Histones in protistan evolution

Slaying the last unicorn: discovery of histones in the microalga Nanochlorum eucaryotum

Histones are the principal constituents of eukaryotic chromatin. The four core histones (H2A, H2B, H3 and H4) are conserved across sequenced eukaryotic genomes and therefore thought to be universal to eukaryotes. In the early 1980s, however, a series of biochemical investigations failed to find evidence for histones or nucleosomal structures in the microscopic green alga Nanochlorum eucaryotum. If true, derived histone loss in this lineage would constitute an exceptional case that might help us further understand the principles governing eukaryotic gene regulation. To substantiate these earlier reports of histone loss in N. eucaryotum, we sequenced, assembled and quantified its transcriptome. Following a systematic search for histone-fold domains in the assembled transcriptome, we detect orthologues to all four core histones. We also find histone mRNAs to be highly expressed, comparable to the situation in other eukaryotes. Finally, we obtain characteristic protection patterns when N. eucaryotum chromatin is subjected to micrococcal nuclease digestion, indicating widespread formation of nucleosomal complexes in vivo. We conclude that previous reports of missing histones in N. eucaryotum were mistaken. By all indications, Nanochlorum eucaryotum has histone-based chromatin characteristic of most eukaryotes.

Cold-induced cysts of the photosynthetic dinoflagellate Lingulodinium polyedrum have an arrested circadian bioluminescence rhythm and lower levels of protein phosphorylation

Dinoflagellates are microscopic, eukaryotic, and primarily marine plankton. Temporary cyst formation is a well-known physiological response of dinoflagellate cells to environmental stresses. However, the molecular underpinnings of cold-induced cyst physiology have never been described. Cultures of the photosynthetic dinoflagellate Lingulodinium polyedrum readily form temporary cysts when placed at low (8°C±1°C) temperature and excyst to form normal motile cells following a return to normal temperature (18°C±1°C). The normal circadian bioluminescence rhythm and the expected changes in Luciferin Binding Protein abundance were arrested in L. polyedrum cysts. Furthermore, after excystment, the bioluminescence rhythm initiates at a time corresponding to zeitgeber 12, independent of the time when the cells encysted. Phosphoprotein staining after two-dimensional polyacrylamide gel electrophoresis, as well as column-based phosphoprotein enrichment followed by liquid chromatography tandem mass spectrometry, showed cyst proteins are hypophosphorylated when compared with those from motile cells, with the most marked decreases found for predicted Casein Kinase2 target sites. In contrast to the phosphoproteome, the cyst proteome is not markedly different from motile cells, as assessed by two-dimensional polyacrylamide gel electrophoresis. In addition to changes in the phosphoproteome, RNA sequencing revealed that cysts show a significant decrease in the levels of 132 RNAs. Of the 42 RNAs that were identified by sequence analysis, 21 correspond to plastid-encoded gene products and 11 to nuclear-encoded cell wall/plasma membrane components. Our data are consistent with a model in which the highly reduced metabolism in cysts is achieved primarily by alterations in the phosphoproteome. The stalling of the circadian rhythm suggests temporary cysts may provide an interesting model to address the circadian system of dinoflagellates.

Chromatin and histones from Giardia lamblia: a new puzzle in primitive eukaryotes

The three deepest eukaryote lineages in small subunit ribosomal RNA phylogenies are the amitochondriate Microsporidia, Metamonada, and Parabasalia. They are followed by either the Euglenozoa (e.g., Euglena and Trypanosoma) or the Percolozoa as the first mitochondria-containing eukaryotes. Considering the great divergence of histone proteins in protozoa we have extended our studies of histones from Trypanosomes (Trypanosoma cruzi, Crithidia fasciculata and Leishmania mexicana) to the Metamonada Giardia lamblia, since Giardia is thought to be one of the most primitive eukaryotes. In the present work, the structure of G. lamblia chromatin and the histone content of the soluble chromatin were investigated and compared with that of higher eukaryotes, represented by calf thymus. The chromatin is present as nucleosome filaments which resemble the calf thymus array in that they show a more regular arrangement than those described for Trypanosoma. SDS-polyacrylamide gel electrophoresis and protein characterization revealed that the four core histones described in Giardia are in the same range of divergence with the histones from other lower eukaryotes. In addition, G. lamblia presented an H1 histone with electrophoretic mobility resembling the H1 of higher eukaryotes, in spite of the fact that H1 has a different molecular mass in calf thymus. Giardia also presents a basic protein which was identified as an HU-like DNA-binding protein usually present in eubacteria, indicating a chimaeric composition for the DNA-binding protein set in this species. Finally, the phylogenetic analysis of selected core histone protein sequences place Giardia divergence before Trypanosoma, despite the fact that Trypanosoma branch shows an acceleration in the evolutionary rate pointing to an unusual evolutionary behavior in this lineage.

