Phosphorylation of cleavage stage histone H1 in mitotic and prematurely condensed chromosomes

The topoisomerase II inhibitor VM-26 induces marked changes in histone H1 kinase activity, histones H1 and H3 phosphorylation, and chromosome condensation in G2 phase and mitotic BHK cells

We have examined the effects of topoisomerase inhibitors on the phosphorylation of histones in chromatin during the G2 and the M phases of the cell cycle. Throughout the G2 phase of BHK cells, addition of the topoisomerase II inhibitor VM-26 prevented histone H1 phosphorylation, accompanied by the inhibition of intracellular histone H1 kinase activity. However, VM-26 had no inhibitory effect on the activity of the kinase in vitro, suggesting an indirect influence on histone H1 kinase activity. Entry into mitosis was also prevented, as monitored by the absence of nuclear lamina depolymerization, chromosome condensation, and histone H3 phosphorylation. In contrast, the topoisomerase I inhibitor, camptothecin, inhibited histone H1 phosphorylation and entry into mitosis only when applied at early G2. In cells that were arrested in mitosis, VM-26 induced dephosphorylation of histones H1 and H3, DNA breaks, and partial chromosome decondensation. These changes in chromatin parameters probably reverse the process of chromosome condensation, unfolding condensed regions to permit the repair of strand breaks in the DNA that were induced by VM-26. The involvement of growth-associated histone H1 kinase in these processes raises the possibility that the cell detects breaks in the DNA through their effects on the state of DNA supercoiling in constrained domains or loops. It would appear that histone H1 kinase and topoisomerase II work coordinately in both chromosome condensation and decondensation, and that this process participates in the VM-26-induced G2 arrest of the cell.

Mitosis-specific histone H3 phosphorylation in vitro in nucleosome structures

A mechanism of mitosis-specific enhancement of histone H3 phosphorylation was analyzed in vitro in terms of nucleosome structure. The incorporation of [32P]phosphate into DNA-bound H3 was approximately 5-7 times higher than in DNA-free H3 using the catalytic subunit of cAMP-dependent protein kinase. The two major N-terminal serine sites, including the mitosis-specific site (Ser10) and Ser28, were extensively phosphorylated in the DNA-bound forms. These phosphorylation patterns were identical to those of nucleosomal H3. In contrast, the H3 in DNA-free octamers was very slightly phosphorylated. The major site of H3 phosphorylation in DNA-free H3 was Thr118 in the C-terminus. Results indicate that DNA-binding is essential for the high level of mitosis-specific H3 phosphorylation, and that the nucleosome structure promotes H3 N-terminal phosphorylation in vitro. It also suggests the possibility that H1 prevents H3 phosphorylation during interphase of the cell cycle.

6DMAP inhibits chromatin decondensation but not sperm histone kinase in sea urchin male pronuclei

Treatment of sea urchin eggs for 10 min prior to fertilization with the kinase inhibitor 6DMAP (6-dimethylaminopurine) reversibly inhibits swelling and loss of conical morphology of the male pronucleus. Male pronuclei inhibited with 1 mM 6DMAP for 25 min undergo phosphorylation of Sp H1 and Sp H2B histones as fully as do control nuclei. Therefore, Sp histone kinase, whose target sequences resemble those of the M-phase histone kinase, is not inhibited by 6DMAP, and Sp histone phosphorylation, although it may be necessary, is not sufficient for chromatin decondensation.

