Histone synthesis during the cell cycle of Physarum polycephalum. Synthesis of different histone species is not under a common regulatory control

OUP accepted manuscript

DNA replication occurring in S-phase is critical for the maintenance of the cell fate from one generation to the next, and requires the duplication of epigenetic information. The integrity of the epigenome is, in part, insured by the recycling of parental histones and de novo deposition of newly synthesized histones. While the histone variants have revealed important functions in epigenetic regulations, the deposition in chromatin during S-phase of newly synthesized histone variants remains unclear. The identification of histone variants of H3 and unique features of Physarum polycephalum provides a powerful system for investigating de novo deposition of newly synthesized histones by tracking the incorporation of exogenous histones within cells. The analyses revealed that the rate of deposition of H3.1 and H3.3 is anticorrelated as S-phase progresses, H3.3 is predominately produced and utilized in early S and dropped throughout S-phase, while H3.1 behaved in the opposite way. Disturbing the expression of H3 variants by siRNAs revealed mutual compensation of histone transcripts. Interestingly, the incorporation of pre-formed constrained histone complexes showed that tetramers of H3/H4 are more efficiently utilized by the cell than dimers. These results support the model whereby the histone variant distribution is established upon replication and new histone deposition.

Replication-independent nucleosome exchange is enhanced by local and specific acetylation of histone H4

We used a novel single-cell strategy to examine the fate of histones during G₂-phase. Consistent with previous results, we find that in G₂-phase, the majority of nuclear histones are assembled into chromatin, whereas a small fraction comprises an unassembled pool. Small increases in the amount of histones within the free pool affect the extent of exchange, suggesting that the free pool is in dynamic equilibrium with chromatin proteins. Unexpectedly, acetylated H4 is preferentially partitioned to the unassembled pool. Although an increase in global histone acetylation did not affect overall nucleosome dynamics, an H4 containing lysine to glutamine substitutions as mimics of acetylation significantly increased the rate of exchange, but did not affect the acetylation state of neighbouring nucleosomes. Interestingly, transcribed regions are particularly predisposed to exchange on incorporation of H4 acetylation mimics compared with surrounding regions. Our results support a model whereby histone acetylation on K8 and K16 specifically marks nucleosomes for eviction, with histones being rapidly deacetylated on reassembly.

Replication-coupled chromatin assembly of newly synthesized histones: distinct functions for the histone tail domains

The maintenance of the genome during replication requires the assembly of nucleosomes with newly synthesized histones. Achieving the deposition of newly synthesized histones in chromatin implies their transport from the cytoplasm to the nucleus at the replication sites. Several lines of evidence have revealed critical functions of the histone tail domains in these conserved cellular processes. In this review, we discuss the role of the amino termini of the nucleosome building blocks, H2A/H2B and H3/H4, in different model systems. The experimental data showed that H2A/H2B tails and H3/H4 tails display distinct functions in nuclear import and chromatin assembly. Furthermore, we describe recent studies exploiting the unique properties of the slime mold, Physarum polycephalum , that have advanced understanding of the function of the highly conserved replication-dependent diacetylation of H4.

Replication-independent core histone dynamics at transcriptionally active loci in vivo

We used a novel labeling technique in the naturally synchronous organism Physarum polycephalum to examine the fate of core histones in G2 phase. We find rapid exchange of H2A/H2B dimers with free pools that is greatly diminished by treatment of the cells with alpha-amanitin. This exchange is enhanced in pol II-coding sequences compared with extragenic regions or inactive loci. In contrast, H3/H4 tetramers exhibit far lower levels of exchange in the pol II-transcribed genes tested, suggesting that tetramer exchange occurs via a distinct mechanism. However, we find that transcribed regions of the ribosomal RNA gene loci exhibit rapid exchange of H3/H4 tetramers. Thus, our data show that the majority of the pol II transcription-dependent histone exchange is due to elongation in vivo rather than promoter remodeling or other pol II-dependent alterations in promoter structure and, in contrast to pol I, pol II transcription through nucleosomes in vivo causes facile exchange of both H2A/H2B dimers while allowing conservation of epigenetic "marks" and other post-translational modifications on H3 and H4.

