Nitric oxide synthase is induced in sporulation of Physarum polycephalum

The myxomycete Physarum polycephalum expresses a calcium-independent nitric oxide (NO) synthase (NOS) resembling the inducible NOS isoenzyme in mammals. We have now cloned and sequenced this, the first nonanimal NOS to be identified, showing that it shares < 39% amino acid identity with known NOSs but contains conserved binding motifs for all NOS cofactors. It lacks the sequence insert responsible for calcium dependence in the calcium-dependent NOS isoenzymes. NOS expression was strongly up-regulated in Physarum macroplasmodia during the 5-day starvation period needed to induce sporulation competence. Induction of both NOS and sporulation competence were inhibited by glucose, a growth signal and known repressor of sporulation, and by L-N6-(1-iminoethyl)-lysine (NIL), an inhibitor of inducible NOS. Sporulation, which is triggered after the starvation period by light exposure, was also prevented by 1H-[1,2,4]oxadiazolo-[4,3-a]quinoxalin-1-one (ODQ), an inhibitor of NO-sensitive guanylate cyclase. In addition, also expression of lig1, a sporulation-specific gene, was strongly attenuated by NIL or ODQ. 8-Bromo-cGMP, added 2 h before the light exposure, restored the capacity of NIL-treated macroplasmodia to express lig1 and to sporulate. This indicates that the second messenger used for NO signaling in sporulation of Physarum is cGMP and links this signaling pathway to expression of lig1.

GTP cyclohydrolase I mRNA: novel splice variants in the slime mould Physarum polycephalum and in human monocytes (THP-1) indicate conservation of mRNA processing

GTP cyclohydrolase I (EC 3.5.4.16) is the first enzyme in the biosynthesis of tetrahydrobiopterin [(6R)-5,6,7,8-tetrahydro-L-biopterin, H(4)-biopterin] in mammals and of folic acid in bacteria. Here we have characterized the GTP cyclohydrolase I gene structure and two mRNA species from Physarum polycephalum, an acellular slime mould that synthesizes H(4)-biopterin and metabolites of the folic acid biosynthetic pathway. Its GTP cyclohydrolase I gene consists of seven exons, and the two GTP cyclohydrolase I cDNA species isolated from Physarum encode for proteins with 228 (25.7 kDa) and 195 (22.1 kDa) amino acids. Furthermore, we identified two previously undescribed mRNA species in interferon-gamma-treated human myelomonocytoma cells (THP-1) in addition to the cDNA coding for the fully functional 250-residue (27.9 kDa) protein, which is identical with that in human phaeochromocytoma cells. One of the new splice variants codes for a 233-residue (25.7 kDa) protein, whereas the other codes for the full-length protein but is alternatively spliced within the 3'-untranslated region. In heterologous expression, the shorter proteins of Physarum as well as of THP-1 cells identified here are degraded by proteolysis. Accordingly, only the 27.9 kDa protein was detectable in Western blots from THP-1 cell extracts. Quantification of GTP cyclohydrolase I mRNA species in different human cell types with and without cytokine treatment showed that in addition to the correct mRNA the two splice variants isolated here, as well as the two splice variants known from human liver, are strongly induced by cytokines in cell types with inducible GTP cyclohydrolase I (THP-1, dermal fibroblasts), but not in cell types with constitutive GTP cyclohydrolase I expression (SK-N-SH, Hep-G2). As in human liver, splicing of the new mRNA variant found in THP-1 cells occurs at the boundary of exons 5 and 6. Strikingly, the 195-residue protein from Physarum is alternatively spliced at a homologous position, i.e. at the boundary of exons 6 and 7. Thus alternative splicing of GTP cyclohydrolase I at this position occurs in two species highly distant from each other in terms of evolution. It remains to be seen whether variant proteins encoded by alternatively spliced GTP cyclohydrolase I mRNA transcripts do occur in vivo and whether they participate in regulation of enzyme activity.

