Characterization of the chromosomal protein HMb isolated from Methanosarcina barkeri

High-LET irradiation of a DNA-binding protein: protein-protein and DNA-protein crosslinks

The chromosomal protein MC1 is a monomeric protein of 93 amino acids that is able to bind any DNA but has a slight preferential affinity for some sequences and structures, like cruciform and minicircles. The protein has been irradiated with 36Ar18+ ions of 95 MeV/nucleon. The LET of these particles in water is close to 270 keV/microm. We tested the activity of the protein by measuring its ability to form complexes with DNA. We tested the integrity of the protein by measuring the molecular weight of the species formed. Compared with gamma radiation, we observed for the same dose a less efficient inactivation of the protein, a greater protection of the protein by the bound DNA, a lower induction of chain breakage, and a greater production of protein-protein and DNA-protein crosslinks. The results are discussed in terms of the quantitative and the qualitative differences between the two types of radiation: The global radical yield is slightly higher with gamma rays, whereas the density of radicals produced along the particle track is considerably higher with argon ions.

Response of a DNA-binding protein to radiation-induced oxidative stress

The DNA-binding protein MC1 is a chromosomal protein extracted from the archaebacterium Methanosarcina sp. CHTI55. It binds any DNA, and exhibits an enhanced affinity for some short sequences and structures (circles, cruciform DNA). Moreover, the protein bends DNA strongly at the binding site. MC1 was submitted to oxidative stress through gamma-ray irradiation. In our experimental conditions, damage is essentially due to hydroxyl radicals issued from water radiolysis. Upon irradiation, the regular complex between MC1 and DNA disappears, while a new complex appears. In the new complex, the protein loses its ability to recognise preferential sequences and DNA circles, and bends DNA less strongly than in the regular one. The new complex disappears and the protein becomes totally inactivated by high doses.A model has been proposed to explain these experimental results. Two targets, R(1) and R(2), are concomitantly destroyed in the protein, with different kinetics. R(2) oxidation has no effect on the regular binding, whereas R(1) oxidation modifies the functioning of MC1: loss of preferential site and structure recognition, weaker bending. The destruction of both R(1) and R(2) targets leads to a total inactivation of the protein. This model accounts for the data obtained by titrations of DNA with irradiated proteins. When the protein is irradiated in the complex with DNA, bound DNA protects its binding site on the protein very efficiently. The highly oxidisable tryptophan and methionine could be the amino acid residues implicated in the inactivation process.

Preferential binding of the archaebacterial histone-like MC1 protein to negatively supercoiled DNA minicircles

The interaction of the archaebacterial MC1 protein with 207 bp negatively supercoiled DNA minicircles has been examined by gel retardation assays and compared to that observed with the relaxed DNA minicircle. MC1 binding induces a drastic DNA conformational change of each minicircle, leading to an increase of the electrophoretic mobility of the DNA. A slight increase in salt concentration enhances the amount of bound MC1, and high NaCl concentrations are required to dissociate the complexes. Furthermore, the salt effect on binding depends on the supercoiling state of the DNA. The dissociation rates decrease with increasing linking difference of the minicircles relative to their relaxed configuration to reach a maximum at -2 turns. In addition, differences between the topoisomers are also observed in terms of stoichiometry of the strongest complexes. So with the -2 topoisomer the complex with two MC1 molecules is the most stable, while with the -1 and -3 topoisomers, the strongest ones are those with one MC1 molecule per DNA ring.

Conformational changes of DNA minicircles upon the binding of the archaebacterial histone-like protein MC1

Binding of the archaebacterial histone-like protein MC1 to DNA minicircles has been examined by gel retardation and electron microscopy. MC1 preferentially binds to a 207-base pair relaxed DNA minicircle as compared with the linear fragment. Random binding is observed at very low ionic strength, and a slight increase in salt concentration highly favors the formation of a complex that corresponds to the binding of two MC1 molecules per DNA ring. Measurements of dissociation rates show that this complex is remarkably stable, and electron microscopy reveals that it is characterized by two diametrically opposed kinks. These results are discussed in regard to the mechanisms by which MC1 affects DNA structure.

Nucleoid proteins

This article examines the published evidence in support of the classification of organisms into three groups (Bacteria, Archae, and Eukarya) instead of two groups (prokaryotes and eukaryotes) and summarizes the comparative biochemistry of each of the known histone-like, nucleoid DNA-binding proteins. The molecular structures and amino acid sequences of Archae are more similar to those of Eukarya than of Bacteria, with a few exceptions. Cytochemical methodology employed for localizing these proteins in archaeal and bacterial cells has also been reviewed. It is becoming increasingly apparent that these proteins participate both in the organization of DNA and in the control of gene expression. Evidence obtained from biochemical properties, structural and functional differences, and the ultrastructural location of these proteins, as well as from gene mutations clearly justifies the division of prokaryotes into bacterial and archaeal groups. Indeed, chromosomes, whether they be nuclear, prokaryotic, or organellar, are invariably complexed with abundant, small, basic proteins that bind to DNA with low sequence specificity. These proteins include the histones, histone-like proteins, and nonhistone high mobility group (HMG) proteins.