Injection of poly(β-l-malate) into the plasmodium of Physarum polycephalum shortens the cell cycle and increases the growth rate

Poly(beta-L-malate) (PMLA) has been reported as an unconventional, physiologically important biopolymer in plasmodia of myxomycetes, and has been proposed to function in the storage and transport of nuclear proteins by mimicking the phospho(deoxy)ribose backbone of nucleic acids. It is distributed in the cytoplasm and especially in the nuclei of these giant, multinucleate cells. We report here for the first time an increase in growth rate and a shortening of the cell cycle after the injection of purified PMLA. By comparing two strains of Physarum polycephalum that differed in their production levels of PMLA, it was found that growth activation and cell cycle shortening correlated with the relative increases of PMLA levels in the cytoplasm or the nuclei. Growth rates of a low PMLA producer strain (LU897 x LU898) were increased by 40-50% while those of a high producer strain (M(3)CVIII) were increased by only 0-17% in comparison with controls. In both strains, shortening of the cell cycle occurred to a similar extent (7.2-9.5%), and this was associated with similar increases in nuclear PMLA levels. The effects showed saturation dependences with regard to the amount of injected PMLA. A steep rise of intracellular PMLA shortly after injection was followed by the appearance of histone H1 in the cytoplasm. The increase in growth rate, the shortening of the cell cycle duration and the appearance of H1 in the cytoplasm suggest that PMLA competes with nucleic acids in binding to proteins that control translation and/or transcription. Thus, PMLA could play an important role in the coordination of molecular pathways that are responsible for the synchronous functioning of the multinucleate plasmodium.

The DNA-polymerase inhibiting activity of poly(beta-l-malic acid) in nuclear extract during the cell cycle of Physarum polycephalum

The naturally synchronous plasmodia of myxomycetes synthesize poly(beta-l-malic acid), which carries out cell-specific functions. In Physarum polycephalum, poly(beta-l-malate) [the salt form of poly(beta-l-malic acid)] is highly concentrated in the nuclei, repressing DNA synthetic activity of DNA polymerases by the formation of reversible complexes. To test whether this inhibitory activity is cell-cycle-dependent, purified DNA polymerase alpha of P. polycephalum was added to the nuclear extract and the activity was measured by the incorporation of [3H]thymidine 5'-monophosphate into acid precipitable nick-activated salmon testis DNA. Maximum DNA synthesis by the reporter was measured in S-phase, equivalent to a minimum of inhibitory activity. To test for the activity of endogenous DNA polymerases, DNA synthesis was followed by the highly sensitive photoaffinity labeling technique. Labeling was observed in S-phase in agreement with the minimum of the inhibitory activity. The activity was constant throughout the cell cycle when the inhibition was neutralized by the addition of spermidine hydrochloride. Also, the concentration of poly(beta-l-malate) did not vary with the phase of the cell cycle [Schmidt, A., Windisch, C. & Holler, E. (1996) Nuclear accumulation and homeostasis of the unusual polymer poly(beta-l-malate) in plasmodia of Physarum polycephalum. Eur. J. Cell Biol. 70, 373-380]. To explain the variation in the cell cycle, a periodic competition for poly(beta-l-malate) between DNA polymerases and most likely certain histones was assumed. These effectors are synthesized in S-phase. By competition they displace DNA polymerase from the complex of poly(beta-l-malate). The free polymerases, which are no longer inhibited, engage in DNA synthesis. It is speculated that poly(beta-l-malate) is active in maintaining mitotic synchrony of plasmodia by playing the mediator between the periodic synthesis of certain proteins and the catalytic competence of DNA polymerases.