Control of ribosomal protein L1 synthesis in mesophilic and thermophilic archaea

The mechanisms for the control of ribosomal protein synthesis have been characterized in detail in Eukarya and in Bacteria. In Archaea, only the regulation of the MvaL1 operon (encoding ribosomal proteins MvaL1, MvaL10, and MvaL12) of the mesophilic Methanococcus vannielii has been extensively investigated. As in Bacteria, regulation takes place at the level of translation. The regulator protein MvaL1 binds preferentially to its binding site on the 23S rRNA, and, when in excess, binds to the regulatory target site on its mRNA and thus inhibits translation of all three cistrons of the operon. The regulatory binding site on the mRNA, a structural mimic of the respective binding site on the 23S rRNA, is located within the structural gene about 30 nucleotides downstream of the ATG start codon. MvaL1 blocks a step before or at the formation of the first peptide bond of MvaL1. Here we demonstrate that a similar regulatory mechanism exists in the thermophilic M. thermolithotrophicus and M. jannaschii. The L1 gene is cotranscribed together with the L10 and L11 gene, in all genera of the Euryarchaeota branch of the Archaea studied so far. A potential regulatory L1 binding site located within the structural gene, as in Methanococcus, was found in Methanobacterium thermoautotrophicum and in Pyrococcus horikoshii. In contrast, in Archaeoglobus fulgidus a typical L1 binding site is located in the untranslated leader of the L1 gene as described for the halophilic Archaea. In Sulfolobus, a member of the Crenarchaeota, the L1 gene is part of a long transcript (encoding SecE, NusG, L11, L1, L10, L12). A previously suggested regulatory L1 target site located within the L11 structural gene could not be confirmed as an L1 binding site.

Interaction of ribosomal L1 proteins from mesophilic and thermophilic Archaea and Bacteria with specific L1-binding sites on 23S rRNA and mRNA

In Bacteria and Archaea (formerly Archaebacteria) ribosomal protein L1 has a dual function, as a primary rRNA-binding protein and as a translational repressor which binds to its own mRNA. The L1-binding site on the mRNA exhibits high similarity in both sequence and secondary structure to the binding site for L1 on the 23 S rRNA. A sensitive membrane-filter-binding assay has been used to examine the interactions between ribosomal L1 proteins from different archaeal and bacterial species, and 23S rRNA and mRNA fragments from Methanococcus vannielii containing the MvaL1-binding site. Under standard conditions (0 degrees C, pH 7.5, 20 mM Mg2+, 500 mM KCl), the apparent dissociation constant Kd of the homologous MvaL1-23S rRNA complex is 5 nM, the apparent dissociation constant Kd of the MvaL1-mRNA complex is 0.15 degrees M. L1 proteins from Escherichia coli (EcoL1) and from the thermophilic Bacterium Thermus thermophilus (TthL1), and from the thermophilic Archaea Methanococcus thermolithotrophicus (MthL1), Methanococcus jannaschii (MjaL1), and Sulfolobus solfataricus (SsoL1) were tested for their affinity to the specific L1-binding sites on the 23 S rRNA and mRNA. In general, the affinity of L1 proteins from thermophilic species to the binding sites on both 23 S rRNA and mRNA is about one order of magnitude higher than that of their mesophilic counterparts. This stronger protein-RNA interaction might make a substantial contribution to the thermal tolerance of ribosomes in thermophilic organisms.

MvaL1 autoregulates the synthesis of the three ribosomal proteins encoded on the MvaL1 operon of the archaeon Methanococcus vannielii by inhibiting its own translation before or at the formation of the first peptide bond