Radioprotection of DNA by a DNA-binding protein: MC1 chromosomal protein from the archaebacterium Methanosarcina sp. CHTI55

The archaebacterial chromosomal protein MC1 binds tightly and unspecifically to DNA; binding protects DNA against radiolysis by fast neutrons. At low covering of pBR322 plasmid DNA, one bound protein protects some 50 attack sites (phosphate-sugar moieties) against both single (ssb) and double strand breaks (dsb). At high covering of plasmid, protection against dsb becomes almost complete, although about half of the attack sites remain accessible to ssb. DNA restriction fragments were used to investigate the organization of the complexes, and its consequences on DNA radiolysis. Sequencing gel electrophoresis of the radiolytically-broken fragments are almost regular in the absence of protein, showing that breakage occurs at every base. In the presence of the protein, a periodic protection pattern is observed. The period of 11 base pairs is interpreted as the minimum distance between two adjacent MC1 proteins.

Stoichiometry of the binding of chromosomal protein MC1 from the archaebacterium, Methanosarcina spp. CHTI55, to DNA

We have investigated the binding stoichiometry of the chromosomal MC1 protein on DNA using the gel retardation technique. Analysis of the distribution of the complex containing 0, 1, 2, 3 ... bound proteins shows that the protein MC1 interacts with the DNA as a monomer. Binding experiments with short DNA fragments of various lengths shows that the site size is 11 bp in length. These results are compared to those obtained with other chromosomal proteins including HU protein.

Chromosomal structure of the halophilic archaebacterium Halobacterium salinarium

The chromosomal structure of the extremely halophilic archaebacterium Halobacterium salinarium was examined. Sheared chromosomes prepared from the bacteria in the late exponential phase were separated into two peaks (peaks I and II) by sucrose gradient centrifugation, suggesting that the chromosomes consist of two parts differing in quality. The UV spectra of peaks I and II resembled those of DNA and eukaryotic chromatin, respectively. Electron microscopic observations revealed that the major component of peak I was protein-free DNA, while the major components of peak II were rugged thick fibers with a diameter of 17 to 20 nm. The rugged fibers basically consisted of bacterial nucleosome-like structures composed of DNA and protein, as demonstrated in experiments with proteinase and nuclease digestion. Whole-mount electron microscopic observations of the chromosomes directly spread onto a water surface revealed a configuration in which the above-described regions were localized on a continuous DNA fiber. From these results it is concluded that the H. salinarium chromosome is composed of regions of protein-free DNA and DNA associated with nucleosome-like structures. Peaks I and II were predominant in the early exponential phase and stationary phase, respectively; therefore, the transition of the chromosome structure between non-protein-associated and protein-associated forms seems to be related to the bacterial growth phase.

Salt-dependent and protein-concentration-dependent changes in the solution structure of the DNA-binding histone-like protein, HBsu, from Bacillus subtilis

The solution structure of the histone-like DNA-binding protein, HBsu, from Bacillus subtilis in 2 mM sodium cacodylate, pH 7.5, is sensitive to the ionic strength of the buffer. This was shown by circular dichroism measurements at different concentrations of sodium chloride and potassium fluoride. The stability of HBsu is also influenced; at HBsu concentrations of about 0.1 mg.ml-1, melting temperatures of 32 degrees C and 55 degrees C were found in the absence of potassium fluoride and in the presence of 0.5 M potassium fluoride, respectively, exhibiting drastic ionic-strength-dependent differences in the temperature-induced unfolding of HBsu. Furthermore, at low ionic strength, circular dichroism spectra vary markedly depending on the HBsu concentration in the approximate range 0.2-3 mg.ml-1. Such protein-concentration-dependent differences in the spectra were not observed in the presence of 0.5 M potassium fluoride. Very similar circular dichroism spectra of HBsu and the histone-like DNA-binding protein of Bacillus stearothermophilus (HBst) at high ionic strength, indicate comparable structures of both proteins under these conditions. Estimation of the secondary structure content from the circular dichroism spectra yields data which are in satisfactory agreement with the values obtained from the crystal structure of HBst. Transition temperatures of 45 degrees C and 61 degrees C were found in differential scanning calorimetric measurements performed with HBsu in potassium-fluoride-free buffer and in the presence of 0.5 M potassium fluoride, respectively. The thermodynamic data point to the melting of native HBsu dimers into two denatured monomers.

