The cdc2 kinase is a nuclear protein that is essential for mitosis in mammalian cells

A homolog of the fission yeast cdc2-encoded protein kinase (p34) is a component of M phase promoting factor in Xenopus oocytes. The homologous kinase in human HeLa cells is maximally active during mitosis, suggesting a mitotic role in mammalian somatic cells. This has been directly investigated by microinjection of anti-p34 antibodies into serum-stimulated rat fibroblasts. DNA synthesis was unaffected but cell division was quantitatively blocked in injected cells. Injection of antibodies against p13suc1, a component of the p34 kinase complex, did not block mitosis but caused mitotic abnormalities resulting in cells containing multiple micronuclei in the subsequent interphase. p34 localized in the nucleus during interphase. During mitosis, a fraction tightly associated with centrosomes. p13 was more evenly distributed between the nucleus and cytoplasm. These observations demonstrate that cdc2 is a nuclear and centrosomal protein that is required for mitosis in mammalian cells.     

Evidence that mammalian ribonucleotide reductase is a nuclear membrane associated glycoprotein

Epitope-specific antibodies to the M1 and M2 subunits of mammalian ribonucleotide reductase were prepared using peptides predicted to have a high antigenic index. Western blotting demonstrated that the anti-M1 antibody was specific for the 89-kilodalton M1 subunit (and its degradation fragments) and the anti-M2 antibody specifically recognized the 45-kilodalton M2 subunit. Both antibodies inhibited the CDP-reductase activity of the holoenzyme. Using these antibodies, both the M1 and M2 subunits were shown to be localized in the cytoplasm and in the nuclear regions of a number of cell types, including B77 avian sarcoma virus transformed NRK cells, T51B rat liver cells, 5123tc hepatoma cells, and rat liver cells in vivo. In addition, the M1 subunit was found to be localized as a halo around isolated rat liver nuclei. Biochemical analysis of the cytoplasmic fraction of liver cells and a Triton X-100 wash of nuclei from these cells confirmed the location of the enzyme activity in these cellular compartments. The M1 subunit appears to be glycosylated, as indicated by its retention on a Affi-Gel-concanavalin A affinity column. Therefore, in mammalian cells ribonucleotide reductase appears to be not only in the cytoplasm, but is also associated with the nuclear membrane or nuclear lamina. The activity of the enzyme in the membrane fraction changes dynamically during the cell cycle.     

Identification of a protein component of a mammalian tRNA(Sec) complex implicated in the decoding of UGA as selenocysteine

This report describes a novel RNA-binding protein, SECp43, that associates specifically with mammalian selenocysteine tRNA (tRNA(Sec)). SECp43, identified from a degenerate PCR screen, is a highly conserved protein with two ribonucleoprotein-binding domains and a polar/acidic carboxy terminus. The protein and corresponding mRNA are generally expressed in rat tissues and mammalian cell lines. To gain insight into the biological role of SECp43, affinity-purified antibody was employed to identify its molecular partners. Surprisingly, the application of native HeLa cell extracts to a SECp43 antibody column results in the purification of a 90-nt RNA species identified by direct sequencing and Northern blot analysis as tRNA(Sec). The purification of tRNA(Sec) by the antibody column is striking, based on the low abundance of this tRNA species. Using recombinant SECp43 as a probe for interacting protein partners, we also identify a 48-kDa interacting protein, which is a possible component of the mammalian selenocysteine insertion (SECIS) pathway. To our knowledge, SECp43 is the first cloned protein demonstrated to associate specifically with eukaryotic tRNA(Sec).     

Localization and quantitation of hsp84 in mammalian cells

In order to investigate the function of heat shock protein 84 (hsp84) we have isolated the protein from mouse neuroblastoma cells and raised a polyclonal antiserum which was affinity-purified. The specificity of the antibody was established by immunoprecipitation and immunoblotting. Immunofluorescence studies revealed both a cytoplasmic and a nuclear localization of hsp84 in five different mammalian cell lines (mouse neuroblastoma cells and fibroblasts, rat hepatoma cells, and HeLa cells). In none of the five cell lines were found significant differences in the total cellular levels of hsp84 before and immediately after a heat shock (4 h, 42 degrees C) by immunoblot quantification. Furthermore after heat shock the fluorescence of anti-hsp84-labeled nuclei was increased relative to that of the surrounding cytoplasm. The increased fluorescence disappeared upon reincubation at 37 degrees C. The heat-induced increase in contrast between cytoplasmic and nuclear fluorescence could be explained by a combination of three factors: (a) decrease in nuclear projection area, (b) increase in cytoplasmic projection area, and (c) translocation of hsp84. The contribution of these factors to the increase after heat treatment was different for the cell lines.     