The control of ribosomal protein synthesis has been investigated extensively in Eukarya and Bacteria. In Archaea, only the regulation of the MvaL1 operon (encoding ribosomal proteins MvaL1, MvaL10 and MvaL12) of Methanococcus vannielii has been studied in some detail. As in Escherichia coil, regulation takes place at the level of translation. MvaL1, the homologue of the regulatory protein L1 encoded by the L11 operon of E. coli, was shown to be an autoregulator of the MvaL1 operon. The regulatory MvaL1 binding site on the mRNA is located about 30 nucleotides downstream of the ATG start codon, a sequence that is not in direct contact with the initiating ribosome. Here, we demonstrate that autoregulation of MvaL1 occurs at or before the formation of the first peptide bond of MvaL1. Specific interaction of purified MvaL1 with both 23S RNA and its own mRNA is confirmed by filter binding studies. In vivo expression experiments reveal that translation of the distal MvaL10 and MvaL12 cistrons is coupled to that of the MvaL1 cistron. A mRNA secondary structure resembling a canonical L10 binding site and preliminary in vitro regulation experiments had suggested a co-regulatory function of MvaL10, the homologue of the regulatory protein L10 of the beta-operon of E. coil. However, we show that MvaL10 does not have a regulatory function.

Nucleotide sequence of a gene cluster encoding NusG and the L11-L1-L10-L12 ribosomal proteins from the thermophilic archaeon Sulfolobus solfataricus

The complete nucleotide sequence of a gene cluster encoding the NusG and the L 11-L1-L10-L12 ribosomal proteins from the thermophilic crenarchaeon Sulfolobus solfataricus has been determined. The genes are arranged in the same order as the equivalent genes in the rif region of Escherichia coli. The ribosomal proteins exhibit between 66% (L10) and 80% (L12) identity with their respective equivalents from Sulfolobus acidocaldarius. The short distance (5 nucleotides) between the nusG stop codon and the L11 start codon suggests that nusG and the genes for the ribosomal proteins are transcribed as a single unit.

Use of T7 RNA polymerase in an optimized Escherichia coli coupled in vitro transcription-translation system. Application in regulatory studies and expression of long transcription units

An Escherichia coli coupled in vitro transcription-translation system has been modified to allow efficient expression of genes under the control of a T7 promoter. We describe both the characterization and use of two S30 crude extracts prepared from E. coli, namely S30 BL21(DE3) (containing endogenous T7 RNA polymerase) and S30 BL21 (supplemented with exogenous T7 RNA polymerase). Since transcription by the highly active T7 RNA polymerase is known to overload the translational machinery of E. coli, the ratio between mRNA and ribosomes has to be regulated in the coupled in vitro system. For this purpose, the level of mRNA is controlled by varying the amount of DNA template (S30 extract with endogenous T7 RNA polymerase) or by limited amounts of exogenously added T7 RNA polymerase. The coupled in vitro system described in this paper provides two especially useful applications. First, it is most suitable for studying the regulation of gene expression in vitro, second, it can be used to express DNA templates carrying up to 10 genes. We show that genes which are not well expressed in E. coli in vivo because of unfavourable codon usage or plasmid instability are synthesized efficiently in the coupled in vitro system.

TTG serves as an initiation codon for the ribosomal protein MvaS7 from the archaeon Methanococcus vannielii

The ribosomal protein MvaS7 from the methanogenic archaeon Methanococcus vannielii is a protein of 188 amino acids, i.e., it is 42 amino acids longer than previously suggested. The triplet TTG serves as a start codon. The methanogenic translation initiation region that includes the rare TTG start codon is recognized in Escherichia coli.

TTG serves as an initiation codon for the ribosomal protein MvaS7 from the archaeon Methanococcus vannielii

The ribosomal protein MvaS7 from the methanogenic archaeon Methanococcus vannielii is a protein of 188 amino acids, i.e., it is 42 amino acids longer than previously suggested. The triplet TTG serves as a start codon. The methanogenic translation initiation region that includes the rare TTG start codon is recognized in Escherichia coli.

