Further studies on basic nucleoproteins from the cellular slime mold Dictyostelium discoideum

Origin of H1 linker histones

In which taxa did H1 linker histones appear in the course of evolution? Detailed comparative analysis of the histone H1 and histone H1-related sequences available to date suggests that the origin of histone H1 can be traced to bacteria. The data also reveal that the sequence corresponding to the 'winged helix' motif of the globular structural domain, a domain characteristic of all metazoan histone H1 molecules, is evolutionarily conserved and appears separately in several divergent lines of protists. Some protists, however, appear to have only a lysine-rich basic protein, which has compositional similarity to some of the histone H1-like proteins from eubacteria and to the carboxy-terminal domain of the H1 linker histones from animals and plants. No lysine-rich basic proteins have been described in archaebacteria. The data presented in this review provide the surprising conclusion that whereas DNA-condensing H1-related histones may have arisen early in evolution in eubacteria, the appearance of the sequence motif corresponding to the globular domain of metazoan H1s occurred much later in the protists, after and independently of the appearance of the chromosomal core histones in archaebacteria.

The lysine-rich H1 histones from the slime moulds, Physarum polycephalum and Dictyostelium discoideum lack phosphorylation sites recognised by cyclic AMP-dependent protein kinase in vitro

Calcium chloride-extracted histones were prepared from nuclei of the slime moulds, Physarum polycephalum and Dictyostelium discoideum, and phosphorylation by purified preparations of cyclic AMP-dependent protein kinase (cAMP-d PK) and growth-associated H1 histone kinase (HKG) examined and compared. Among the major histone fractions and other proteins in the two preparations, the H1 histones from both organisms were found to be effective and exclusive substrates for HKG. cAMP-d PK, which phosphorylates mammalian H1 histone and certain, in particular H2B, of the mammalian core histones, phosphorylated several of the core histones from both slime moulds but did not phosphorylate H1 histone from either. The slime mould H1s remained ineffective substrates for cAMP-d PK even after extensive alkaline phosphatase treatment of the histone preparations. Additional studies demonstrated that the lack of slime mould H1 phosphorylation by cAMP-d PK was not due to competition of the H1 molecules with the core histones for the kinase. Our studies suggest that H1 histones from these organisms, whilst clearly containing sites for phosphorylation by HKG, apparently lack phosphorylation sites recognised by cAMP-d PK. Thus, the mediation of specific nuclear functions by cAMP-dependent phosphorylation of H1 in higher organisms may not occur or be required in these lower eukaryotes.

Characterization and nucleosomal core localization of Achlya histones involved in stress-induced chromatin condensation

To better understand the basis for heat shock-induced chromatin condensation in Achlya, a further characterization of the histones of this organism was carried out. The nucleosomal location (i.e., core vs linker), partial peptide map, and electrophoretic behavior of each Achlya histone was determined and compared to the well-characterized histones of rabbit kidney. The results of this and previous studies suggest that in Achlya, no nucleosome linker-associated histone analogous to histone H1 of higher eucaryotes is observed and that the Achlya histone designated alpha is a novel nucleosomal core histone. These observations may reflect the existence of a mechanism of stress-induced chromatin condensation which does not involve histone H1.

Transition of starving Dictyostelium cells to differentiation phase at a particular position of the cell cycle

The relationship between proliferation and differentiation in Dictyostelium discoideum Ax-2 was analyzed with reference to the cell-cycle position at the onset of starvation, using cells synchronized by temperature shift (11.5 degrees C-22.0 degrees C). To examine how far Ax-2 cells at any particular phase of the cell cycle are able to progress through the cycle in response to nutritional deprivation, we measured temporal changes in cell number and nuclearity after starvation. Nuclear DNA synthesis in synchronously developing cells was also monitored by pulse-labeling with [methyl-3H]thymidine. Increase in cell number and subsequent DNA synthesis occurred in cells just before mitosis (referred to as T0.5 cells and T1 cells; 0.5 h and 1 h after the shift-up from 11.5 degrees C to 22.0 degrees C respectively), but not in T3, T5, or T7 cells. When T1 cells were incubated for 6 h in the absence of external nutrients, they (T1 + 6 cells) exhibited developmental features similar to T7 cells, which most rapidly acquired chemotactic sensitivity to 3',5'-cyclic adenosine monophosphate (cAMP) and EDTA-resistant cohesiveness after starvation. Thus, it is quite likely that Ax-2 cells may progress through the cell cycle to a particular point (possibly the cell-cycle position of T7 cells), irrespective of the presence or absence of nutrients, and enter the differentiation phase from this point under conditions of nutritional deprivation. There was no difference in the ratio of prestalk to prespore cells in migratory pseudoplasmodia derived from cells that had been starved at other cell-cycle positions.(ABSTRACT TRUNCATED AT 250 WORDS)