Mammalian p55CDC Mediates Association of the Spindle Checkpoint Protein Mad2 with the Cyclosome/Anaphase-promoting Complex, and is Involved in Regulating Anaphase Onset and Late Mitotic Events

We have investigated the function of p55CDC, a mammalian protein related to Cdc20 and Hct1/Cdh1 in Saccharomyces cerevisiae, and Fizzy and Fizzy-related in Drosophila. Immunofluorescence studies and expression of a p55CDC-GFP chimera demonstrate that p55CDC is concentrated at the kinetochores in M phase cells from late prophase to telophase. Some p55CDC is also associated with the spindle microtubules and spindle poles, and some is diffuse in the cytoplasm. At anaphase, the concentration of p55CDC at the kinetochores gradually diminishes, and is gone by late telophase. In extracts prepared from M phase, but not from interphase HeLa cells, p55CDC coimmunoprecipitates with three important elements of the M phase checkpoint machinery: Cdc27, Cdc16, and Mad2. p55CDC is required for binding Mad2 with the Cdc27 and Cdc16. Thus, it is likely that p55CDC mediates the association of Mad2 with the cyclosome/anaphase-promoting complex. Microinjection of anti-p55CDC antibody into mitotic mammalian cells induces arrest or delay at metaphase, and impairs progression of late mitotic events. These studies suggest that mammalian p55CDC may be part of a regulatory and targeting complex for the anaphase-promoting complex.     

Sun2 is a novel mammalian inner nuclear membrane protein

Sun protein (Sun1 and Sun2) cDNAs were previously cloned based on the homology of their C-terminal regions (SUN (Sad1 and UNC) domain) with the Caenorhabditis elegans protein UNC-84 whose mutation disrupts nuclear migration/positioning. In this study, we raised an anti-Sun2 serum and identified Sun2 in mammalian cells. In HeLa cells, Sun2 displays a nuclear rim-like pattern typical for a nuclear envelope protein. The Sun2 antibody signal co-localizes with nuclear pore and INM markers signals. The rim-like pattern was also observed with the recombinant full-length Sun2 protein fused to either EGFP or V5 epitopes. In addition, we found that a recombinant truncated form of Sun2, extending from amino acids 26 to 339, is sufficient to specify the nuclear envelope localization. Biochemical analyses show that Sun2 is an 85-kDa protein that is partially insoluble in detergent with high salt concentration and in chaotropic agents. Furthermore, Sun2 is enriched in purified HeLa cell nuclei. Electron microscopy analysis shows that Sun2 localizes in the nuclear envelope with a sub-population present in small clusters. Additionally, we show that the SUN domain of Sun2 is localized to the periplasmic space between the inner and the outer nuclear membranes. From our data, we conclude that Sun2 is a new mammalian inner nuclear membrane protein. Because the SUN domain is conserved from fission yeast to mammals, we suggest that Sun2 belongs to a new class of nuclear envelope proteins with potential relevance to nuclear membrane function in the context of the involvement of its components in an increasing spectrum of human diseases.     

Nuclear granules recognized by some monoclonal antibodies against intermediate filament protein locate on chromosomes during mitosis

AC54 monoclonal antibody (MAb), an anti-desmin MAb, recognizes both intermediate filaments (IFs) and nuclear granules in BHK21/C13 cells. To investigate nuclear granules, similar MAbs were obtained by using desmin fraction as an antigen. Among them, DSB389 MAb recognized mainly nuclear granules in HeLa and rat liver cells. The nuclear granules in HeLa cells were aligned in arrays, sometimes connected by, or part of, a rope-like structure, and stable against treatment with 0.5% Triton X-100 and 2 M NaCl. They located on or around the chromosomes during mitosis. Essentially the same results were obtained with DSB860 and AC54 MAbs. The distribution of the granules in liver nuclei recognized by DSB389 MAb was similar to that of DNA and was different from that of the nuclear pore complexes. The biological significance of the nuclear granules is discussed.     

p63cdc13, a B-type cyclin, is associated with both the nucleolar and chromatin domains of the fission yeast nucleus.

