex, we used a series of plasmids encoding full-length or mutant HBV or p53 fragments to determine the binding ability of HBV DNA after cotransfected into cells by electrophoretic mobility shift (and supershift) assay. We found that HBV DNA could bind to P53 protein and form DNA-protein complexes in human hepatoma cell lines. Cotransfection with p53 and HBV DNA increased the replication of HBV, CAT activity, tumor cell apoptosis, and cytoplasmic P53 accumulation in the hepatoma cells. In conclusions, our observations suggest that the interaction of HBV and p53 at the levels of protein-protein and DNA-protein, which resulted in inactivation of p53 transactivation.     

Amplification of the gene for 3-hydroxy-3-methylglutaryl coenzyme A reductase, but not for the 53-kDa protein, in UT-1 cells

32P-labeled cDNA probes were used to study levels of genomic DNA and regulation of mRNA for 3-hydroxy-3-methylglutaryl coenzyme A reductase in UT-1 cells, a clone of compactin-resistant Chinese hamster ovary cells that have a 100-1000-fold increase in the amount of reductase protein. Similar measurements were made for the 53-kDa protein, a cytosolic protein of unknown function that is also expressed at high levels in UT-1 cells. The number of copies of the gene for reductase was increased by 15-fold in UT-1 cells as compared to the parental Chinese hamster ovary cells, as judged from Southern gel analysis of restriction endonuclease-digested genomic DNA. In contrast, there was no detectable increase in the number of gene copies for the 53-kDa protein. The amount of cytoplasmic mRNA for both proteins was markedly elevated in UT-1 cells, as determined by filter hybridization studies using 32P-labeled cDNA probes. The amount of mRNA for both reductase and the 53-kDa protein declined in parallel after addition of low density lipoprotein, 25-hydroxycholesterol, or mevalonate to the culture medium. The decline in reductase mRNA was associated with a marked decrease in the rate of [3H]uridine incorporation into hybridizable cytoplasmic mRNA. When UT-1 cells were grown for 3-4 months in the absence of compactin, the level of reductase mRNA and enzymatic activity decreased markedly, but the number of copies of the reductase gene did not decline. When the compactin-withdrawn cells were rechallenged with compactin, high levels of reductase mRNA and enzymatic activity promptly returned. We conclude that the gene for 3-hydroxy-3-methylglutaryl coenzyme A reductase, but not for the 53-kDa protein, has been stably amplified in UT-1 cells. Despite this differential gene amplification, the levels of cytoplasmic mRNA for both gene products are markedly elevated, and both are reduced in parallel by either sterols (low density lipoprotein-cholesterol or 25-hydroxycholesterol) or mevalonate, the product of the reductase-catalyzed reaction.