A novel labeling technique reveals a function for histone H2A/H2B dimer tail domains in chromatin assembly in vivo

During S phase in eukaryotes, assembly of chromatin on daughter strands is thought to be coupled to DNA replication. However, conflicting evidence exists concerning the role of the highly conserved core histone tail domains in this process. Here we present a novel in vivo labeling technique that was used to examine the role of the amino-terminal tails of the H2A/H2B dimer in replication-coupled assembly in live cells. Our results show that these domains are dispensable for nuclear import but at least one tail is required for replication-dependent, active assembly of H2A/H2B dimers into chromatin in vivo.

Assembly into chromatin and subtype-specific transcriptional effects of exogenous linker histones directly introduced into a living Physarum cell

The apparent diversity of linker histone subtypes may be related to their specific roles in defining functional states of chromatin in vivo. We have developed a novel method to study constitutive peptides throughout the cell cycle and have demonstrated that an exogenous linker histone could be introduced into a living cell of the slime mold Physarum polycephalum. Here, we have used this method to assess the functional differences between three somatic linker histone subtypes in vivo, and to demonstrate the general applicability of this method. Exogenous linker histone proteins H1 degrees, H5 and H1 were directly absorbed into living cell segments of the naturally synchronous Physarum macroplasmodia at precise cell cycle stages. Fluorescence microscopy, native nucleoprotein gels and immunoblotting of nuclei and chromatin with subtype-specific antibodies revealed that exogenous linker histones were efficiently transported into nuclei and were integrated into chromatin. The immunoreactivity of a preparation of anti-H1 degrees antibodies that are blocked from binding to specific H1 degrees epitopes in native chromatin indicates that the exogenous linker histones were similarly associated into Physarum chromatin. Interestingly, linker histones were found to be less stably associated with Physarum chromatin during S-phase than during G(2)-phase. Furthermore, we show that exogenous linker histones incorporated in early G(2)-phase inhibited transcription and that the level of inhibition correlates with the apparent role of the linker histone subtype in regulating transcription in cells where it normally occurs.

Efficient antibody generation using histone H1 subfractions purified from western blots

Linker histones from grapevine were purified by electrophoretic methods (SDS-PAGE and electrotransfer onto a nitrocellulose sheet). Individual linker histones were recovered after nitrocellulose solubilization by acetone. The proteins precipitated after this treatment were used as antigen for subsequent immunizations of mice. Such purified immunogens were injected into mice with dimethyl sulfoxide, as the presence of nitrocellulose-protein complexes in the antigen pellets after the acetone treatment was suspected. The resulting antisera were specific to the injected antigens after only the first immunization and could be used as specific probes in immunohistological studies. Our approach seems more efficient (in using less antigen and obtaining a faster response) than the classical procedure recommended for histones in general (B. D. Stollar and M. Ward, 1970, J. Biol. Chem. 245, 1261-1266) and other methods that use free linker histone as immunogen.

Histone synthesis in Trypanosoma cruzi

Trypanosoma cruzi is an ancient, parasitic eukaryote which does not undergo chromatin condensation during cell division. This behavior may be explained if one considers the strong amino acid sequence divergence of Trypanosoma histones compared to higher eukaryotes. In the latter organisms histone synthesis is coupled to DNA replication. Considering the nonconserved amino acid sequence of T. cruzi histones, as well as the absence of chromatin condensation in this organism, we have studied histone synthesis in relation to DNA replication in this parasite. We have found that core histones and a fraction of histone H1 are synthesized concomitantly to DNA replication. However, another fraction of histone H1 is constitutively synthesized.

Antisera directed against anti-histone H4 antibodies recognize linker histones. Novel immunological probes to detect histone interactions