The cellular distribution of the fission yeast mitotic cyclin B, p63cdc13, was investigated by a combination of indirect immunofluorescence light microscopy, immunogold electron microscopy, and nuclear isolation and fractionation. Immunofluorescence microscopy of wild-type cells and the cold-sensitive mutant dis2.11 with a monospecific anti-p63cdc13 antiserum was consistent with the association of a major subpopulation of fission yeast M-phase protein kinase with the nucleolus. Immunogold electron microscopy of freeze-substituted wild-type cells identified two nuclear populations of p63cdc13, one associated with the nucleolus, the other with the chromatin domain. To investigate the cell cycle regulation of nuclear labeling, the mutant cdc25.22 was synchronized through mitosis by temperature arrest and release. Immunogold labeling of cells arrested at G2M revealed gold particles present abundantly over the nucleolus and less densely over the chromatin region of the nucleus. Small vesicles around the nucleus were also labeled by anti-p63cdc13, but few gold particles were detected over the cytoplasm. Labeling of all cell compartments declined to zero through mitosis. Cell fractionation confirmed that p63cdc13 was substantially enriched in both isolated nuclei and in a fraction containing small vesicles and organelles. p63cdc13 was not extracted from nuclei by treatment with RNase A, Nonidet P40 (NP-40), Triton X-100, and 0.1 M NaCl, although partial solubilization was observed with DNase I and 1 M NaCl. A known nucleolar protein NOP1, partitioned in a similar manner to p63cdc13, as did p34cdc2, the other subunit of the M-phase protein kinase. We conclude that a major subpopulation of the fission yeast mitotic cyclin B is targeted to structural elements of the nucleus and nucleolus.     

Relationship between contact inhibition and intranuclear S100C of normal human fibroblasts

Many lines of evidence indicate that neoplastic transformation of cells occurs by a multistep process. For neoplastic transformation of normal human cells, they must be first immortalized and then be converted into neoplastic cells. It is well known that the immortalization is a critical step for the neoplastic transformation of cells and that the immortal phenotype is recessive. Thus, we investigated proteins downregulated in immortalized cells by two-dimensional gel electrophoresis. As a result, S100C, a Ca(2+)-binding protein, was dramatically downregulated in immortalized human fibroblasts compared with their normal counterparts. When the cells reached confluence, S100C was phosphorylated on threonine 10. Then the phosphorylated S100C moved to and accumulated in the nuclei of normal cells, whereas in immortalized cells it was not phosphorylated and remained in the cytoplasm. Microinjection of the anti-S100C antibody into normal confluent quiescent cells induced DNA synthesis. Furthermore, when exogenous S100C was compelled to localize in the nuclei of HeLa cells, their DNA synthesis was remarkably inhibited with increase in cyclin-dependent kinase inhibitors such as p16(Ink4a) and p21(Waf1). These data indicate the possible involvement of nuclear S100C in the contact inhibition of cell growth.     

Leptomycin B Inhibition of Signal-Mediated Nuclear Export by Direct Binding to CRM1

Leptomycin B (LMB) is aStreptomycesmetabolite that inhibits nuclear export of the human immunodeficiency virus type 1 regulatory protein Rev at low nanomolar concentrations. Recently, LMB was shown to inhibit the function of CRM1, a receptor for the nuclear export signal (NES). Here we show evidence that LMB binds directly to CRM1 and that CRM1 is essential for NES-dependent nuclear export of proteins in both yeast and mammalian cells. Binding experiments with a biotinylated derivative of LMB and a HeLa cell extract led to identifying CRM1 as a major protein that bound to the LMB derivative. Microinjection of a purified anti-human CRM1 antibody into the mammalian nucleus specifically inhibited nuclear export of NES-containing proteins, as did LMB. Consistent with this, CRM1 was found to interact with NES, when assayed with immobilized NES and HeLa cell extracts. This association was disrupted by adding LMB or purified anti-human CRM1 antibody. The inhibition of CRM1 by LMB was also observed in fission yeast. The fission yeastcrm1mutant was defective in the nuclear export of NES-fused proteins, but not in the import of nuclear localization signal (NLS)-fused proteins. Interestingly, a protein containing both NES and NLS, which is expected to shuttle between nucleus and cytoplasm, was highly accumulated in the nucleus of thecrm1mutant cells or of cells treated with LMB. These results strongly suggest that CRM1 is the target of LMB and is an essential factor for nuclear export of proteins in eukaryotes.     