Pteridine biosynthesis and nitric oxide synthase in Physarum polycephalum

Physarum polycephalum, an acellular slime mould, serves as a model system to study cell-cycle-dependent events since nuclear division is naturally synchronous. This organism was shown to release isoxanthopterin which is structurally related to tetrahydrobiopterin, a cofactor of aromatic amino acid hydroxylases and of nitric oxide synthases (NOSs) (EC 1.14.13.39). Here, we studied Physarum pteridine biosynthesis in more detail and found that high amounts of tetrahydrobiopterin are produced and NOS activity is expressed. Physarum pteridine biosynthesis is peculiar in as much as 7,8-dihydroneopterin aldolase (EC 4.1.2.25), an enzyme of folic acid biosynthesis usually not found in organisms producing tetrahydrobiopterin, is detected in parallel. NOS purified from Physarum depends on NADPH, tetrahydrobiopterin and flavins. Enzyme activity is independent of exogenous Ca2+ and is inhibited by arginine analogues. The purified enzyme (with a molecular mass of 130 kDa) contains tightly bound tetrahydrobiopterin and flavins. During the synchronous cell cycle of Physarum, pteridine biosynthesis increases during S-phase whereas NOS activity peaks during mitosis, drops at telophase and peaks again during early S-phase. Our results characterize Physarum pteridine biosynthesis and NOS and suggest a possible link between NOS activity and mitosis.

Autogenous translational regulation of the ribosomal MvaL1 operon in the archaebacterium Methanococcus vannielii

The mechanisms for regulation of ribosomal gene expression have been characterized in eukaryotes and eubacteria, but not yet in archaebacteria. We have studied the regulation of the synthesis of ribosomal proteins MvaL1, MvaL10, and MvaL12, encoded by the MvaL1 operon of Methanococcus vannielii, a methanogenic archaebacterium. MvaL1, the homolog of the regulatory protein L1 encoded by the L11 operon of Escherichia coli, was shown to be an autoregulator of the MvaL1 operon. As in E. coli, regulation takes place at the level of translation. The target site for repression by MvaL1 was localized by site-directed mutagenesis to a region within the coding sequence of the MvaL1 gene commencing about 30 bases downstream of the ATG initiation codon. The MvaL1 binding site on the mRNA exhibits similarity in both primary sequence and secondary structure to the L1 regulatory target site of E. coli and to the putative binding site for MvaL1 on the 23S rRNA. In contrast to other regulatory systems, the putative MvaL1 binding site is located in a sequence of the mRNA which is not in direct contact with the ribosome as part of the initiation complex. Furthermore, the untranslated leader sequence is not involved in the regulation. Therefore, we suggest that a novel mechanism of translational feedback regulation exists in M. vannielii.

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.

Histone acetylation in Zea mays. II. Biological significance of post-translational histone acetylation during embryo germination

Multiple forms of histone acetyltransferases and histone deacetylases, which have been separated and characterized in the accompanying manuscript (López-Rodas, G., Georgieva, E. I., Sendra, R., and Loidl, P. (1991) J. Biol. Chem. 266, 18745-18750), together with in vivo acetate incorporation, were studied during the germination of Zea mays embryos. Total histone acetyltransferase activity increases during germination with two maxima at 40 and 72 h after start of germination. This fluctuation is mainly due to the cytoplasmic B-enzyme which predominantly acetylates histone H4 up to the diacetylated form. The nuclear histone acetyltransferase A2, specific for H3, is low throughout germination, except at 24 h, when it transiently becomes the main activity. Both enzymes are also present in the dry embryo, whereas the second nuclear enzyme A1, specific for H3 and H4, is absent in the initial stage of differentiation. The two histone deacetylases, HD1 and HD2, exhibit entirely different patterns. Whereas HD1 activity is low in the dry embryo and increases during germination, HD2 is the predominant enzyme at the start of differentiation, but almost disappears at later stages. Analysis of the in vivo acetate incorporation reveals that H4 is present in up to tetraacetylated subspecies. The pattern of acetate incorporation into core histones closely resembles the fluctuations of histone acetyltransferase B. Based on the analysis of thymidine kinase activity a close correlation was established between histone acetyltransferase B and DNA replication, whereas the A2 enzyme is associated with transcriptional activity. Histone deacetylase HD1 obviously serves a specific function in the dry embryo and could be a prerequisite for DNA repair processes. The study confirms the idea of DNA repair processes. The study confirms the idea of multiple functions of histone acetylation and assigns distinct enzymes, involved in this modification, to certain nuclear processes.