Characterization of phosphorylation sites in histone H1 in the amitotic macronucleus of Tetrahymena during different physiological states

Histone H1 is highly phosphorylated in transcriptionally active, amitotic macronuclei of Tetrahymena during vegetative growth. However, the level of H1 phosphorylation changes dramatically in response to different physiological conditions. H1 is hyperphosphorylated in response to heat shock and during prezygotic stages of conjugation. Conversely, H1 is largely dephosphorylated during prolonged starvation and during elimination of parental macronuclei during conjugation. Mapping of phosphorylation sites within H1 indicates that phosphorylation occurs at multiple sites in the amino-terminal portion of the molecule, predominantly at threonine residues. Two of these sites have been identified by compositional analyses and microsequencing of tryptic peptides. Interestingly, two major sites contain the sequence Thr-Pro-Val-Lys similar to that contained in the sites recognized by growth-associated histone kinase in other organisms. No new sites are detected during the hyperphosphorylation of H1 which occurs during heat shock or in early stages of conjugation, and no sites are preferentially dephosphorylated during starvation or later stages of conjugation. Therefore, changes in the overall level of H1 phosphorylation, as opposed to phosphorylation or dephosphorylation at particular sites, appear to be important in the regulation of chromatin structure under these physiological conditions. Further, since no cell division or DNA replication occurs under these conditions, changes in the level of H1 phosphorylation are best correlated to changes in gene expression during heat shock, starvation, and conjugation. We suggest that, at least in Tetrahymena, H1 hyperphosphorylation is used as a rapid and transient mechanism for the cessation of transcription under conditions of cellular stress.

Possible target of Abelson virus phosphokinase in cell transformation

By fusing interphase cells to cells undergoing mitosis, the interphase chromosomes can be visualized. When analyzed in this way, chromosomes of normal mouse cells show characteristic undercondensed centromeric regions. We have found that the centromeric regions of chromosomes from Abelson virus-transformed cells are fully condensed. Abelson virus transforms mouse cells by introducing into them a virally encoded phosphokinase that is expressed constitutively. Thus, we propose that the condensation of centromeric chromatin is a result of overphosphorylation by the Abelson virus phosphokinase, and that the centromeric region is the relevant target of overphosphorylation in transformed cell growth.

Histone phosphorylation in native chromatin induces local structural changes as probed by electric birefringence

In order to understand how the phosphorylation of histones affects the chromatin structure, we used electron microscopy, sedimentation velocity, circular dichroism and electric birefringence to monitor the salt-induced filament reversible solenoid transition of phosphorylated and native chromatin. Phosphorylation in vitro of chicken erythrocyte chromatin by cyclic-AMP-dependent protein kinase from porcine heart led to the modification of the histones H3 and H5 only, which were modified at a level of one phosphate and about three phosphate groups per molecule, respectively. In contrast to circular dichroism and sedimentation studies, which tend to suggest that phosphorylation of H3 and H5 does not affect chromatin structure, electron microscopy reveals that phosphorylation causes a relaxation of structure at low ionic strength. Electric birefringence and relaxation time measurements clearly prove that local structural changes are induced in chromatin: we observe a decrease of the steady-state birefringence with the appearance of a negative contribution in the signal and a marked increase of the flexibility of fibres. The component with the negative birefringence presents very short relaxation times, like those exhibited by small DNA fragments or individual nucleosomes. Two possibilities are then suggested. First, the conformational change is consistent with what would be expected from the presence of DNA segments loosely associated with the core histone H3. That the length of such segments could correspond to about one to two base-pairs per nucleosome strongly suggests that phosphorylation induces changes affecting some specific H3-DNA interactions only. This result could corroborate previous observations indicating that the N-terminal region of H3, where the site of phosphorylation is located, plays a decisive role in maintaining the superstructure of chromatin. Second, phosphorylation could introduce hinge points between each nucleosome. In this case, the negative birefringence results from partial orientation of the swinging nucleosomes. A possible mode of action of phosphorylation might be to weaken structural restraints imposed by histone H3, thus facilitating further condensation of chromatin.

