Phosphorylation of the nuclear lamins during interphase and mitosis

Calcium and calmodulin-dependent phosphorylation of a 62 kd protein induces microtubule depolymerization in sea urchin mitotic apparatuses

Sea urchin mitotic apparatuses (MAs) were isolated in a microtubule stabilizing buffer that contained detergent. These isolated MAs contain a calcium and calmodulin-dependent protein kinase that phosphorylates one specific MA-associated endogenous substrate with a relative molecular mass of 62 kd. No protein phosphorylation occurs in the presence of calcium or magnesium ion alone, or when magnesium ion is combined with 10 microM cyclic AMP or cyclic GMP. Because in vivo labeling studies showed that the 62 kd protein was also phosphorylated in living cells during mitosis, the effect of protein phosphorylation on MA stability was also studied. When isolated MAs were incubated under conditions that resulted in phosphorylation of the 62 kd protein, substantial depolymerization of MA microtubules occurred within 10 min. MAs incubated under similar conditions but in the absence of 62 kd phosphorylation lost many fewer microtubules and were stable for up to 30 min. The results are discussed with respect to a model for mitosis in which the specific role of protein phosphorylation in the events of anaphase is addressed.

Lamin disassembly kinetics: a cell-free system with extracts from mitotic HeLa cells

We describe a cell-free system in which a postribosomal supernatant from metaphase HeLa cells induces prophase-like changes in permeabilized HeLa cell populations as evidenced by the nuclear lamin disassembly and chromatin condensation. We have attempted to characterize the cell-free system with permeabilized HeLa cells. First, by extracting lamins with agents known to disrupt the noncovalent interactions in the supramolecular lamin aggregate in interphase using polyclonal and a newly established monoclonal anti-lamin Ab 2E3, uniform extraction of lamins was achieved with urea and deoxycholate whereas the cation Mg2+ and 2-mercaptoethanol had little effect on the disassembly of interphase lamins. Second, cytoplasmic extract from mitotic HeLa cells, synchronized by a nitrous oxide metaphase arrest, was tested. It had a differential effect on interphase lamin depolymerization. Nuclei in G1 phase of the cell cycle were more resistant against the mitotic extracts than cells in S and G2 phase. The results are discussed in terms of a possible inactivation of mitotic extracts by factors present in nuclei in early interphase.

An M-phase-specific protein kinase of Xenopus oocytes: partial purification and possible mechanism of its periodic activation

The activity of a Ca2+- and cyclic nucleotide-independent protein kinase(s) which catalyzes hyperphosphorylation of a set of endogenous proteins, including a 95-kDa soluble phosphoprotein, is found to fluctuate in both the meiotic and mitotic cell cycles of Xenopus oocytes and activated eggs. The activity is high in M-phase and hardly detectable in interphase. The activity copurifies with a major histone kinase(s) throughout four purification steps: ammonium sulfate precipitation, DEAE-cellulose chromatography, high-performance liquid chromatography on TSK G3000, and CM-Sepharose chromatography. This suggests that a single enzyme shares activity against endogenous proteins and added histones. Changes in the activity of the M-phase-specific protein kinase(s) as assayed in vitro correlate with changes in the extent of protein phosphorylation in oocytes pulse-labeled with 32P-phosphate by microinjection during meiotic maturation and the early embryonic cell cycle. This suggests that the kinase(s) has a broad specificity and plays a key role in the increased protein phosphorylation which occurs at the transition to M-phase. Microinjection of the maturation-promoting factor (MPF) into immature oocytes triggers, after a 10-min lag period, the activation of the M-phase specific kinase(s), even in the absence of protein synthesis. In contrast MPF microinjection does not induce kinase activation in cycloheximide-treated oocytes arrested after completion of the first meiotic cell cycle or in activated eggs arrested in S-phase by incubation in cycloheximide. This suggests that immature oocytes contain an inactive kinase precursor (prokinase) which is synthesized at each of the following cell cycles. In the absence of MPF addition, the prokinase to kinase transition occurs "spontaneously" after a 2-hr lag period in high-speed supernatants prepared from prophase-arrested oocytes if low-molecular-weight metabolites are eliminated by gel filtration. Addition of ATP, but not of AMP-PNP (adenylyl-imidodiphosphate), prevents spontaneous kinase activation in gel-filtered extracts. We propose that MPF activates the M-phase-specific protein kinase in the intact cell by inactivating a factor which requires phosphorylation conditions to inhibit the prokinase to kinase transition.