ADP-ribosylation of core histones and their acetylated subspecies

ADP-ribosylation of core histones was investigated in isolated nuclei of Physarum polycephalum. Core histone species differed in the mode of modification. Whereas ADP-ribosylation of H2A and H2B is sensitive to inhibition by 3-methoxybenzamide, as with most other nuclear acceptor proteins, the modification of H3 and H4 is not inhibited. Cleavage experiments with hydroxylamine indicate a carboxylate ester type ADP-ribose-protein bond for H2A and H2B and arginine-linked ADP-ribose residues for H3 and H4. ADP-ribosylation preferentially occurs on acetylated histone subspecies, as shown for H4. These data are substantiated by the use of n-butyrate, which induces hyperacetylation of core histones; the butyrate-induced shift towards more acetylated H4 subspecies is accompanied by an increase of ADP-ribose incorporation into highly acetylated H4 subspecies.

ADP-ribosylation in isolated nuclei of Physarum polycephalum

ADP-ribosylation of histones and non-histone nuclear proteins was studied in isolated nuclei during the naturally synchronous cell cycle of Physarum polycephalum. Aside from ADP-ribosyltransferase (ADPRT) itself, histones and high mobility group-like proteins are the main acceptors for ADP-ribose. The majority of these ADP-ribose residues is NH2OH-labile. ADP-ribosylation of the nuclear proteins is periodic during the cell cycle with maximum incorporation in early to mid G2-phase. In activity gels two enzyme forms with Mr of 115,000 and 75,000 can be identified. Both enzyme forms are present at a constant ratio of 3:1 during the cell cycle. The higher molecular mass form cannot be converted in vitro to the low molecular mass form, excluding an artificial degradation during isolation of nuclei. The ADPRT forms were purified and separated by h.p.l.c. The low molecular mass form is inhibited by different ADPRT inhibitors to a stronger extent and is the main acceptor for auto-ADP-ribosylation. The high molecular mass form is only moderately auto-ADP-ribosylated.

Periodic fluctuations of nuclear high mobility group like proteins during the cell cycle of Physarum polycephalum

High mobility group like (HMG-like) nuclear proteins were isolated from plasmodia of the lower eucaryote Physarum polycephalum and characterized by different types of polyacrylamide gel electrophoresis. The synthesis of these proteins was measured during the naturally synchronous cell cycle of Physarum. The four HMG-like proteins (AS1-4) exhibit a pronounced cell cycle dependent pattern of synthesis: AS1 and AS4 have a clear maximum of synthesis in mid S phase with a basal synthesis during the entire G2 period. In contrast, AS2 and AS3 have little synthesis in S phase but a broad maximum in mid G2 period. The four HMG-like proteins have a very low synthesis in early S phase and late G2 period. In addition, other non-histone proteins, which are coextracted with the HMG proteins, exhibit distinct periodic synthesis patterns. A novel non-histone protein, which is the most abundant protein species in 0.35 M NaCl extracts, was detected. It exhibits a high rate of synthesis around the time of mitosis. In general, the results indicate that, in contrast to the main cytoplasmic proteins, most nuclear proteins are phase-specific with respect to their synthesis in the cell cycle.

Postsynthetic acetylation of histones during the cell cycle: a general function for the displacement of histones during chromatin rearrangements

Postsynthetic acetylation of core histones exhibits a peak during S-phase of the Physarum cell cycle. The maximum 3H-acetate incorporation precedes the maximum of histone synthesis. Acetate is incorporated into all core histones during S-phase, but only into H2A and H2B during G2-period. Resolution of acetylated H4-subspecies reveals acetate incorporation into preexisting H4, but not into newly synthesized molecules during mitosis and early S-phase. In a protamine competition assay histones from S-phase chromatin are released at lower protamine concentrations as compared to the lower acetylated G2-chromatin. We demonstrate a preferential release of highly acetylated H4-subspecies at low protamine concentrations. Our results fit into a general model of the relationship between histone acetylation and chromatin assembly. According to this model acetylation of core histones would serve as a signal for displacement of histones from nucleosomes by modulating histone-protein or histone-DNA interactions. We propose that this mechanism operates during DNA-replication and transcription, as well as during other chromatin rearrangements.

