Basic chromosomal proteins in lower eukaryotes: relevance to the evolution and function of histones

The precarious prokaryotic chromosome

Evolutionary selection for optimal genome preservation, replication, and expression should yield similar chromosome organizations in any type of cells. And yet, the chromosome organization is surprisingly different between eukaryotes and prokaryotes. The nuclear versus cytoplasmic accommodation of genetic material accounts for the distinct eukaryotic and prokaryotic modes of genome evolution, but it falls short of explaining the differences in the chromosome organization. I propose that the two distinct ways to organize chromosomes are driven by the differences between the global-consecutive chromosome cycle of eukaryotes and the local-concurrent chromosome cycle of prokaryotes. Specifically, progressive chromosome segregation in prokaryotes demands a single duplicon per chromosome, while other "precarious" features of the prokaryotic chromosomes can be viewed as compensations for this severe restriction.

Epigenetic silencing of tumor suppressor genes in pancreatic cancer

INTRODUCTION

Without any alteration of DNA sequence, heritable changes in gene expression, caused by epigenetic pathways, are gaining a spotlight in research of diseases, and in particular, cancer. Although the dominant paradigm in cancer research, proposed by Vogelstein, suggested that cancer progression was caused by a sequential accumulation of genetic aberrations, basic science studies in epigenetics have now advanced our knowledge enough to apply its concepts and methodology to the study of cancer. In fact, chromatin dynamics and small RNAs are altered far more prevalently in cancer than genetic alterations and most important, can be reversible, lending themselves as attractive therapeutic targets.

CONCLUDING REMARKS

In the current review, the inactivation of p16 will be utilized as the most prominent example of epigenetic silencing of a tumor suppressor gene in pancreatic cancer. In addition, fundamental insight will be given into why and how epigenetics can be targeted for therapeutic purposes. This knowledge will help the reader in determining the breadth and depth of this field of study with potentially high impact to oncology.

Histone-like proteins of the dinoflagellate Crypthecodinium cohnii have homologies to bacterial DNA-binding proteins

The dinoflagellates have very large genomes encoded in permanently condensed and histoneless chromosomes. Sequence alignment identified significant similarity between the dinoflagellate chromosomal histone-like proteins of Crypthecodinium cohnii (HCCs) and the bacterial DNA-binding and the eukaryotic histone H1 proteins. Phylogenetic analysis also supports the origin of the HCCs from histone-like proteins of bacteria.

About the organisation of condensed and decondensed non-eukaryotic DNA and the concept of vegetative DNA (a critical review)

Experiments are reviewed that allow one to assign naturally occurring DNA-containing plasmas to either of two classes by virtue of their sensitivity to aggregation upon dehydration in organic solvents. The interphase nuclei of higher cells are relatively insensitive, while the DNA plasmas represented by bacterial nucleoids, vegetative bacteriophage and the chromosomes of dinoflagellates are sensitive. In higher cells the bulk of DNA is organised with histones in the form of nucleosomes. In prokaryotes and in the pool of vegetative phage DNA the most abundant histone-like protein HU is not associated with the bulk DNA, but localised in the border region with ribosomes where transcription and translation occur. These experimental results strongly suggest that the two classes of DNA plasmas are distinguishable by a low (1:10) or high (1:1) protein-to-DNA ratio. The hypothesis is formulated that the vegetative DNA (replicating and transcribing), throughout the living world, is nucleosome-free; during evolution, nucleosomes would have been introduced as a simple and adequate means for compacting the resting DNA. Condensation of DNA does not occur with prokaryotic nucleoids, but does take place when DNA is withdrawn from the vegetative phage pool to become packaged into phage heads. Dinoflagellate chromosomes are rather condensed although structurally different from eukaryotic chromosomes (e.g., those from Euglena) and are much more aggregation-sensitive.

Histones in protistan evolution

The potential of comparative studies on histones for use in protistan evolution is discussed, using algal histones as specific examples. A basic premise for the importance of histones in protistan evolution is the observation that these proteins are completely absent in prokaryotes (and cytoplasmic organelles), but with few exceptions, the same five major histone types are found in all higher plants and animals. Since the histone content of the algae and other protists is not constant, some of these organisms may represent transition forms between the prokaryotic and eukaryotic modes of packaging the genetic material. Comparative studies of protistan histones may thus be of help in determining evolutionary relationships. However, several problems are encounter with protistan histones, including difficulties in isolating nuclei, proteolytic degradation, anomalous gel migration of histones, and difficulties in histone identification. Because of the above problems, and the observed variability in protistan histones, it is suggested that several criteria be employed for histone identification in protists.

Histone-like protein and chromatin structure in the wall-less dinoflagellate Gymnodinium nelsoni

Basic nuclear proteins from the wall-less dinoflagellate Gymnodinium nelsoni were analyzed by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate (SDS). One major histone-like protein with a molecular weight of about 10 000 was present in acid extracts of whole nuclei and chromatin isolated from growing cultures. In addition, two minor components of 17 000 and 13 000 daltons were also noted. Chromatin fibers spread by the microcentrifugation technique showed no indication of a subunit structure, but instead appeared as smooth threads with diameter of about 6.5 nm.

