Isolation and characterization of chromatin from Neurospora crassa

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.

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

The occurence of the basic chromosomal proteins in lower eukaryotes provides a useful approach to the study of histone evolution and function in higher eukaryotes. The histones of higher plants and animals are very similar and some are nearly identical, suggesting a high degree of evolutionary conservation within this group of proteins. However, a literature survey reveals that in the lower eukaryotes the histone situation is quite variable. The ciliates, and the true and cellular slime molds possess basic chromosomal proteins that are very similar to the histones of higher plants and animals. Various other lower eukaryotes possess basic chromosomal proteins that resemble at least some of the major histone fractions, and some microorganisms possess basic chromosomal proteins that bear little or no relationship to higher plant and animal histones. Since histones play a major role in the control of gene expression and the maintenance of chromosome structure in higher organisms, the evolution of these proteins represents a major change in the packaging of DNA and the mode of regulating gene expression in eukaryotes.

The similarities of ribosomal and basic chromosomal proteins from fungi

We have compared the physical and chemical properties of yeast and fungal ribosomal proteins with those of higher eukaryotic histones. We have found that acidic urea gel electrophoresis, sodium dodecyl sulfate gel electrophoresis or chromatography on carboxymethylcellulose columns failed to distinguish ribosomal proteins from histones. The majority of the ribosomal proteins did not adsorb to an amberlite CG-50 column in the presence of 8% guanidine hydrochloride. Histones quantitatively adsorbed to an amberlite CG-50 column in the presence of 8% guanidine hydrochloride. A small number of fungal acid-soluble nuclear proteins, which coelectrophoresed with histones, were identified in a presumed nucleolar and nuclear membrane fraction. This fraction contained large amounts of RNA and small amounts of DNA. It is suggested that contamination of yeast and fungal chromosome preparations by a small number of ribosomal proteins can occur. Furthermore, several commonly employed criteria did not distinguish contaminating ribosomal proteins from authentic histones.

Presence of histones in Aspergillus nidulans

Five major histone proteins have been extracted from chromatin isolated from purified nuclei of the fungus, Aspergillus nidulans. These proteins had chromatographic properties which were similar to reference calf thymus histones and were purified to electrophoretic homegeneity by gel chromatography of Bio-Gel P10, Bio-Gel P60, and Sephadex G-100. Electrophoresis of these proteins in three different systems (urea-starch, urea-acetic acid polyacrylamide, and discontinuous SDS polyacrylamide) showed that the A. nidulans histones H3 and H4 were nearly identical to calf thymus H3 and H4 with respect to net charge and molecular weight criteria, whereas the fungal histones H1, H2a and H2b were similar but not identical to the corresponding calf thymus histones. Amino acid analysis of A. nidulans histones H2a, H2b, and H4 showed them to be closely related to the homologous calf thymus histones. The mobility patterns of A. nidulans ribosomal basic proteins in three different electrophoretic systems were distinctly different from those of the fungal histones.

The isolation of nuclei and basic nucleoproteins from the cellular slime mold Dictyostelium discoideum

A method is described for the isolation of nuclei from an axenic strain of Dictyostelium discoideum using a sorbitol/Ficoll solution and low concentration of Triton X-100. Basic proteins have been extracted from the nuclei and on polyacrylamide gel electrophoresis yield a consistent pattern in which five major groups or bands predominate. Four of these five fractions comigrate with calf thymus histones and one fraction seems to be unique to D. discoideum. The slowest moving of the five fractions is soluble in 0.5 M perchloric acid and comigrates with calf thymus histone F1. After recovery from the perchloric acid solution by precipitation with acetone this fraction yielded one major band on electrophoresis.

Absence of histones from the chromosomal proteins of fungi

Interphase chromosomes were isolated in good yield from four species of fungi. In no case does the chromatin contain histones such as are characteristic of the chromosomes of other eukaryotic organisms.

A variegated position effect in Aspergillus nidulans

In mutants at the ‘bristle’ locus ofAspergillus nidulansthe conidiophore remains as a stiff hypha rather than developing a vesicle, sterigmata and conidia. ThebrlA12 allele of this locus has a variegated phenotype, and genetic analysis has shown that this is associated with a translocation which has a breakpoint in the map interval adjacent to thebristlelocus.

The mutant phenotype is partially repaired on high-salt medium at low pH, and can also be repaired by suppressors, one of which has been mapped at a locus unlinked tobrlA12.

The mutant provides proof that variegation is due to instability of gene expression and not to mutability sincebrlA12 is genetically stable and can be propagated from either conidia or sterile conidiophores, the structures formed at the two extremes of variegation, and the resulting colonies in both cases are identical to the original strain.

It has been shown by mitotic recombination that the translocation associated with the variegated mutant is a ‘simple translocation’ in which the distal half of linkage group VIII is attached to the end of linkage group III. This terminal attachment site does not appear to be damaged in any genetically detectable way.