The 46-kDa nucleoside triphosphatase of rat liver nuclear scaffold represents the N-terminal portion of lamins A/C

The major nucleoside triphosphatase (NTPase) of rat liver nuclear scaffold (NS) or envelope, which is thought to participate in nucleocytoplasmic transport, has been identified via photoaffinity labeling as a 46-kDa polypeptide. This 46-kDa protein was purified by SDS-polyacrylamide gel electrophoresis and cleaved with trypsin. The resulting peptides were purified by HPLC and five were microsequenced. All five peptides appear to be derived from the N-terminal region of lamins A/C. Subsequent experiments with photolabeled NS showed that the 46-kDa polypeptide was selectively immunoprecipitated by antiserum specific to lamins A/C and by affinity-purified anti-lamin antibodies. Photolabeling of nuclei prepared in the presence of protease inhibitors showed predominant labeling of the 46-kDa polypeptide, suggesting that it is an integral nuclear constituent and not an artifact produced during NS preparation. Use of protease inhibitors throughout purification of NS increased the specificity of photolabeling of the 46-kDa band by significantly reducing photolabeling of smaller molecular weight components, which arise by proteolysis. Anti-lamin antibodies also produced a significant inhibition of NTPase activity in NS. These results suggest that the N-terminal portion of lamins A/C represents the 46-kDa NTPase, which, according to previous reports, may participate in RNA transport.

Mitotic induction and maintenance by overexpression of a G2-specific gene that encodes a potential protein kinase

There may be a causal relationship between expression of the G2-specific gene nimA and mitotic regulation in Aspergillus. To test this relationship we have introduced extra inducible copies of nimA into Aspergillus and determined the effect of nimA overproduction on mitotic regulation. The results show that nimA overexpression causes mitotic induction in less than a cell cycle and maintains chromatin in a condensed state. These effects occur even if cells are first blocked in S phase. Sequence analysis shows that the nimA gene encodes a potential protein kinase. These data indicate that there is indeed a causal relationship between expression of nimA and the regulation of mitosis and further implicate protein phosphorylation in mitotic control.

Cell-cycle modulation of MPM-2-specific spindle pole body phosphorylation in Aspergillus nidulans

MPM-2 is a monoclonal antibody that interacts with mitosis-specific phosphorylated proteins in many different organisms. Immunocytochemistry of tissue culture cells has shown that MPM-2 stains centrosomes, chromosomes, kinetochores, and spindles. In this paper, we demonstrate that MPM-2 staining colocalizes with the spindle pole body (SPB) of Aspergillus nidulans and that SPB staining varies during the mitotic cycle. In an unsynchronized population, about one-fourth to one-third of the cells stain with MPM-2 at the spindle plaques or SPBs. Nuclei in mitosis have two SPBs localized at the ends of the spindle, both of which stain with MPM-2. To determine when MPM-2 staining appears, we have examined the effects of temperature-sensitive cell-cycle mutations that block nuclear division in S or G2. Only a very small fraction of cells blocked in S-phase stain with MPM-2. In contrast, a large fraction of cells blocked in G2 stain brightly at the SPB. These data suggest that MPM-2 reactivity of SPBs appears in G2. Moreover, the fact that cells blocked in G2 showed MPM-2 staining but no spindles suggests that reactivity of SPBs occurs prior to mitosis but is not sufficient to trigger spindle formation. When G2-blocked cells were downshifted to permissive temperature, they generated a mitotic spindle with an SPB at each end. Both SPBs stained with MPM-2 in all of the mitotic cells.

Lamin A is not synthesized as a larger precursor polypeptide

Isolation of rat liver nuclei in the presence of N-ethylmaleimide (NEM) led to the recovery in the final nuclear matrix of a higher molecular weight form of lamin A. The 2 kDa larger form was identified as lamin A by isoelectric point determination, recognition by an anti-lamin A and C monoclonal antibody and peptide mapping using V8 protease and N-chlorosuccinimide. The 2 kDa extension was tentatively localized to the carboxy-terminus of lamin A. Pulse-chase labeling and immunoprecipitation studies using baby hamster kidney cells showed that lysis of the cells in the presence of NEM allowed the recovery of a stable higher molecular weight form of lamin A. We conclude from these results that NEM prevented the degradation of the native form of lamin A previously thought to represent a higher molecular weight transient precursor form.