Distribution of histone H1 alpha among cells of the sea urchin embryo

We have used immunofluorescent staining of sea urchin embryos to study how histone H1 alpha is distributed among progeny cells formed after the cessation of its synthesis. Our results are consistent with H1 alpha being distributed to both daughter cells at mitosis, resulting in it being most concentrated in cells that stop dividing shortly after H1 alpha synthesis ends, while cells that continue to divide dilute their H1 alpha content in proportion to the number of cell divisions. This rules out our earlier suggestion that H1 alpha becomes segregated in dividing cells. In addition, our results show that most dividing cells of the 3-day embryo contain predominantly H1 beta and H1 gamma. Since these subtypes are known not to undergo phosphorylation, this finding has implications regarding the roles of H1 phosphorylation in the cell cycle.

RNA synthesis in male pronuclei of the sea urchin

Transcription in male pronuclei of fertilized sea urchin eggs was measured by comparison of [3H]uridine incorporation into RNA in polyspermic, monospermic and activated eggs under conditions where uptake of the isotope and conversion to UTP were equivalent. RNA accumulation from male pronuclei begins by S phase of the first cell cycle. Initiation of this RNA synthesis does not require DNA synthesis. A major fraction of the newly synthesized transcripts are mRNAs coding for early embryo (alpha-) histones. In addition, several other unidentified transcripts are detected by gel electrophoresis. The pattern of RNA transcription remains constant for at least 4 h post-fertilization. These results demonstrate that specific transcription of male pronuclear sequences is activated in the first cell cycle following fertilization.

Phosphorylation of non-histone proteins associated with mitosis in HeLa cells

Our previous studies indicated that certain non-histone proteins (NHP) extractable with 0.2 M NaCl from mitotic HeLa cells induce germinal vesicle breakdown and chromosome condensation in Xenopus laevis oocytes. Since the maturation-promoting activity of the mitotic proteins is stabilized by phosphatase inhibitors, we decided to examine whether phosphorylation of NHP plays a role in the condensation of chromosomes during mitosis. HeLa cells, synchronized in S phase, were labeled with 32P at the end of S phase, and the cells subsequently collected while they were in G2, mitosis, or G1. Cytoplasmic, nuclear, or chromosomal proteins were extracted and separated by gel electrophoresis. The labeled protein bands were detected by radioautography. The results indicated an 8-10-fold increase in the phosphorylation of NHP from mid-G2 to mitosis, followed by a similar-size decrease as the cells divided and entered G1. The NHP phosphorylation rate increased progressively during G2 traverse and reached a peak in mitosis. Radioautography of the separated NHP revealed eight prominent, extensively phosphorylated protein bands with molecular masses ranging from 27.5 to 100 kD. These NHP were rapidly dephosphorylated during M-G1 transition. Phosphorylation-dephosphorylation of NHP appeared to be a dynamic process, with the equilibrium shifting to phosphorylation during G2-M and dephosphorylation during M-G1 transitions. These results suggest that besides histone H1 phosphorylation, phosphorylation of this subset of NHP may also play a part in mitosis.

Injected mitotic extracts induce condensation of interphase chromatin

Although extracts from mitotic cells have been shown to induce chromosome condensation when injected into amphibian oocytes, they have not as yet been shown to induce this response in somatic interphase cells. In the experiments reported here, when mitotic extracts were injected into syncytial frog embryos, whose somatic nuclei were arrested in interphase, chromosome condensation was observed. The inability of interphase extracts, injected at similar concentrations, to induce this event demonstrates the cell cycle-specific accumulation of the factors responsible.

Relationship between histone phosphorylation and premature chromosome condensation

The relationship between histone phosphorylation and chromosome condensation was investigated by determining changes in phosphorylation levels of histones H1 and H3 following fusion between mitotic and interphase cells and subsequent premature chromosome condensation. We detected significant increases in the levels of phosphorylation of H1 and H3 from interphase chromatin in which a majority of nuclei had undergone premature chromosome condensation. In addition, we noted significant decreases in the phosphate content of the highly phosphorylated mitotic H1 and H3, presumably resulting from phosphatase activity contributed by the interphase component of mitotic/interphase fused cells. These observations further strengthen the correlation between histone phosphorylation and the changes in chromosome condensation associated with the initiation of mitosis. This study also suggests that maintenance of the mitotic chromosomes in a highly condensed state does not require the continued presence of histones in a highly phosphorylated form.