Role of nuclear WW domains and proline-rich proteins in dinoflagellate transcription

Dinoflagellates are unique among eukaryotes in their lack of histones and nucleosomes, and permanently condensed chromosomes. These unusual features raise questions as how chromatin condensation and gene expression are achieved. In this study, we investigated nuclear proteins potentially implicated in the regulation of the transcription. Dinap1 is a dinoflagellate nuclear protein that has a WW domain and is synthesized mainly in G1 and S phases of the cell cycle. In this study, we found that Dip1, a proline-rich potential ligand of Dinap1, and DapC, a Dip1 potential ligand, were both present in the nucleus of Crypthecodinium cohnii during the G1 phase. Dip1 contained a PPXY motif, and its domain organization was similar to that of the splicing factor FBP21 in that it possessed one zinc finger and two WW domains. Although DapC has no known homolog, 22 repeats of a PPXPXGX heptapeptide were identified at the N-terminus, and this structure is similar to that of the C-terminal part of the mouse splicing factor SAP62. Dinap1 was co-precipitated with Dip1 and DapC in vitro and in vivo, but despite their nuclear location, these three proteins did not bind directly to DNA. Dinap1 activated up to 40% of the basal transcription activity of C. cohnii in an in vitro assay, whereas DapC inhibited it by 40% and Dip1 had no effect. These dinoflagellate proteins appear to be the subunits of a nuclear complex that may be involved in regulating transcription.

Characterization of p80, a novel nuclear and cytoplasmic protein in dinoflagellates

The presence of myosin in dinoflagellates was tested using an anti-Acanthamoeba castellanii myosin II polyclonal antibody on the heterotrophic dinoflagellate Crypthecodinium cohnii Seligo. Western blots revealed the presence of a unique band of 80 kDa in total protein extracts and after immunoprecipitation. Expression of this 80 kDa protein appeared constant during the different phases of the cell cycle. In protein extracts from various other dinoflagellates, this 80 kDa protein was detected only in the autotrophic species Prorocentrum micans Ehr. Screening of a C. cohnii cDNA expression library with this antibody revealed a cDNA coding for an amino acid sequence without homology in the databases. However, particular regions were detected: - a polyglutamine repeat domain in the N-terminal part of the protein, - four peptide sequences associated with GTP-binding sites, - a sequence with slight homology to the rod tail of Caenorhabditis elegans myosin II, -a sequence with homology to a human kinesin motor domain. Immunocytolocalization performed on C. cohnii thin sections with a polyclonal antibody raised against the recombinant protein showed p80 to be present both within the nucleus and in the cytoplasm. Labelling was widespread in the nucleoplasm and more concentrated at the periphery of the permanently condensed chromosomes. In the cytoplasm, labelling appeared in a punctate region close to the nucleus and in the flagellum. Potential functions of this novel protein are discussed.

Presence of an unusually high concentration of an ubiquitinated histone-like protein in Trypanosoma cruzi

The conjugation of ubiquitin to histones H2A and H2B has been established in higher eukaryotes and has been related to changes in chromatin organization. In Trypanosoma cruzi, no condensation of chromatin occurs during mitosis. In order to determine the presence of histone ubiquitination in T. cruzi epimastigotes, histones were extracted from chromatin and analyzed by three electrophoretic systems: acid-urea, triton-acid-urea and sodium-dodecyl-sulphate polyacrylamide gel. The immunochemical detection of ubiquitin-histone conjugates by Western blotting showed a strong reaction with a slow migrating band of M(r) 19 kDa. The high percentage of ubiquitin-histone conjugates present in T. cruzi chromatin may be related to the inability of this parasite to condense chromatin into a 30 nm fiber.

The chromatin of trypanosomes

The nuclear chromatin of trypanosomes is organised in the form of nucleosome filaments. When soluble chromatin is prepared under suitable conditions, a regular array of nucleosomes can be shown by electron microscopy. Chromatin of blood stream as well as procyclic culture forms of Trypanosoma brucei brucei and of T. cruzi shows limited compaction at salt concentrations increasing from 1 to 100 mM. No 30 nm fibres, typical for higher eukaryotes, are formed. Digestion of the nuclear chromatin with micrococcal nuclease and analysis of the histone proteins with various techniques reveal that the basic organisation of the trypanosome chromatin is similar but not identical as compared to that of higher eukaryotes. Distinct differences are present with respect to biochemical properties of the histones as well as to their interaction with the DNA. The primary structure of the histones also differs significantly from that found in other lower and higher eukaryotes. The function of the recently described H1-like proteins in trypanosomes is currently being investigated. The differences that have already been found in the structure and compaction of the trypanosome chromatin compared to that of higher eukaryotes lead us to expect differences of gene expression which, in turn, might offer targets for the control of trypanosomiasis.