Histone acetyltransferase activity during the cell cycle

Histone acetyltransferase activity was measured in isolated nuclei during the synchronous cell cycle of the myxomycete Physarum polycephalum. Nuclei were incubated with [14C]acetyl-coenzyme A and an excess of exogenous calf thymus histones. The activity is periodic during the cell cycle; it rises during the S-phase to reach a maximum in the early G2-period with a decline in mid and late G2. Comparison of the pattern of enzyme activity with the in vivo acetylation of histones during the cell cycle reveals that the enzyme activity does not wholly determine the acetylation state, indicating that other factors, including possibly the structural state of chromatin, are responsible for the observed cell cycle pattern of in vivo histone acetylation.

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

The synthesis of histones and nonhistone nuclear proteins was studied during the naturally synchronous cell cycle of Physarum polycephalum. Contrary to the commonly accepted idea of a tight coupling of histone biosynthesis and DNA replication during the somatic cell cycle we found that 40% of total histone synthesis takes place in the G2 period in the complete absence of DNA synthesis. The core histones exhibit a maximum of synthesis during S-phase. The synthesis of histones H2A and H2B continues during the G2 period, but synthesis of H4 and H3 is restricted to the S-phase of the cell cycle. Experiments with hydroxyurea demonstrated that the synthesis of H4 and H3 is completely dependent on unperturbed DNA synthesis, whereas synthesis of H2A and H2B is independent from DNA synthesis during the entire cell cycle. This implicates significant differences between the arginine-rich histones H4 and H3 and the moderately lysine-rich histones H2A and H2B with respect to the control mechanisms of their synthesis, the metabolic stability, and the function for chromatin structure. The nonhistone nuclear proteins are synthesized throughout the cell cycle with a broad maximum in the early G2 period. The cell cycle pattern of synthesis of H1 rather resembles the pattern of the nonhistone proteins than of core histones.

Biosynthesis and posttranslational acetylation of histones during spherulation of Physarum polycephalum

Plasmodia of Physarum polycephalum can be induced to differentiate into dormant spherules: DNA-, RNA- and protein-synthesis cease during this process. Analysis of the histone H4 acetylation during spherulation revealed no significant changes of the relative acetate content and percentage of acetylated H4 subspecies. This result does not support a close correlation of histone acetylation and transcriptional activity. Posttranslational incorporation of 3H-acetate into core histones decreased rapidly after start of spherulation. However, acetate incorporation increased significantly at a late stage of spherulation (30 h). To elucidate the role of this elevated acetate incorporation we followed histone synthesis during spherulation. Histone synthesis decreased upon induction of differentiation and stopped after 12 h. After 38 h of spherulation histone synthesis again occurred in the absence of DNA synthesis. The peak of acetate incorporation into core histones clearly preceded this late histone synthesis, indicating acetylation of preexisting histones. We suggest, that this acetate incorporation is part of the mechanism, by which preexisting histones are replaced by newly synthesized histones. Pulse treatment with actinomycin D or cycloheximide during spherulation suggested, that the observed histone synthesis is essential for the germination of spherules. Obviously, new histones have to be synthesized for the coordinate course of the differentiation program.

ADP-ribosyltransferase in isolated nuclei during the cell cycle of Physarum polycephalum

ADP-ribosyltransferase was measured in isolated nuclei of Physarum polycephalum. Activity was determined with and without exogenous DNA and histones. During the synchronous cell cycle the activity measured with exogenous substrates exhibited a typical peak enzyme pattern with a maximum of activity in S-phase, whereas activity measured without exogenous substrates displayed a step enzyme pattern. Both activities doubled in each cell cycle.

