HMf, a DNA-binding protein isolated from the hyperthermophilic archaeon Methanothermus fervidus, is most closely related to histones

Crystallization and preliminary X-ray characterization of the Methanothermus fervidus histones HMfA and HMfB

HMfA and HMfB are histone proteins from the thermophilic archaeon Methanothermus fervidus. They wrap DNA into nucleosome-like structures and appear to represent the basic core histone fold. HMfA was crystallized in space groups P4(2)2(1)2 and P2(1)2(1)2(1). HMfB crystallized in space group P2(1)2(1)2, while a selenomethionine-substituted variant, SeMet-HMfB, yielded crystals in C222(1). In all crystal forms HMfA, HMfB, or SeMet-HMfB may be present as homodimers.

Parallel origins of the nucleosome core and eukaryotic transcription from Archaea

Computational sequence analysis of 10 available archaean histone-like proteins has shown that this family is not only divergently related to the eukaryotic core histones H2A/B, H3, and H4, but also to the central domain of subunits A and C of the CCAAT-binding factor (CBF), a transcription factor associated with eukaryotic promoters. Despite the low sequence identity, it is unambiguously shown that the core histone fold shares a common evolutionary history. Archaean histones and the two CBF families show a remarkable variability in contrast to eukaryotic core histones. Conserved residues shared between families are identified, possibly being responsible for the functional versatility of the core histone fold. The H4 subfamily is most similar to archaean proteins and may be the progenitor of the other core histones in eukaryotes. While it is not clear whether archaean histones are more actively involved in transcription regulation, the present observations link two processes, nucleosomal packing and transcription in a unique way. Both these processes, evidently hybrid in Archaea, have originated before the ermergence of the eukaryotic cell.

Three classes of mutations in the A subunit of the CCAAT-binding factor CBF delineate functional domains involved in the three-step assembly of the CBF-DNA complex

The mammalian CCAAT-binding factor CBF (also called NF-Y or CP1) consists of three subunits, CBF-A, CBF-B, and CBF-C, all of which are required for DNA binding and present in the CBF-DNA complex. In this study we first established the stoichiometries of the CBF subunits, both in the CBF molecule and in the CBF-DNA complex, and showed that one molecule of each subunit is present in the complex. To begin to understand the interactions between the CBF subunits and DNA, we performed a mutational analysis of the CBF-A subunit. This analysis identified three classes of mutations in the segment of CBF-A that is conserved in Saccharomyces cerevisiae and mammals. Analysis of the first class of mutants revealed that a major part of the conserved segment was essential for interactions with CBF-C to form a heterodimeric CBF-A/CBF-C complex. The second class of mutants identified a segment of CBF-A that is necessary for interactions between the CBF-A/CBF-C heterodimer and CBF-B to form a CBF heterotrimer. The third class defined a domain of CBF-A involved in binding the CBF heterotrimer to DNA. The second and third classes of mutants acted as dominant negative mutants inhibiting the formation of a complex between the wild-type CBF subunits and DNA. The segment of CBF-A necessary for DNA binding showed sequence homology to a segment of CBF-C. Interestingly, these sequences in CBF-A and CBF-C were also homologous to the sequences in the histone-fold motifs of histones H2B and H2A, respectively, and to the archaebacterial histone-like protein HMf-2. We discuss the functional domains of CBF-A and the properties of CBF in light of these sequence homologies and propose that an ancient histone-like motif in two CBF subunits controls the formation of a heterodimer between these subunits and the assembly of a sequence-specific DNA-protein complex.

Gene cloning, expression, and characterization of the Sac7 proteins from the hyperthermophile Sulfolobus acidocaldarius

The genes for two Sac7 DNA-binding proteins, Sac7d and Sac7e, from the extremely thermophilic archaeon Sulfolobus acidocaldarius have been cloned into Escherichia coli and sequenced. The sac7d and sac7e open reading frames encode 66 amino acid (7608 Da) and 65 amino acid (7469 Da) proteins, respectively. Southern blots indicate that these are the only two Sac7 protein genes in S. acidocaldarius, each present as a single copy. Sac7a, b, and c proteins appear to be carboxy-terminal modified Sac7d species. The transcription initiation and termination regions of the sac7d and sac7e genes have been identified along with the promoter elements. Potential ribosome binding sites have been identified downstream of the initiator codons. The sac7d gene has been expressed in E. coli, and various physical properties of the recombinant protein have been compared with those of native Sac7. The UV absorbance spectra and extinction coefficients, the fluorescence excitation and emission spectra, the circular dichroism, and the two-dimensional double-quantum filtered 1H NMR spectra of the native and recombinant species are essentially identical, indicating essentially identical local and global folds. The recombinant and native proteins bind and stabilize double-stranded DNA with a site size of 3.5 base pairs and an intrinsic binding constant of 2 x 10(7) M-1 for poly[dGdC].poly[dGdC] in 0.01 M KH2PO4 at pH 7.0. The availability of the recombinant protein permits a direct comparison of the thermal stabilities of the methylated and unmethylated forms of the protein. Differential scanning calorimetry demonstrates that the native protein is extremely thermostable and unfolds reversibly at pH 6.0 with a Tm of approximately 100 degrees C, while the recombinant protein unfolds at 92.7 degrees C.