We introduce a novel immunological approach to detect structural interactions between chromosomal proteins. Antigenically pure core histone H4 was prepared from chicken erythrocytes and used to produce anti-histone H4 antisera. IgG fractions were isolated from purified anti-H4 antibodies and used as antigens to produce "second generation" antisera. Epitopes cross-reacting with the second generation antisera were then identified within chromosomal proteins. These epitopes were presumed to mimic the complementary molecular surface of the original anti-H4 antibodies, and thus proteins containing these epitopes were putatively identified as specific ligands of H4 in chromatin. Surprisingly, we found this immunoreactivity was predominantly directed against H1 compared with H5 from chicken erythrocytes. Further, the immunoreactive epitopes were located within the C-terminal tail domain of the linker histones. These results suggest similar complementary interactions occur between H4 and the C-terminal tail domain of H1s in native chromatin. This could occur either within a single nucleosome as suggested by a previous report (Banères, J.-L., Essalouh, L., Jariel-Encontre, I., Mesnier, D., Garrod, S., and Parello, J. (1994) J. Mol. Biol., 243, 48-59) or between neighboring nucleosomes within the condensed chromatin fiber. The implications of these results with regard to the structure of the chromatin fiber and the future utility of this technique are discussed.

Nuclear matrix and the cell cycle

The facts that the nuclear matrix represents a structural framework of the cell nucleus and that nuclear events, such as DNA replication, transcription, and DNA repair, are associated with this skeletal structure suggest that its components are subject to cell cycle-regulatory mechanisms. Cell cycle regulation has been shown for nuclear lamina assembly and disassembly during mitosis and chromatin reorganization. Little attention has so far been paid to internal nuclear matrix proteins and matrix-associated proteins with respect to the cell cycle. This survey attempts to summarize available data and presents experimental evidence that important metabolic functions of the nucleus are regulated by the transient, cell cycle-dependent attachment of enzymes and regulatory proteins to the nuclear matrix. Results on thymidine kinase and RNA polymerase during the synchronous cell cycle of Physarum polycephalum demonstrate that reversible binding to the nuclear matrix represents an additional level of regulation for nuclear processes.

Rapid and effective western blotting of histones from acid-urea-Triton and sodium dodecyl sulfate polyacrylamide gels: two different approaches depending on the subsequent qualitative or quantitative analysis

An improved method for the electrophoretic transfer of histones from sodium dodecyl sulfate (SDS) and acetic acid-urea-Triton X-100 (AUT) polyacrylamide gels onto nitrocellulose membranes is described. In the case of SDS-gels, it was not essential to equilibrate them before transfer while for the AUT-gels, an equilibration step is essential to prevent the interference of Triton X-100 with the binding of histones to nitrocellulose. Transfer efficiency was different for different histone classes. Two procedures were developed: (1) one suitable for qualitative studies, and (ii) another for quantitative transfer.

Nuclear matrix of the lower eukaryote Physarum polycephalum and the mammalian epithelial LLC-PK1 cell line. A comprehensive investigation of different preparation procedures

Agarose-encapsulated nuclear matrix preparations of the lower eukaryote Physarum polycephalum and the mammalian renal epithelial LLC-PK1 cell line were analyzed after various experimental protocols with respect to the protein composition. The effect of the mode of deproteinization (2 M NaCl, 0.25 M ammonium sulfate or 25 mM lithium diiodosalicylate), presence of 2-mercaptoethanol, Ca2+, Cu2+, chelating agents, the sequence of protein extraction and nuclease digestion, the use of RNase, the temperature at which the experimental manipulations were performed and the use of hypotonic or isotonic conditions was investigated. No significant differences in the final nuclear matrix composition could be observed, regardless of the experimental procedure applied. In Physarum, the major nuclear matrix proteins range over 12-70 kDa with prominent bands at 24, 31, 37 and 45 kDa; the proteins of the matrix in LLC-PK1 cells extend predominantly over 40-80 kDa. Furthermore, no essential differences in the protein composition could be observed when type I and type II nuclear matrices from the highly differentiated LLC-PK1 cell line were compared. The same was found for analogous matrix preparations of Physarum. Therefore, in both systems a distinction between type I/II matrix is questionable. Immunoblotting of the matrix preparations with a variety of antibodies against intermediate filament proteins and with antinuclear autoantibodies revealed the presence of intermediate filament proteins as components of the nuclear matrix. We conclude that the nuclear matrix represents a much more stable and reproducible structure than has been proposed so far, largely independent of changes in the preparation protocol.