The effects of transcription on the nucleosome structure of four Dictyostelium genes

Micrococcal nuclease digestion of Dictyostelium discoideum nuclei from various developmental stages was used to investigate transcription-related changes in the chromatin structure of the coding region of four genes. Gene activity was determined by Northern blotting and nuclear run on experiments. During strong transcription of the developmentally regulated cysteine proteinase I gene, a smear superimposed on a nucleosomal ladder was observed, indicating perturbation of nucleosomal structure was occurring. However, two other developmentally regulated genes, discoidin I and pSC253, showed only slight nucleosome disruption during high levels of transcription. The chromatin structure of a fourth gene (pCZ22) was disrupted throughout development, even at those stages where transcription was greatly reduced. We suggest that although nucleosome structure can be transiently perturbed by the passage of the transcription complex in vivo, the degree of perturbation and the speed with which nucleosomes reassemble is also influenced by the DNA sequence.

Methidiumpropyl-EDTA-iron(II) cleavage of ribosomal DNA chromatin from Dictyostelium discoideum

We have used methidiumpropyl-EDTA-iron(II) [MPE.Fe(II)] in parallel with micrococcal nuclease to investigate the chromatin structure of the extrachromosomal palindrome ribosomal RNA genes of Dictyostelium. Confirming our earlier results with micrococcal nuclease (1,2), MPE.Fe(II) digested the coding region of rapidly transcribing rRNA genes as a smear, indicating the absence or severe disruption of nucleosomes, whereas in slowly transcribing rRNA genes, a nucleosomal ladder was produced. In the central non-transcribed spacer region of the palindrome, MPE.Fe(II) digestion resulted in a normal nucleosomal repeat, whereas micrococcal nuclease gave a complex banding pattern. The difference is attributed to the lower sequence specificity of MPE.Fe(II) compared to micrococcal nuclease. In the terminal region of the palindrome, however, both substances gave a complex chromatin digestion pattern. In this region the DNA appears to be packaged in structures strongly positioned with respect to the underlying DNA sequence.

A lysine-rich protein functions as an H1 histone in Dictyostelium discoideum chromatin

Mononucleosomes released from Dictyostelium discoideum chromatin by micrococcal nuclease contained two distinctive DNA sizes (166-180 and 146 bp). Two dimensional gel electrophoresis suggested a lysine-rich protein protected the larger mononucleosomes from nuclease digestion. This was confirmed by stripping the protein from chromatin with Dowex resin. Subsequently, only the 146 bp mononucleosome was produced by nuclease digestion. Reconstitution of the stripped chromatin with the purified lysine-rich protein resulted in the reappearance of the larger mononucleosomes. Two-dimensional gel electrophoresis showed the protein was associated with mononucleosomes. Hence, the protein functions as an H1 histone in bringing the two DNA strands together at their exit point from the nucleosome. Trypsin digestion of the lysine-rich protein in nuclei resulted in a limiting peptide of approx. 10 kilodaltons. Trypsin concentrations which degraded the protein to peptides of 12-14 kilodaltons and partially degraded the core histones did not change the DNA digestion patterns obtained with micrococcal nuclease. Thus, the trypsin-resistant domain of the lysine-rich protein is able to maintain chromatosome structure.