An immunological approach to enrich a mitotic stimulator and to reveal G2-phase-specific proteins in Physarum polycephalum

Purified antibodies from an antiserum against S-phase proteins of the myxomycete Physarum polycephalum were attached to protein-A-Sepharose CL-4B. A late G2-phase extract that contained a mitosis-stimulating protein was applied to this immunoadsorbent, and the mitosis-stimulating protein was enriched by a factor of ten. This protein, which is present in the cell in low amounts, is synthesized in late G2 phase and obviously degraded in a later stage of the cycle. Immunoadsorption of a G2-phase extract with anti-S-antibodies decreased the 700 main proteins to 20 as demonstrated by two-dimensional gel electrophoresis. No difference in protein pattern could be observed on two-dimensional gels between S-phase and G2-phase extracts before and after immunoadsorption with anti-S-antibodies. This indicates that there are no G2-phase-specific proteins among the 700 most abundant proteins of Physarum polycephalum.

RNA polymerase activity and template activity of chromatin after butyrate induced hyperacetylation of histones in Physarum

We have studied the effect of sodium-n-butyrate on endogenous RNA polymerase in Physarum polycephalum. 1 mM butyrate strongly reduces RNA polymerase activity measured in isolated nuclei or chromatin; both RNA polymerase A as well as the alpha-amanitin sensitive RNA polymerase B are equally affected. Despite a concomitant hyperacetylation of histone H4 the template activity of chromatin, as analyzed by in vitro transcription of the chromatin with exogenous RNA polymerase from E. coli or RNA polymerase II from wheat germ, remains unaltered as compared to untreated control chromatin, indicating that there is no positive correlation between histone acetylation and template activity of chromatin for transcription in this organism. The results further indicate, that butyrate acts primarily as a quick but reversible inhibitor of protein synthesis in Physarum; the fast decrease of endogenous RNA polymerase activity after butyrate treatment is due to inhibition of enzyme synthesis rather than inactivation of other factors necessary for transcription.

Thymidine kinase. A novel affinity chromatography of the enzyme and its regulation by phosphorylation in Physarum polycephalum

dThd bound to epoxy-activated Sepharose results in a high specific affinity adsorbent, which was used to purify Physarum dThd kinase 8000-fold. With this purified enzyme, it was proved that dThd kinase exists in five enzyme variants in Physarum polycephalum, the acidic forms being phosphorylated. This protein modification is discussed under the aspect of the regulation of this enzyme.

Lack of correlation between histone H4 acetylation and transcription during the Physarum cell cycle

The interaction between nucleosomal proteins and DNA is expected to change during DNA replication as well as during transcription. A possible way of achieving the necessary structural changes is the modification of histones and high mobility group (HMG) proteins. The acetylation of core histones has been studied in various systems (for a review see ref. 1) and a correlation between histone acetylation and transcriptional activity of chromatin has frequently been proposed. In particular, Bradbury and co-workers have reported a cell cycle dependence of histone H4 acetylation in Physarum polycephalum which revealed two correlations: (1) tetraacetylated H4 (H4Ac4) correlated with the rate of transcription and (2) H4 acetylation was inversely correlated with H1 phosphorylation in mitosis. We present evidence here that H4 acetylation does not fit these correlations. Our data clearly show that the acetate content of H4 is high during the S phase, but low during later stages of the cell cycle. H4Ac4 remains at a nearly constant level during the whole cycle, with an elevation during the S phase. Furthermore, experiments with the deacetylase inhibitor sodium-n-butyrate do not support the proposed connection between diacetylated H4 (H4Ac2) and DNA replication. Our data imply that a correlation of H4 acetylation and transcription is unlikely during the cell cycle of Physarum. The conclusions of Bradbury and co-workers are therefore invalid.