Cell cycle-dependent and DNA damage-inducible nuclear localization of FEN-1 nuclease is consistent with its dual functions in DNA replication and repair

Flap endonuclease-1 (FEN-1), a 43-kDa protein, is a structure-specific and multifunctional nuclease. It plays important roles in RNA primer removal of Okazaki fragments during DNA replication, DNA base excision repair, and maintenance of genome stability. Three functional motifs of the enzyme were proposed to be responsible for its nuclease activities, interaction with proliferating cell nuclear antigen, and nuclear localization. In this study, we demonstrate in HeLa cells that a signal located at the C terminus (the nuclear localization signal (NLS) motif) facilitates nuclear localization of the enzyme during S phase of the cell cycle and in response to DNA damage. Truncation of the NLS motif prevents migration of the protein from the cytoplasm to the nucleus, while having no effect on the nuclease activities and its proliferating cell nuclear antigen interaction capability. Site-directed mutagenesis further revealed that a mutation of the KRK cluster to three alanine residues completely blocked the localization of FEN-1 into the nucleus, whereas mutagenesis of the KKK cluster led to a partial defect of nuclear localization in HeLa cells without observable phenotype in yeast. Therefore, the KRKXXXXXXXXKKK motif may be a bipartite NLS driving the protein into nuclei. Yeast RAD27Delta cells transformed with human mutant M(krk) survived poorly upon methyl methanesulfonate treatment or when they were incubated at an elevated temperature.     

Studies of a microtubule-associated protein using a monoclonal antibody elicited against mammalian mitotic spindles

We have devised a procedure for the identification of individual molecules which are associated with the mitotic spindle apparatus and cytoskeleton in mammalian cells. We prepared monoclonal antibody-producing hybridomas by immunizing mice with mitotic spindles isolated from cultured HeLa cells. Among several antibody-producing clones obtained, one hybridoma (22MA2) produced an antibody that recognizes a putative microtubule-associated protein which exhibits unusual distribution characteristics in cultured cells. Immunofluorescence studies showed that during mitosis the 22MA2 antigen is distributed in parallel with the spindle fibers of the mitotic apparatus, and that during interphase the antigen is always associated to a limited extent with cytoplasmic microtubules. Also, the co-distribution of the antigen with microtubules was found to be Colcemid sensitive. However, the 22MA2 antibody immunofluorescently stained the nuclei of cells in the exponential growth phase, but did not stain the nuclei of cells that had grown to confluence. This nuclear fluorescence appears to be directly related to cell density rather than nutritional (serum) factors in the growth medium. The results suggest that the antigen undergoes some change in structure or distribution in response to changes in the proliferative capacity of the cell. Biochemical analyses of cytoplasmic, nuclear, and mitotic spindle subcellular fractions show that the antigen exhibits a polypeptide molecular weight of 240,000 is found in various mammalian cells ranging from marsupial to human, and is particularly susceptible to proteolysis.     

Histochemical detection of DNA strand scissions in mammalian cells by in situ nick translation

A method to visualize in situ of single strand scissions of DNA in fixed mammalian cells has been developed. Using the nuclear nick translation with biotin-labeled dUTP followed by binding to avidin-biotin-peroxydase complex, the nuclei of HeLa cells which had been treated with a DNA-damaging antibiotic bleomycin were specifically stained, implicating that the histochemical detection of single strand scissions (nicks) of DNA in fixed cells was completed without destroying the morphology, and without using autoradiography.     

Staurosporine-induced apoptosis of HPV positive and negative human cervical cancer cells from different points in the cell cycle

In the present study, we compare the sensitivity of CaSki and HeLa cells (HPV positive, wild-type p53) and C33A cells (HPV negative, mutated p53) to a protein kinase inhibitor, the staurosporine (ST). We show that ST can reversibly arrest the three cervical-derived cell lines, either in G1 or in G2/M. Beyond certain ST concentrations or/and over 24 h exposure, the cells underwent apoptosis. This process took place in G1 and G2/M for C33A and CaSki plus HeLa cell lines, respectively. By using an in vitro cell-free system, we demonstrated that cytoplasmic extracts from apoptotic cells were sufficient to induce hallmarks of programmed cell death on isolated nuclei. Moreover, we found that only G2/M cytoplasmic extracts from viable CaSki and HeLa cells supplemented with ST, triggered apoptosis while exclusively G1 cytoplasmic fractions from C33A cells were efficient. Our study describes a possible involvement of the HPV infection or/and p53 status in this different ST-induced apoptosis susceptibility.     