Teratocarcinoma stem cells and early mouse embryos contain only a single major lamin polypeptide closely resembling lamin B

The nuclear lamina in adult mammalian somatic cells is composed of three major proteins, lamins A, B, and C. The expression of these proteins during the differentiation of teratocarcinomas and mouse embryogenesis is described. Embryos up to day 8 of gestation and embryonal carcinoma (EC) cells express only a single lamin species closely resembling, if not identical to, lamin B. Lamins A and/or C were detected in fertilized eggs, but disappear during the first 2-4 cleavage divisions, only reappearing in 8 day post-implantation embryos. These two lamins are absent from EC cells, but are strongly expressed in some of their derivatives. These results show that cells of the early mouse embryo do not have a functional requirement for lamins A and C and imply that the structural organization of the nucleus may change fundamentally during embryogenesis.

Protein kinase C activity, protein phosphorylation and germinal vesicle breakdown in Spisula oocytes

To test the possible role of protein kinase C (C-kinase) in regulating germinal vesicle breakdown (GVBD) in Spisula oocytes, we studied the effects of phorbol esters and antagonists of C-kinase on GVBD and protein phosphorylation. Responses to these agents were compared to those elicited by fertilization or increased extracellular K+. The tumor-promoting phorbol ester, 12-O-tetradecanoylphorbol-13-acetate (TPA), a potent agonist of C-kinase, elicited GVBD with half-maximal stimulation at 20 nM. By contrast, 4 alpha-phorbol-12,13-didecanoate, a phorbol ester which does not stimulate C-kinase, did not trigger GVBD. TPA accelerated GVBD when induced by excess K+, but it did not affect the time course of the process when initiated by fertilization. Three structurally different antagonists of C-kinase (W-7, H-7, and retinol) all blocked GVBD when induced by fertilization or TPA. When oocytes were preincubated with [32P]orthophosphate and then stimulated to undergo GVBD by fertilization, TPA, or 45 mM K+, protein phosphorylation was greatly increased, especially for a polypeptide(s) of about 45 kDa. Phosphorylation increased prior to GVBD. Retinol inhibited phosphorylation in activated eggs. C-kinase activity was demonstrated in oocyte extracts. These results strongly suggest that protein phosphorylation by C-kinase is involved in the pathway that regulates GVBD in Spisula oocytes.

The mitotic inducer nim1+ functions in a regulatory network of protein kinase homologs controlling the initiation of mitosis

The newly discovered fission yeast mitotic control element nim1+ (new inducer of mitosis) is the first dose-dependent mitotic inducer identified as a protein kinase homolog. Increased nim1+ expression rescues mutants lacking the mitotic inducer cdc25+ and advances cells into mitosis at a reduced cell size; loss of nim1+ delays mitosis until cells have grown to a larger size. The nim1+ gene potentially encodes a 50 kd protein that contains the consensus sequences of protein kinases. Genetic evidence indicates that nim1+ is a negative regulator of the wee1+ mitotic inhibitor, another protein kinase homolog. The combined mitotic induction activities of nim1+ and cdc25+ counteract the wee1+ mitotic inhibitor in a regulatory network that appears also to involve the cdc2+ protein kinase, which is required for mitosis.

Exposure to caffeine and suppression of DNA replication combine to stabilize the proteins and RNA required for premature mitotic events

Caffeine had been shown to induce mitotic events in Syrian hamster fibroblast (BHK) cells that were arrested during DNA replication (Schlegel and Pardee, Science 232:1264-1266, 1986). Inhibition of protein synthesis blocked these caffeine-induced events, while inhibition of RNA synthesis showed little effect. We now report that the protein(s) that are required for inducing mitosis in these cells were synthesized shortly after caffeine addition, the activity was very labile in the absence of caffeine, and the activity was lost through an ATP-dependent mechanism. Caffeine dramatically increased the stability of these putative proteins while having no effect on overall protein degradation. Experiments with an inhibitor of RNA synthesis indicated that mitosis-related RNA had accumulated during the suppression of DNA replication, and this RNA was unstable when replication was allowed to resume. These results suggest that the stability of RNA needed for mitosis is regulated by the DNA replicative state of the cell and that caffeine selectively stabilizes the protein product(s) of this RNA. Conditions can therefore be selected that permit mitotic factors to accumulate in cells at inappropriate times in the cell cycle. Two-dimensional gel electrophoresis has demonstrated several protein changes resulting from caffeine treatment; their relevance to mitosis-inducing activity remains to be determined.