Phosphorylation of nuclear proteins

Many nuclear proteins are phosphorylated: they range from enzymes to several structural proteins such as histones, non-histone chromosomal proteins and the nuclear lamins. The pattern of phosphorylation varies through the cell cycle. Although histone H1 is phosphorylated during interphase its phosphorylation increases sharply during mitosis. Histone H3, chromosomal protein HMG 14 and lamins A, B and C all show reversible phosphorylation during mitosis. Several nuclear kinases have been characterized, including one that increases during mitosis and phosphorylates H1 in vitro. Factors have been demonstrated in maturing amphibian oocytes and mitotic mammalian cells that induce chromosome condensation and breakdown of the nuclear membrane. The possibility that they are autocatalytic protein kinases is considered. The location of histone phosphorylation sites within the nucleosome is consistent with a role for phosphorylation in modulating chromatin folding.

Monoclonal antibodies to mitotic cells

Certain proteins or activities are present in mitotic cells but not in interphase cells. These proteins may be synthesized or activated, or both, just prior to mitosis and are responsible for the breakdown of the nuclear envelope and the condensation of chromosomes. To learn more about the nature of these proteins, we raised monoclonal antibodies to mitotic cells. Spleen cells from mice immunized with a 0.15 M NaCl extract of synchronized mitotic HeLa cells were fused with SP2/0-Ag14 mouse myeloma cells, and hybrids were selected in medium containing hypoxanthine, methotrexate, thymidine, and glycine. Two different hybridoma clones secreting antibodies reactive with mitotic and meiotic cells from every species tested were isolated. Chromosomes as well as cytoplasm in mitotic cells reacted with the antibodies, as detected by indirect immunofluorescence. The proteins from mitotic cells were separated by electrophoresis in NaDodSO4/polyacrylamide slab gels, transferred to nitrocellulose sheets, and stained immunochemically. The two antibodies, designated MPM-1 and MPM-2, recognize a family of polypeptides with apparent molecular masses of 0.40 to greater than 200 kilodaltons (kDa). Both antibodies reacted strongly with three polypeptide bands of 182 kDa, 118 kDa, and 70 kDa. Only mitotic cells exhibited the protein bands that were recognized by the antibodies. All these bands were found to be phosphoproteins as shown by 32P labeling and autoradiography and their removal by alkaline phosphatase treatment.

The increased phosphorylation of ribosomal protein S6 in Arbacia punctulata is not a universal event in the activation of sea urchin eggs

Eggs of the sea urchins Arbacia punctulata (Ap), Lytechinus pictus (Lp), and Strongylocentrotus purpuratus (Sp) were labeled to equilibrium with 32PO3-4. Approximately 65-70% of the label in extractable adenine nucleotides comigrates chromatographically with ATP. Autoradiograms of one-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) slab gels show that each species possesses a distinct complement of phosphate-exchangeable phosphoproteins. No changes in the phosphoprotein composition are detected in Lp and Sp eggs as a result of fertilization or development for 2.5 hr (with the possible exception of a 43,000 Mr protein in Lp). In Ap, increases in the phosphorylation of bands at Mr's 30,000, 55,000, and 105,000 are seen during the first 10 min postinsemination. The 30,000 Mr band in Ap eggs has previously been identified as ribosomal protein S6 and the hypothesis presented that its increased phosphorylation may be an important step in the activation of protein synthesis at fertilization (D. G. Ballinger and T. Hunt, 1981, Dev. Biol. 87, 277-285). In Lp and Sp eggs S6 (identified by two-dimensional PAGE) is heavily phosphorylated in the unfertilized state and the extent of labeling does not increase after fertilization. If the increased phosphorylation of S6 seen in Ap is indeed related to translational activation, then these results suggest that different sea urchin species may rely on different mechanisms for the activation of protein synthesis.