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

Overexpression of p53 protein in human tumors

According to the current concept of carcinogenesis, neoplastic transformation consists of multistep accumulations of adverse genetic and epigenetic events. p53 is a transcription factor that regulates cellular response to diverse forms of stress through a complex network which monitors genome integrity and cell homeostasis. Mutant p53 loss-of-function, dominant-negative, and gain-of-function properties have been implicated in the development of a wide variety of human cancers, and it is generally accepted that p53 is a component in biochemical pathways central to human carcinogenesis. Study of p53 has come to the forefront of cancer research, and detection of its abnormalities during the development of tumors may have diagnostic, prognostic, and therapeutic implications. In this review, we focus on recent research on overexpression of mutant p53 in human cancer, with an emphasis on mutant p53 regulation, gain of function of mutant p53 in transcriptional effects, and the diagnostic, prognostic, and predictive value of p53 overexpression in human cancer.

Selective interactions of human kin17 and RPA proteins with chromatin and the nuclear matrix in a DNA damage- and cell cycle-regulated manner

Several proteins involved in DNA synthesis are part of the so-called 'replication factories' that are anchored on non-chromatin nuclear structures. We report here that human kin17, a nuclear stress-activated protein, associates with both chromatin and non-chromatin nuclear structures in a cell cycle- and DNA damage-dependent manner. After L-mimosine block and withdrawal we observed that kin17 protein was recruited in the nucleus during re-entry and progression through S phase. These results are consistent with a role of kin17 protein in DNA replication. About 50% of the total amount of kin17 protein was detected on nuclear structures and could not be released by detergents. Furthermore, the amount of kin17 protein greatly increased in both G(1)/S and S phase-arrested cells in fractions containing proteins anchored to nuclear structures. The detection of kin17 protein showed for the first time its preferential assembly within non-chromatin nuclear structures in G(1)/S and S phase-arrested cells, while the association with these structures was found to be less stable in the G(2)/M phase, as judged by fractionation of human cells and immunostaining. In asynchronous growing cells, kin17 protein interacted with both chromatin DNA and non-chromatin nuclear structures, while in S phase-arrested cells it interacted mostly with non-chromatin nuclear structures, as judged by DNase I treatment and in vivo UV cross-linking. In the presence of DNA damage in S phase cells, the distribution of kin17 protein became mainly associated with chromosomal DNA, as judged by limited formaldehyde cross-linking of living cells. The physical interaction of kin17 protein with components of the nuclear matrix was confirmed and visualized by indirect immunofluorescence and immunoelectron microscopy. Our results indicate that, during S phase, a fraction of the human kin17 protein preferentially associates with the nuclear matrix, a fundamentally non-chromatin higher order nuclear structure, and to chromatin DNA in the presence of DNA damage.

Molecular cloning and characterization of the human KIN17 cDNA encoding a component of the UVC response that is conserved among metazoans

We describe the cloning and characterization of the human KIN17 cDNA encoding a 45 kDa zinc finger nuclear protein. Previous reports indicated that mouse kin17 protein may play a role in illegitimate recombination and in gene regulation. Furthermore, overproduction of mouse kin17 protein inhibits the growth of mammalian cells, particularly the proliferation of human tumour-derived cells. We show here that the KIN17 gene is remarkably conserved during evolution. Indeed, the human and mouse kin17 proteins are 92.4% identical. Furthermore, DNA sequences from fruit fly and filaria code for proteins that are 60% identical to the mammalian kin17 proteins, indicating conservation of the KIN17 gene among metazoans. The human KIN17 gene, named (HSA)KIN17, is located on human chromosome 10 at p15-p14. The (HSA)KIN17 RNA is ubiquitously expressed in all the tissues and organs examined, although muscle, heart and testis display the highest levels. UVC irradiation of quiescent human primary fibroblasts increases (HSA)KIN17 RNA with kinetics similar to those observed in mouse cells, suggesting that up-regulation of the (HSA)KIN17 gene after UVC irradiation is a conserved response in mammalian cells. (HSA)kin17 protein is concentrated in intranuclear focal structures in proliferating cells as judged by indirect immunofluorescence. UVC irradiation disassembles (HSA)kin17 foci in cycling cells, indicating a link between the intranuclear distribution of (HSA)kin17 protein and the DNA damage response.