Disassembly of the nucleus in mitotic extracts: membrane vesicularization, lamin disassembly, and chromosome condensation are independent processes

We describe a stable cell-free mitotic extract derived from Xenopus eggs that contains activities necessary for nuclear envelope breakdown and chromosome condensation during mitosis. Using these cell-free extracts, we have demonstrated that nuclear envelope vesicularization, lamina solubilization, and chromosome condensation are independent and separable biochemical processes. We present evidence indicating that during mitosis nuclear membrane breakdown may involve the binding of a coating protein, lamin solubilization is enzymatically driven, and chromosome condensation involves both binding proteins and enzymatic activities including topoisomerase II. These results provide a coherent framework for investigating structural modification of the nucleus during mitosis at the biochemical level.

The cell cycle control gene cdc2+ of fission yeast encodes a protein kinase potentially regulated by phosphorylation

The cdc2+ gene function has an important role in controlling the commitment of the fission yeast cell to the mitotic cycle and the timing of mitosis. We have raised antibodies against the cdc2+ protein using synthetic peptides and have demonstrated that it is a 34 kd phosphoprotein with protein kinase activity. The protein level and phosphorylation state remain unchanged during the mitotic cycle of rapidly growing cells. When cells cease to proliferate and arrest in G1 the protein becomes dephosphorylated and loses protein kinase activity. Exit from the mitotic cycle and entry into stationary phase may be controlled in part by modulation of the cdc2 protein kinase activity by changes in its phosphorylation state.

Preferential association of acidic actin with nuclei and nuclear matrix from mouse leukemia L5178Y cells

Nuclear matrix prepared from mouse leukemia L5178Y cells contained not only the two common actin isomers, beta and gamma actins, but also two additional acidic species of actin (pI 5.1 and 5.3). An anti-actin antibody recognized these acidic species as well as beta and gamma actins on a nitrocellulose filter following western blotting of two-dimensional electrophoresis. These acidic species were co-purified with beta and gamma actins using DNase I-Sepharose affinity chromatography on the nuclear matrix. Limited digestion of the acidic actin with protease V8 or trypsin gave very similar peptide fragments as did digestion of beta and gamma actins. These acidic actins were found to be distributed in the nuclear fraction, but were scarcely detectable in the cytoplasmic fraction. One of the acidic actins (pI 5.3) was found in all subnuclear fractions (DNase extract, high-salt extract and nuclear matrix), while the other species, the most acidic actin (pI 5.1), was localized predominantly in the nuclear matrix.

A cell free system to study reassembly of the nuclear envelope at the end of mitosis

We described a cell free system involving total homogenates of metaphase CHO cells, which yields telophase-like assembly of nuclear envelopes around mitotic chromosomes. During formation of the nuclear envelope in vitro, the three major lamina polypeptides (lamins A, B, and C) assemble around chromosomes and become dephosphorylated, similar to their behavior in vivo during telophase. Nuclear lamina and envelope assembly apparently do not require free ATP and are strongly inhibited by gamma-S-ATP, supporting the notion that these processes are regulated by protein dephosphorylation. Immunological depletion of disassembled lamins from the initial assembly system results in strong inhibition of subsequent nuclear envelope assembly, directly demonstrating that the lamins are involved in this process.

Homologies in both primary and secondary structure between nuclear envelope and intermediate filament proteins

The A, B and C lamins are the major proteins of the nuclear envelope. The complete nucleotide sequence of the coding region of the A and C lamins shows that these proteins are identical except for their carboxy termini. The most prominent structural feature of both lamins is an alpha-helical region of repeating heptads of amino acids that shows striking homology with the entire family of cytoplasmic intermediate filament proteins. These features suggest that the nuclear envelope is made up of a network of coiled-coil polymers.

The nuclear lamins. A multigene family of proteins in evolution and differentiation

The nuclear lamina consists of a proteinaceous layer or meshwork situated subjacent to the inner nuclear membrane. It is a karyoskeletal structure formed by a polymer containing one to three major polypeptides collectively termed the lamins. In all cells examined of vertebrates and invertebrates, the lamins exhibit very similar Mr ranging from 60 000 to 80 000. In vertebrates, two groups of lamins can be distinguished by their isoelectric value, one being near-neutral and the other acidic (isoelectric pH values of 5.6 and lower). The lamins represent a family of polypeptides with regions highly conserved during evolution. In certain species, e.g., the amphibian, Xenopus laevis, they exhibit cell type-specific expression during embryonic development, terminal differentiation of certain somatic cells, and gametogenesis. The nuclear lamina of diverse cell types can be composed of one, two or three different lamin polypeptides, without obvious differences in its morphology.