Conformational study of the chromosomal protein MC1 from the archaebacterium Methanosarcina barkeri

Methanogen chromosomal protein MC1 is a polypeptide of 93 amino acid residues (Mr 10,757) which represents the major protein associated with the DNA of the archaebacterium Methanosarcina barkeri and can protect DNA against thermal denaturation. The conformation of protein MC1 has been investigated by means of predictive methods, infrared spectroscopy, circular dichroism and tryptophan fluorescence studies. Protein MC1 has a low amount of alpha-helix but contains antiparallel beta-sheet strands. The larger hydrophobic cluster which contains tryptophan at position 61 appears buried in the protein. Addition of salts induces the unfolding of the protein and makes the tryptophan indole ring more rigid. With respect to its primary structure and its conformation, protein MC1 appears radically different from the chromosomal DNA-binding protein II (also called HU-type protein) in eubacteria.

Primary structure of the chromosomal protein MC1 from the archaebacterium Methanosarcina sp. CHTI 55

The DNA of the thermophilic archaebacterium Methanosarcina sp. CHTI 55 has been shown to be associated with two proteins called MC1 and MC2, of molecular mass 11 kDa and 17 kDa (Chartier et al. (1988) Biochim. Biophys. Acta 951, 149-156). The most abundant of these proteins, protein MC1, can protect DNA against thermal denaturation. In the present paper we report the covalent structure of protein MC1 and its effect on transcription of DNA in vitro. The covalent structure was determined from automated sequence analysis of the protein and from structural data provided by peptides derived from cleavage of the protein at aspartic acid and arginine residues. The amino-acid sequence of protein MC1 from Methanosarcina sp. CHTI 55 is closely related to that of the protein MC1 (previously called HMb) isolated from Methanosarcina barkeri strain MS: among the nine substitutions observed between the two proteins seven are conservative. Transcription of DNA in vitro is stimulated by protein MC1 at low protein-to-DNA ratio but is inhibited at a ratio higher than 0.1 (w/w), which is the one determined in the bacterial deoxyribonucleoprotein complex.

Nucleosomelike structures associated with chromosomes of the archaebacterium Halobacterium salinarium

Chromosomes of the halophilic archaebacterium Halobacterium salinarium were examined by electron microscopy after being spread onto water. The major part of the chromosomal DNA was associated with protein particles with diameter of 9.4 nm, arranged tandemly along the DNA fibers. Thus, the primary structure of the chromosome resembles that of eucaryote chromosomes.

High-performance liquid chromatographic separation of variants of chromosomal proteins from prokaryotes

The separation of variants of chromosomal proteins exhibiting closely related amino acid compositions has been achieved using weak cation-exchange or reversed-phase high-performance liquid chromatography. The purity of the isolated proteins has been ascertained by polyacrylamide gel electrophoresis and in several cases by micro-sequencing.

Gene structure, organization, and expression in archaebacteria

Major advances have recently been made in understanding the molecular biology of the archaebacteria. In this review, we compare the structure of protein and stable RNA-encoding genes cloned and sequenced from each of the major classes of archaebacteria: the methanogens, extreme halophiles, and acid thermophiles. Protein-encoding genes, including some encoding proteins directly involved in methanogenesis and photoautotrophy, are analyzed on the basis of gene organization and structure, transcriptional control signals, codon usage, and evolutionary conservation. Stable RNA-encoding genes are compared for gene organization and structure, transcriptional signals, and processing events involved in RNA maturation, including intron removal. Comparisons of archaebacterial structures and regulatory systems are made with their eubacterial and eukaryotic homologs.

Characterization of the chromosomal protein MC1 from the thermophilic archaebacterium Methanosarcina sp. CHTI 55 and its effect on the thermal stability of DNA

In the deoxyribonucleoprotein complex of Methanosarcina sp. CHTI 55, DNA is associated with two proteins, named MC1 (methanogen chromosomal protein 1) (Mr 10,760) and MC2 (Mr 17,000). Protein MC1, the most abundant of these proteins, is closely related to the Methanosarcina barkeri MS protein MC1. The effect of Methanosarcina sp. CHTI 55 protein MC1 on the thermal stability of DNA has been studied in native deoxyribonucleoprotein complex, as well as in reconstituted complexes, and it has been compared to the effect of E. coli DNA-binding protein II. Both proteins are able to protect DNA against thermal denaturation, but the differences observed in the melting profiles suggest that they interact by different mechanisms. Moreover, our studies indicate that one molecule of protein MC1 protects eight base pairs of DNA.

Primary structure of the chromosomal protein HMb from the archaebacteria Methanosarcina barkeri

The amino acid sequence of the protein HMb, a protein of 93 residues (Mr 10757) which represents the major acid-soluble component of the Methanosarcina barkeri nucleoprotein complex, has been established from automated sequence analysis of the protein and from structural data provided by peptides derived from cleavage of the protein at aspartic acid, arginine and methionine residues. The protein HMb is mainly characterized by a high amount of charged residues (15% of acidic residues and 26.8% of basic residues) which are distributed all along the polypeptide chain. The amino acid sequence of the protein HMb is not homologous to any eubacterial, archaebacterial or eukaryotic chromosomal proteins known up to now.