A gene family encoding heterogeneous histone H1 proteins in Trypanosoma cruzi

A gene family encoding a set of histone H1 proteins in Trypanosoma cruzi is described. The sequence of 3 genomic and 4 cDNA clones revealed the presence of several motifs characteristic of histone H1, although heterogeneity at the polypeptide level was evident. The clones encode histone H1 proteins of an unusually small size (74-97 amino acids), which lack the globular domain found in histone H1 of higher eukaryotes. All histone H1 mRNAs from T. cruzi are polyadenylated, although no typical polyadenylation signal was found. Furthermore, the genes encoding the histone H1 proteins in T. cruzi are found in a tandem array containing 15-20 gene copies per haploid genome. This tandem array is located on a large chromosome of 2.2 Mb.

Unambiguous identification of histone H1 in Trypanosoma cruzi

The existence of histone H1 has been questioned in Trypanosomatids. We report here the presence of a histone H1 in the chromatin of Trypanosoma cruzi. This protein was purified by narrow-bore reversed phase HPLC and its amino acid composition analyzed and compared with histones H1 from other species. Furthermore, the purified chromosomal protein was digested with proteases and the amino acid sequences of the resulting peptides were analyzed by the automated Edman degradation. The sequences obtained were found to present a high degree of homology when compared to the carboxy terminal domain of other known histones H1.

Extremely divergent histone H4 sequence from Trypanosoma cruzi: evolutionary implications

Trypanosoma cruzi presents six histones electrophoretically resolved in three gel systems. Indirect evidence shows that one of these histones, named e, corresponds to H4 in other species. We present evidence that histone e is H4 by sequencing its amino terminal end. The amino terminal of T. cruzi histone H4, unlike that of other H4s examined thus far is not blocked. Moreover, this protein presents two variants. This partial amino acid sequence of T. cruzi histone H4 differs greatly from homologous sequences of human, yeast, or Tetrahymena. Since the conservatism of the core histones (H2A, H2B, H3, and H4) is clearly illustrated by comparative sequence analyses, the data shown here demonstrates that T. cruzi histone H4 is the most divergent reported. Quantitative analysis of the data suggests that the rate of substitutions in the histone H4 amino terminal sequence varies among different lineages. We postulate a slow-down in the evolutionary rate of histone H4 amino terminal domain in the metazoa branch related perhaps to the appearance of a novel function for this domain.

Chromatin organization in Entamoeba histolytica

The chromatin structure of Entamoeba histolytica was investigated. It was found that this protozoan organizes its chromatin in nucleosome-like particles 10 nm in diameter, but digestion of the chromatin with micrococcal nuclease did not render a regularly spaced DNA ladder in agarose gels. Southern blot analysis of the products of Entamoeba chromatin digestion using total amebic DNA and a non-transcribed repetitive sequence produced a banding pattern characteristic of eukaryotic chromatin with a repetitive size of approximately 130 bp. Conversely, hybridization with two active gene probes, actin and ribosomal RNA, showed that these sequences are not part of the chromatin organized in nucleosomes. It was also found that the basic nuclear proteins differ from histones of higher eukaryotes in electrophoretic mobility. Screening of an E. histolytica HM1-IMSS genomic library with Saccharomyces cerevisiae H3 and H4 genes and attempts to amplify E. histolytica sequences, homologous to these yeast histone genes, gave negative results suggesting that the Entamoeba proteins involved in chromatin organization are not typical histones.

The histones of the insect trypanosomatid, Crithidia fasciculata

The histone-like proteins of the monogenetic parasite Crithidia fasciculata were extracted with 0.2 M sulfuric acid either from purified nuclei, or from purified chromatin, in both cases in the presence of 1 mM tosyl lysylchloromethylketone and 2 mM phenyl methyl sulfonyl fluoride as proteinase inhibitors. The presence of histones in the flagellate, nonidentical with those from calf thymus used as controls, was shown by their electrophoretic patterns in three different polyacrylamide gel systems; their staining with Alkaline fast green, specific for basic proteins; their global amino acid composition and absorption spectrum and their molecular weights. The protein showing the slower mobility in SDS gels and the fastest mobility in the urea-acetic acid-Triton gels, seems to be an H1 histone, because of its metachromatic staining with Coomassie brilliant blue, solubility characteristics, differential destaining properties and amino acid composition. Band 5 in Triton-urea-acetic acid gels is probably an HMG protein. We conclude that C. fasciculata has a complete set of histones and that the lack of chromosome condensation during mitosis is not due to lack of histone H1.