Chromatin structure along the ribosomal DNA of Dictyostelium. Regional differences and changes accompanying cell differentiation

The ribosomal genes of Dictyostelium discoideum are extrachromosomal palindromic DNA molecules situated in the nucleolus. Each molecule comprises ribosomal RNA coding regions and non-transcribed spacer regions. We used both biochemical and electron microscopic approaches to investigate the structure of transcribing and non-transcribing chromatin. Nucleoli from exponentially growing cells were digested with micrococcal nuclease, and the resulting DNA fragments were separated by gel electrophoresis and transferred to DBM paper. They were hybridized with cloned EcoRI fragments derived from different parts of the ribosomal gene. Probes of the coding region showed a smear, while probes of the non-transcribed regions gave pronounced banding patterns more complex than typical nucleosome repeats, but not due solely to sequence-specific cutting by micrococcal nuclease. The DNA of the coding region was digested more quickly than that of the non-transcribed ones. When nucleoli were digested with restriction enzymes, sites within the coding region were accessible and sites in the non-transcribed region were protected. The structure of ribosomal chromatin in differentiating cells, in which the rate of ribosomal RNA synthesis is reduced, was examined using essentially the same methods. The coding region, probed by hybridization to micrococcal digests, then showed a typical DNA repeat pattern indicating that this region had become condensed into nucleosomes, and its accessibility to restriction enzymes was very much reduced. On electron micrographs of lysed nucleoli from exponentially growing cells, two types of chromatin were observed, one with a beaded nucleosomal appearance, the other with putative RNA polymerase molecules attached to fibres indistinguishable from free DNA adsorbed to the same grid. The combined results suggest that whereas regions that are not transcribed are packaged with proteins that protect them from nuclease digestion, actively transcribing ribosomal genes are associated with few macromolecular constituents apart from those required for transcription and its regulation.

Electrophoretic study of histones in the unicellular alga Olisthodiscus luteus

Basic proteins were prepared from isolated nuclei of the unicellular alga Olisthodiscus luteus. The ratio of DNA/RNA/basic protein for these nuclei was 1:0.17:1.1, respectively, and the amino acid composition of the basic protein was very similar to that of Euglena and calf histones. The Olisthodiscus basic proteins were separated into four major components by polyacrylamide gel electrophoresis in four gel systems: (1) low pH disc gels containing 2.5 M urea; (2) two-dimensional low pH-urea gels in which the second dimension contained 1% Triton X-100; (3) slab gels containing 0.1% sodium dodecyl sulfate (SDS); (4) two-dimensional gels combining systems (1) and (3). The presence of four rather than five major histone fractions was shown to be not merely the result of proteolytic degradation. Results from the urea-containing gels suggest that an H1-like histone is missing, while electrophoresis in the SDS-containing gels shows the presence of a component resembling H1. In view of recent reports documenting the presence of five major histones in lower eukaryotes as well as in higher organisms, the presence of only four histones in Olisthodiscus suggests that this primitive eukaryote is unusual in its histone complement.

Basic nuclear proteins in the aquatic fungus Achlya ambisexualis

The complement of basic chromosomal proteins in the aquatic fungus Achlya ambisexualis has been characterized. Achlya nuclei contain proteins with electrophoretic mobilities on acetic acid/urea and dodecyl sulphate polyacrylamide gels which are comparable to rabbit kidney histones H3, H4 and H2A. In contrast, the behavior of putative H2B and H1 proteins from Achlya showed greater analogy on acid/urea gels to higher plant histones. A closely related water fungus Saprolegnia ferax contained basic nuclear proteins which were very similar to those of Achlya.

Yeast chromatin: search for histone H1

Yeast chromatin, isolated by a rapid procedure contains in addition to histones H2A, H2B, H3 and H4 a fifth major basic protein. This fifth polypeptide is not an intrinsic component of the nucleosome structure. It has properties of both histone and nonhistone proteins and might represent an early form of histone H1 and of high mobility group nonhistone proteins of higher eukaryotes. Electron microscopic visualization of isolated yeast nucleosomes substaniates further the similarity of the chromatin structudre of this unicellular eukaryote to that of higher eukaryotes.