Overexpression of kin17 protein disrupts nuclear morphology and inhibits the growth of mammalian cells

UVC or ionizing radiation of mammalian cells elicits a complex genetic response that allows recovery and cell survival. Kin17 gene, which is highly conserved among mammals, is upregulated during this response. Kin17 gene encodes a 45 kDa protein which binds to DNA and presents a limited similarity with a functional domain of the bacterial RecA protein. Kin17 protein is accumulated in the nucleus of proliferating fibroblasts and forms intranuclear foci. Using expression vectors, we show that overexpression of kin17 protein inhibits cell-cycle progression into S phase. Our results indicate that growth inhibition correlates with disruption of the nuclear morphology which seems to modify the intranuclear network required during the early steps of DNA replication. We report that a mutant encoding a protein deleted from the central domain of kin17 protein enhanced these effects whereas the deletion of the C-terminal domain considerably reduced them. These mutants will be used to elucidate the molecular mechanism by which kin17 protein alters cell growth and DNA replication.

Nuclear import of p53 during Xenopus laevis early development in relation to DNA replication and DNA repair

The role of p53 in transcriptional activation of genes involved in cell cycle progression is well established. However, the wide range of functions attributed to this gene suggests that some of them might be unrelated to transcription. Here we investigated p53 localization and recruitment to chromatin during Xenopus early development when 12 rapid cell cycles occur without transcription of the genome. We show that after fertilization, part of the large store of p53 previously stored in the cytoplasm of the oocyte is imported into the nucleus. This import was further analyzed in relation with DNA replication and DNA repair using cell-free systems from Xenopus eggs. Formation of a nuclear lamina envelope is necessary for the import of p53 into the nucleus. p53 associates both with decondensed DNA and the nuclear lamina envelope, but no colocalization with prereplication or replication complexes is observed. We show that UV- or gamma-damaged nuclei recruit p53 as well as replication protein A (RPA) in large common foci. Together, these data suggest that p53 plays a role in the regulation of the accelerated S phases that occur during Xenopus early development, in a manner that does not rely on its transcription-mediated activity.

p80-coilin: a component of coiled bodies and interchromatin granule-associated zones

We investigated at the electron microscope level the fate of the three intranuclear structures known to accumulate snRNPs, and which correspond to the punctuate immunofluorescent staining pattern (the coiled bodies, the clusters of interchromatin granules and the interchromatin granule-associated zones) after exposure to either a low salt medium which induces a loosening and partial spreading of nucleoprotein fibers or a high ionic strength salt medium and subsequent DNase I digestion, in order to obtain DNA-depleted nuclear matrices. The loosened clusters of interchromatin granules and the coiled bodies could no longer be distinguished from surrounding nucleoprotein fibers solely by their structure, but constituents of the clusters of interchromatin granules could be detected by in situ hybridization with both U1 and U2 DNA probes, and constituents of the coiled bodies were detectable mainly with the U2 DNA probe. The interchromatin granule-associated zones, the electron-opacity and compactness of which were preserved despite the loosening treatment, remained labeled with the U1 DNA probe only. In DNA-depleted nuclear matrices, the snRNA content of the coiled bodies, the clusters of interchromatin granules and their associated zones, which were all easily recognizable within the residual nuclear ribonucleoprotein network, was unmodified. The data indicate, therefore, that the loosening procedure as well as the high salt extraction procedure preserve the snRNA content of all three spliceosome component-accumulation sites and reveal that interchromatin granule-associated zones are elements of the nuclear matrix. The p80-coilin content coiled bodies was also preserved whatever the salt treatment used. An intriguing new finding is the detection of abundant p80-coilin within the interchromatin granule-associated zones, both before and after either low or high salt treatment of cells. Therefore, p80-coilin is an integral constituent of the interchromatin granule-associated zones.