Response of the dTMP-synthesizing enzymes to differentiation processes in Physarum polycephalum

Synthesis of deoxythymidylate (dTMP) is a rate-limiting step in DNA synthesis; there are two main enzymes which are responsible for dTMP production, thymidylate synthetase (ts) and thymidine kinase (tk). Both enzymes were studied during several differentiation processes of the myxomycete Physarum polycephalum. In all stages of proliferation (microplasmodia, macroplasmodia, germinating microsclerotia and germinating spores) tk is the dominant enzyme in terms of activity, whereas ts is the predominant enzyme in quiescent stages (microsclerotia, sporangia, respectively spores); this is expressed by calculating the tk/ts ratio. This ratio is greater than 1 during proliferation and much less than 1 during quiescence. Our results clearly show that ts is the basic enzyme for dTMP production during all differentiation stages, whereas tk, if required, is shut on and represents an additional potential for dTMP synthesis during rapid proliferation.

Cell-cycle-dependent effects of sodium-n-butyrate in Physarum polycephalum

Sodium-n-butyrate affects the length of the mitotic cycle of Physarum polycephalum. Application during S- or early G2-period results in a delay of the subsequent mitosis, whereas application later in the cycle has no delaying effect. Interestingly, the second mitotic cycle after application is considerably shortened when butyrate has been administered during S- or early G2-period of the preceding cycle. In comparison, other homologous short-chain fatty acids were tested; the retarding effect on mitosis increases with the number of carbon atoms, although only butyrate can shorten the second mitotic cycle. It is shown that butyrate causes an immediate depression of synthesis of DNA, RNA and protein. After a certain time-interval the plasmodium overcomes the butyrate block. DNA synthesis is fully recovered and the inhibition of RNA and protein synthesis is even overcompensated until the next mitosis, as reflected by elevated levels of RNA and protein.

Thymidylate synthetase during synchronous nuclear division cycle and differentiation of Physarum polycephalum

Thymidylate synthetase and thymidine kinase activities in wild type strain M3b and in thymidine kinase-deficient mutant TU63 of Physarum polycephalum are studied. Whenever nuclear division occurs in macroplasmodia of wild type, thymidine kinase and thymidylate synthetase activities sharply increase, although the increase of thymidylate synthetase activity is less pronounced than thymidine kinase activity. This is also true for other investigated nuclear divisions during the life cycle of P. polycephalum. It is shown for the first time that thymidylate synthetase is a periodically fluctuating enzyme during the naturally synchronous nuclear division cycle of P. polycephalum with a peak of specific activity in the S phase. In macroplasmodia, as well as after germination of microsclerotia of M3b, thymidine kinase is the dominant enzyme, whereas at the time of the precleavage mitosis in sporulating macroplasmodia thymidylate synthetase is the predominant enzyme. This study describes and compares both dTMP-synthesizing enzymes during proliferation and differentiation of the same organism.

Thymidine kinase enzyme variants in Physarum polycephalum. In vitro interconversion of the enzyme variants

Isoelectric focusing of plasmodial extracts of Physarum polycephalum demonstrated the presence of several multiple enzyme variants of thymidine kinase, which appear sequentially during the nuclear division cycle. Variants (A) + (A1) are the only enzyme variants found in the late G2-phase, whereas the variants (C) + (C1) are only present at the time of mitosis and S-phase (1, 2). Evidence is presented that multiple forms of thymidine kinase (A) + (A1) with high pI arise by dephosphorylation of a primary translation product with low pI (C and/or C1). The thymidine kinase fractions (A) + (A1) and (C) + (C1) + (c1) were separated and partially purified by DEAE-cellulose chromatography. The enzyme variants (C) + (C1) are converted in vitro by an endogenous enzymatic factor as well as by bacterial alkaline phosphatase into the variants (A) + (A1).

Thymidine kinase enzyme variants in Physarum polycephalum. Kinetics and properties of the enzyme variants

Thymidine kinase variants of Physarum polycephalum separated by repeated DEAE-cellulose chromatography have been characterized. The enzyme variants show similar catalytic properties (e.g., substrate specificity, pH optimum) and molecular weights, as judges by their sedimentation in sucrose gradients. However, they differ significantly with respect to pI, inhibition by dTTP and thermostability, and they have slightly different Km values for deoxythymidine as a substrate.