Analysis of Chlamydomonas reinhardtii histones and chromatin

Chromatin spreads made from isolated nuclei of the unicellular green alga Chlamydomonas reinhardtii show the beaded fibers typical of eukaryotic polynucleosomes. Micrococcal nuclease digestions confirmed the presence of nucleosomes with a repeat length of 189 base pairs, essentially the same as typical mammalian cells. Basic nuclear proteins extracted from isolated nuclei or chromatin with 1 M calcium chloride and 0.3 M hydrochloric acid are resolved into seven major components by electrophoresis in the presence of sodium dodecyl sulfate (SDS). These seven components were subjected to qualitative peptide mapping with V8 protease on SDS gels for comparison with the major histone components of calf thymus. Finally, the C. reinhardtii basic nuclear proteins were fractionated by reversed phase high performance liquid chromatography and their amino acid composition determined. From these studies, we conclude that C. reinhardtii has a full complement of the five histones with properties very similar to those of both higher animals and higher plants.

The histones of the endosymbiont alga of Peridinium balticum (Dinophyceae)

The histones of the endosymbiont nucleus of the binucleate dinoflagellate Peridinium balticum were characterized by amino acid analysis and peptide mapping, and compared to calf thymus histones. Using these and various other criteria we have identified two H1-like histones as well as the highly conserved histones H3 and H4. A 13,000 dalton component in sodium dodecyl sulphate (SDS) gels can be separated into two components in Triton-containing gels. We suggest that these histones (HPb1 and HPb2) correspond to the vertebrate histones H2A and H2B, respectively.

H 1 histone and histone variants in Trypanosoma cruzi

Trypanosoma cruzi chromatin is not condensed in chromosomes during mitosis. In previous studies a characteristic H 1 was not found in SDS or in acid-urea-PAGE. Consequently, it was proposed that the particular behavior of T. cruzi chromatin in dividing cells was due to the absence of an H 1 histone. In the present work, histones from this parasite were systematically characterized by spectrofluorometric analysis, amino acid composition, PAGE in one and in two dimensions, differential extraction with PCA and TCA, immunological cross-reactivity with antisera, and immunoblotting. We conclude that T. cruzi contains all five histones, H 1 presenting solubility and immunological properties similar to those in other species, but with a particular electrophoretic mobility in Triton-PAGE. Thus an explanation other than the absence of H 1 should be offered in order to understand the behavior of T. cruzi chromatin during mitosis. Moreover, histone variants were described by two-dimensional PAGE. The presence of histone variants suggests that they may participate in the regulation of cell proliferation and differentiation of this parasite, as it has been postulated for higher eukaryotes.

Molecular characterization of the histone gene family of Caenorhabditis elegans

The core histone genes (H2A, H2B, H3 and H4) of Caenorhabditis elegans are arranged in approximately 11 dispersed clusters and are not tandemly arrayed in the genome. Three well-characterized genomic clones, which contain histone genes, have one copy of each core histone gene per cluster. One of the clones (lambda Ceh-1) carries one histone cluster surrounded by several thousand base-pairs of non-histone DNA, and another clone (lambda Ceh-3) contains a histone cluster duplication surrounded by non-histone DNA. A third clone (lambda Ceh-2) carries a cluster of core histone genes flanked on one side (12,000 base-pairs away) by a single H2B gene and on the other by non-histone DNA. A fourth cluster (clone BE9) has one copy each of H3 and H4 and two copies each of H2A and H2B. This cluster is also flanked by non-histone DNA. Analysis of cosmid clones which overlap three of the clusters shows that no other histone clusters are closer than 8000 to 60,000 base-pairs, although unidentified non-histone transcription units are present on the flanking regions. Gene order within the histone clusters varies, and histone mRNAs are transcribed from both DNA strands. No H1 sequences are found on these core histone clones. Restriction fragment length polymorphisms between two related nematode strains (Bristol and Bergerac) were used as phenotypic markers in genetic crosses to map one histone cluster to linkage group V and another to linkage group IV. Hybridization of gene-specific probes from sea urchin to C. elegans RNA identifies C. elegans core histone messenger RNAs of sizes similar to sea urchin early stage histone mRNAs (H2A, H2B, H3 and H4). The organization of histone genes in C. elegans resembles the clustering found in most vertebrate organisms and does not resemble the tandem patterns of the early stage histone gene family of sea urchins or the major histone locus of Drosophila.