Cellular protein alterations in colorectal cancer: p28, p53 and p65 studies

The expression and intracellular distribution of the p28 protein (MW 28 kD), which is electrophoretically specific for tumour cells, the p53 protein (MW 53 kD), one of the most frequently mutated in cancer, and the oncofoetal p65 protein (MW 65 kD), were investigated in colorectal cancer and normal colonic mucosa. The correlation between the expression of these proteins and the stage of the cancer, was evaluated. Neoplastic and normal tissues were fractionated by differential centrifugation, and protein analysis was performed by means of the Western blot technique in the presence of polyclonal (anti-p28 and anti-p65) or monoclonal (anti-p53) antibodies. Among the colorectal cancer cases examined 69% (11/16), 53% (10/19) and 77% (17/22) were positive for p28, p53 and p65, respectively. Immunoblot analysis revealed that the tumour specific p28 protein expression was mainly evident in the nuclear fraction, while the p53 and p65 proteins accumulated in the cell nuclei and the cytoplasm, although to different extents. The p65 protein appeared to be specifically expressed in the early stages of colorectal cancer, while a high level of p53 protein was typical for more invasive colorectal cancer stages.     

Nuclear antigens in the HeLa cell cycle

Summary Antisera to 0.35 M NaCl extracts and residues of S phase HeLa nuclei were reacted with electrophoretically separated proteins from the nuclei or nuclear material of HeLa cells synchronized in G₁, S, G₂ or M phases of the cell cycle. Quantitative evaluation of the peroxidase-antiperoxidase stained nitrocellulose transfers (Western blots) revealed significant changes in the quantities of nuclear non-histone proteins during the cell cycle. Immunochemical staining of electrophoretically separated nuclear antigens permits their selective detection in minute quantities and in the presence of many additional proteins.     

The major nucleoside triphosphatase in pea (Pisum sativum L.) nuclei and in rat liver nuclei share common epitopes also present in nuclear lamins.

The major nucleoside triphosphatase (NTPase) activities in mammalian and pea (Pisum sativum L.) nuclei are associated with enzymes that are very similar both biochemically and immunochemically. The major NTPase from rat liver nuclei appears to be a 46-kD enzyme that represents the N-terminal portion of lamins A and C, two lamina proteins that apparently arise from the same gene by alternate splicing. Monoclonal antibody (MAb) G2, raised to human lamin C, both immunoprecipitates the major (47 kD) NTPase in pea nuclei and recognizes it in western blot analyses. A polyclonal antibody preparation raised to the 47-kD pea NTPase (pc480) reacts with the same lamin bands that are recognized by MAb G2 in mammalian nuclei. The pc480 antibodies also bind to the same lamin-like bands in pea nuclear envelope-matrix preparations that are recognized by G2 and three other MAbs known to bind to mammalian lamins. In immunofluorescence assays, pc480 and anti-lamin antibodies stain both cytoplasmic and nuclear antigens in plant cells, with slightly enhanced staining along the periphery of the nuclei. These results indicate that the pea and rat liver NTPases are structurally similar and that, in pea nuclei as in rat liver nuclei, the major NTPase is probably derived from a lamin precursor by proteolysis.     

The organizational fate of intermediate filament networks in two epithelial cell types during mitosis

Intermediate filaments (IF) appear to be attached to the nuclear envelope in various mammalian cell types. The nucleus of mouse keratinocytes is enveloped by a cagelike network of keratin-containing bundles of IF (IFB). This network appears to be continuous with the cytoplasmic IFB system that extends to the cell surface. Electron microscopy reveals that the IFB appear to terminate at the level of the nuclear envelope, frequently in association with nuclear pore complexes (Jones, J. C .R., A. E. Goldman, P. Steinert, S. Yuspa, and R. D. Goldman, 1982, Cell Motility, 2:197-213). Based on these observations of nuclear-IF associations, it is of interest to determine the fate and organizational states of IF during mitosis, a period in the cell cycle when the nuclear envelope disassembles. Immunofluorescence microscopy using a monoclonal keratin antibody and electron microscopy of thin and thick sections of mitotic mouse keratinocytes revealed that the IFB system remained intact as the cells entered mitosis and surrounded the developing mitotic spindle. IFB were close to chromosomes and often associated with chromosome arms. In contrast, in HeLa, a human epithelial cell, keratin-containing IFB appear to dissemble as cells enter mitosis (Franke, W. W., E. Schmid, C. Grund, and B. Geiger, 1982, Cell, 30:103-113). The keratin IFB in mitotic HeLa cells appeared to form amorphous nonfilamentous bodies as determined by electron microscopy. However, in HeLa, another IF system composed primarily of a 55,000-mol-wt protein (frequently termed vimentin) appears to remain morphologically intact throughout mitosis in close association with the mitotic apparatus (Celis, J.E., P.M. Larsen, S.J. Fey, and A. Celis, 1983, J. Cell Biol., 97:1429-34). We propose that the mitotic apparatus in both mouse epidermal cells and in HeLa cells is supported and centered within the cell by IFB networks.