Comparative aspects of basic chromatin proteins in dinoflagellates

Previous work on histone-like proteins in dinoflagellates is summarized, together with some new data to give an overview of basic proteins in these algae. The first two dinoflagellates studied were both found to contain one major acid-soluble protein that migrated to the same position in acidic-urea gels. When several other genera were studied however, it became apparent that the histone-like proteins from different dinoflagellates were similar but not identical. In view of the great diversity of living dinoflagellates it is speculated that further differences in dinoflagellate basic chromatin proteins will be revealed. Electrophoretic data from the eukaryotic (endosymbiont) nucleus of Peridinium balticum showed the presence of five major components. It is speculated that two of these proteins represent an H1-like doublet and two others correspond to the highly conserved histones H3 and H4. The fifth component is a new histone that may substitute for H2A and H2B in the nucleosome. Because histones and nucleosomes are present in all higher organisms but completely lacking in procaryotes, studies on basic proteins in dinoflagellates will provides insights into the evolution of histones and eucaryotic chromatin organization.

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.

Chromatin structure in the unicellular algae Olisthodiscus luteus, Crypthecodinium cohnii and Peridiniun balticum

Isolated nuclei of the unicellular alga Olisthodiscus luteus, the uninucleate dinoflagellate Crypthecodinium cohnii and the binucleate dinoflagellate Peridinium balticum were lysed and deposited on grids by the microcentrifugation technique. The ultrastructure of the released chromatin fibers was compared to that of mouse liver nuclei. Chromatin from nuclei of Olisthodiscus luteus and the "eukaryotic" nuclei of Peridinium balticum, appeared as linear arrays of regularly repeating subunits which were identical in size and morphology to mouse nucleosomes. In contrast, the chromatin fibers from Crypthecodinium cohnii nuclei appeared as smoothe threads with a diameter of about 6.5 nm. Nuclear preparations containing mixtures of "dinokaryotic" and "eukaryotic" nuclei of Peridinium balticum also contained smooth fibers which most likely originated from the dinokaryotic nuclei. These and other results demonstrating the presence of nucleosomes in lower eukaryotes suggest that the subunit structure of chromatin arose very early in the evolution of the eukaryotic cell.

Purification and the histones of Dictyostelium discoideum chromatin

Dictyostelium chromatin has been purified from nuclei in high yield by differential centrifugation and nuclease cleaving. Its chemical composition has been assayed, and its histones have been analyzed by gel electrophoresis, peptide fingerprints, amino acid composition, and ion-exchange chromatography. The mass ratios of DNA/RNA/histone/nonhistone are 1.0:0.18:0.98:1.02. There are four histones including one unusual histone, H7, which is the most abundant histone in the slime mold. The H4-like protein is the most conserved protein, while the other histones show both similarities and differences with mammalian histones.

High levels of transition metals in dinoflagellate chromosomes

X-ray microanalysis of fixed, sectioned chromosomes of the dinoflagellates Glenodinium foliaceum, Prorocentrum micans and Amphidinium carterae has revealed high levels of iron, nickel, copper and zinc. We report high levels of these transition metals in association with chromosomes in intact eukaryote cells.

Phylogenetic affinities between eukaryotic cells and a thermophilic mycoplasma

Thermoplasma acidophilum, a thermophilic mycoplasma, has several unusual features suggesting a possible relationship to eukaryotic cells. One feature is a histone-like protein that is associated with the DNA, condensing it into subunits similar to those in eukaryotic chromatin. A second feature is an association of cytoplasmic proteins that resembles eukaryotic actin and myosin. These two components are widely distributed in different groups of eukaryotic cells, but are typically lacking in prokaryotic cells. Furthermore, T. acidophilum lacks cytochromes and respires by enzymes that apparently are not coupled to oxidative phosphorylation. This primitive type of respiration resembles that of microbodies, another feature which is represented in the cytoplasm of all groups of eukaryotic cells. Furthermore, since T. acidophilum lacks a cell wall and appears to have a primitive correlate of endocytosis, it would appear to be mechanically capable of acquiring a symbiotic mitochondrion. Thus, our observations are consistent with the symbiotic hypothesis for the origin of eukaryotic cells. We suggest that an organism similar to T. acidophilum was the host cell for the original symbiosis, becoming the nucleus and cytoplasm of modern eukaryotic cells.

Histone occurrence in chromatin from Peridinium balticum, a binucleate dinoflagellate

Peridinium balticum is one of two dinoflagellates known to have dissimilar nuclei together in the same cell. One nucleus (dinokaryotic) has permanently condensed chromosomes, while the other (eukaryotic) does not have morphologically distinct chromosomes. Acid extracts of chromatin prepared from a mixture of dinokaryotic and eukaryotic nuclei and purified eukaryotic nuclei give four bands that co-migrate with four of the five histones from calf thymus when analyzed in urea-containing polyacrylamide gels.