Change in chromatin organization related to in vivo transcriptional activity and histone synthesis independent of DNA replication during differentiation (germination) of Physarum spherules

During the germination of Physarum spherules, increases have been observed, at the same moment, in the level of in vivo transcriptional activity as measured by [³H] uridine incorporation, and the accessibility of DNA for ethidium bromide staining as shown by flow cytometric measurements. We suppose that the changes observed in these two processes are due to a difference in chromatin organization between the first and the second period of the premitotic germination stage. In the second period, the four nucleosome core histories are synthesized in the absence of DNA replication and may correspond to a replacement of spherulation histone variants by plasmodial histone types in nucleosomes. The synthesis of historic H₄ clearly distinguishes the second period of the premitotic germination stage from a growing plasmodium G₂ phase, though nuclei exhibit a G₂ phase DNA content. The same pattern of histone synthesis has been found during the cell cycle following the first mitosis after germination and the growing plasmodium cell cycle, with a synthesis of two histories H₂B and H₂A and the high mobility group (HMG)-like protein AS₃ during the G₂ phase, i.e. in the absence of DNA synthesis.

Enzymes involved in the dynamic equilibrium of core histone acetylation of Physarum polycephalum

DEAE-Sepharose chromatography of extracts from plasmodia of the myxomycete Physarum polycephalum revealed the presence of multiple histone acetyltransferases and histone deacetylases. A cytoplasmic histone acetyltransferase B, specific for histone H4, and two nuclear acetyltransferases A1 and A2 were identified; A1 acetylates all core histones with a preference for H3 and H2A, whereas A2 is specific for H3 and also slightly for H2B. Two histone deacetylases, HD1 and HD2, could be discriminated. They differ with respect to substrate specificity and pH dependence. For the first time the substrate specificity of histone deacetylases was determined using HPLC-purified individual core histone species. The order of acetylated substrate preference is H2A much greater than H3 greater than or equal to H4 greater than H2B for HD1 and H3 greater than H2A greater than H4 for HD2, respectively; HD2 is inactive with H2B as substrate. Moreover histone deacetylases are very sensitive to butyrate, since 2 mM butyrate leads to more than 50% inhibition of enzyme activity.

Regulation of tubulin synthesis during the cell cycle in the synchronous plasmodia of Physarum polycephalum

Regulation of alpha- and beta-tubulin isotype synthesis during the cell cycle has been studied in the myxomycete Physarum polycephalum, by subjecting synchronous plasmodia to temperature shifts and pharmacological perturbations. Temperature shifts interfered with the regulation of tubulin synthesis. Inhibition of DNA synthesis prevents tubulin degradation after completion of the cell cycle (Ducommun and Wright, Eur. J. Cell Biol., 50:48-55, 1989) but did not perturb the initiation of tubulin synthesis. The constant increase of tubulin synthesis in the presence of tubulin-sequestering drugs and the decrease of tubulin synthesis during a treatment with aphidicolin in late G2 phase suggest the existence of an autoregulatory mechanism of tubulin synthesis. Moreover, the microtubule poison methyl benzimidazole carbamate dissociated synthesis of the alpha 1-tubulin isotype from the generally strictly coordinated synthesis of all tubulin isotypes during the transient interruption of mitosis. These observations show that a microtubular poison can perturb regulation of the synthesis of specific isotubulins.

Towards an understanding of the biological function of histone acetylation

A model is presented which explains the biological function of posttranslational acetylation of core histones in chromatin. Along the lines of this model histone acetylation serves as a general mechanism to destabilize nucleosome core particles during various processes occurring in chromatin. Acetylation acts as a signal that modulates histone-protein and histone-DNA interactions and finally leads to the displacement of particular histones from nucleosome cores. The high specificity of the acetylation signal for different processes (DNA replication, transcription, differentiation-specific histone replacement) is achieved by site specificity and asymmetry of acetylation in nucleosomes. The essential features of this model are in accord with the more recent results on histone acetylation.