Expression of myelin protein genes and other myelin components in an oligodendrocytic cell line conditionally immortalized with a temperature-sensitive retrovirus

We have conditionally immortalized oligodendrocytes isolated from normal and shiverer primary mouse brain cultures through the use of the retroviral vector ZIPSVtsA58. This vector encodes an immortalizing thermolabile simian virus 40 large T antigen (Tag) and allows for clonal selection by conferring neomycin (G418) resistance. We isolated 14 shiverer and 10 normal lines that expressed the early oligodendrocyte marker 2',3'-cyclic nucleotide 3'-phosphodiesterase mRNA. These cell lines grew continuously at the permissive temperature (34 degrees C) and displayed Tag nuclear immunostaining. On shifting to nonpermissive temperatures (39 degrees C), the cells showed rapid arrested cell growth and loss of Tag staining. One line (N20.1) engineered from normal oligodendrocytes also expressed myelin basic protein (MBP) and proteolipid protein (PLP) mRNAs, genes normally expressed by mature, differentiated oligodendrocytes. No differences in any of the myelin-specific protein mRNA levels were observed in N20.1 cells grown at 39 degrees C for > 9 days compared with cells maintained at 34 degrees C. Immunocytochemical staining revealed N20.1 cells to be positive for the oligodendrocyte surface markers--galactocerebroside, A007, and A2B5. However, MBP and PLP polypeptides could not be detected by western blot or immunocytochemical staining at either the permissive or nonpermissive temperature. Cell-free protein synthesis experiments indicated that the MBP mRNAs isolated from N20.1 cells were translatable and directed the synthesis of the 17-, 18.5-, and 21.5-kDa MBP isoforms. Analysis of the PLP/DM20 gene splice products by polymerase chain reaction indicated that the expression of DM20 mRNA predominated over that of PLP mRNA in this cell line. Because the cell line expressed the MBP and PLP genes, it represents a "mature" oligodendrocyte, but the splicing patterns of these genes indicate that it is at an early stage of "maturation." This cell line has now been passaged > 40 times with fidelity of phenotype and genotype.

Midline brain tumors in MSV-SV 40-transgenic mice originate from the pineal organ

Adult transgenic mice expressing the large T-antigen of the Simian virus 40 (SV 40) under the control of the Moloney murine sarcoma virus (MSV) enhancer and the SV 40 promoter develop inheritable uniform midline brain neoplasms showing features of primitive neuroectodermal tumors. The origin and histogenesis of these tumors were investigated in the present study. The brain and pineal organ of fetal and young transgenic mice less than 3 months old displayed normal macroscopic and microscopic features. In 3.5-month-old animals, the pineal organ was considerably enlarged due to hyperplasia, finally leading to tumor formation. Immunocytochemical demonstration of large T-antigen showed that this oncoprotein was already expressed in the nuclei of certain cells in the pineal organ of fetuses (16 and 18 days old) and newborn animals, but was absent from all other parts of the brain. The immunocytochemical demonstration of S-antigen (arrestin), a highly characteristic marker for pinealocytes, was used for further characterization of the large T-antigen-immunoreactive cells. The fetal pineal organ did not contain immunoreactive S-antigen. This first occurred in certain pinealocytes of newborn mice. Double immunostaining revealed that in newborn and older transgenic mice the immunoreactive large T-antigen was exclusively found in nuclei of cells containing S-antigen immunoreaction in their cytoplasm. Thus, transformed pinealocytes appear as stem cells of the experimental tumors. The results of this study suggest that primitive neuroectodermal tumors and the normal tissue from which they originate share certain molecular and immunocytochemical features.