A variety of DNA-binding and multimeric proteins contain the histone fold motif

The histone fold motif has previously been identified as a structural feature common to all four core histones and is involved in both histone-histone and histone-DNA interactions. Through the use of a novel motif searching method, a group of proteins containing the histone fold motif has been established. The proteins in this group are involved in a wide variety of functions related mostly to DNA metabolism. Most of these proteins engage in protein-protein or protein-DNA interactions, as do their core histone counterparts. Among these, CCAAT-specific transcription factor CBF and its yeast homologue HAP are two examples of multimeric complexes with different component subunits that contain the histone fold motif. The histone fold proteins are distantly related, with a relatively small degree of absolute sequence similarity. It is proposed that these proteins may share a similar three-dimensional conformation despite the lack of significant sequence similarity.

Structure and stability of histone HMf from the hyperthermophilic archaeon Methanothermus fervidus

The secondary and quaternary structures and stabilities of recombinant (r) forms of the HMfA and HMfB histones from Methanothermus fervidus have been investigated by CD spectroscopy and formaldehyde-mediated protein-protein cross-linking. Both proteins were shown to be dimers in solutions containing 5-1300 mM KCl, at pH 6-10 and 25-83 degrees C, and specifically in 1 M KCl, at pH 7.5 and 83 degrees C, conditions which approximate those in vivo in M. fervidus cells. Heat treatment of a mixture of rHMfA and rHMfB homodimers resulted in the formation of rHMfA.rHMfB heterodimers, as demonstrated by two-dimensional PAGE. Heterodimer formation did not result in a CD-detectable conformational change from the homodimer states, indicating that homogeneous (rHMfA)2 and (rHMfB)2 preparations may be considered as structural models of heterodimers. At pH 2, both rHMfA and rHMfB were denatured under low-salt (< 0.2 M KCl) conditions, and their conformations were stabilized in a cooperative manner by increasing KCl concentration, with cooperativity constants for KCl uptake of 2.7 and 3.1, respectively. The alpha-helical conformations of rHMfA and rHMfB were salt-dependent, at both pH 2 and pH 7.5, with maximal helicities in 1 M KCl of 84% and 63% at pH 2, and 72% and 65% at pH 7.5, respectively. The data obtained indicate that the structures of HMfA and HMfB, in 100-200 mM KCl at pH 7.5 and 25 degrees C, are likely to be very similar to their in vivo structures, even though these conditions are far removed from those found in vivo.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification, cloning, sequencing, and overexpression of the gene encoding proclavaminate amidino hydrolase and characterization of protein function in clavulanic acid biosynthesis

Proclavaminate amidino hydrolase (PAH) catalyzes the reaction of guanidinoproclavaminic acid to proclavaminic acid and urea, a central step in the biosynthesis of the beta-lactamase inhibitor clavulanic acid. The gene encoding this enzyme (pah) was tentatively identified within the clavulanic acid biosynthetic cluster in Streptomyces clavuligerus by translation to a protein of the correct molecular mass (33 kDa) and appreciable sequence homology to agmatine ureohydrolase (M.B.W. Szumanski and S.M. Boyle, J. Bacteriol. 172:538-547, 1990) and several arginases, a correlation similarly recognized by Aidoo et al. (K. A. Aidoo, A. Wong, D. C. Alexander, R. A. R. Rittammer, and S. E. Jensen, Gene 147:41-46, 1994). Overexpression of the putative open reading frame as a 76-kDa fusion to the maltose-binding protein gave a protein having the catalytic activity sought. Cleavage of this protein with factor Xa gave PAH whose N terminus was slightly modified by the addition of four amino acids but exhibited unchanged substrate specificity and kinetic properties. Directly downstream of pah lies the gene encoding clavaminate synthase 2, an enzyme that carries out three distinct oxidative transformations in the in vivo formation of clavulanic acid. After the first of these oxidations, however, no further reaction was found to occur in vitro without the intervention of PAH. We have demonstrated that concurrent use of recombinant clavaminate synthase 2 and PAH results in the successful conversion of deoxyguanidinoproclavaminic acid to clavaminic acid, a four-step transformation. PAH has a divalent metal requirement, pH activity profile, and kinetic properties similar to those of other proteins of the broader arginase class.

Improved N-terminal processing of recombinant proteins synthesized in Escherichia coli

Preparations of rHMfA (recombinant histone A from Methanothermus fervidus) synthesized in E. coli by the heterologous expression of the hmfA gene were found to contain a mixture of rHMfA molecules, approximately 40% that retained the N-terminal formyl-methionyl residue (f-met-rHMfA), approximately 50% that lacked the formyl moiety but retained the methionyl residue (met-rHMfA), and only approximately 10% that had lost both components of the protein synthesis initiating amino acid residue and therefore had the same N-terminal sequence as native HMfA molecules synthesized in Mt. fervidus. Expression of the hmfA gene in E. coli cells grown in the presence of trimethoprim and thymidine, coupled with the concurrent over-expression of a methionine aminopeptidase-encoding map gene, has been shown to overcome this N-terminal heterogeneity problem and to result in rHMfA preparations in which > 85% of the molecules have the fully processed, native N-terminal sequence. This procedure should be generally useful for ensuring N-terminal processing of recombinant proteins synthesized in E. coli.

Methanobacterium formicicum, a mesophilic methanogen, contains three HFo histones

The mesophilic methanogen Methanobacterium formicicum JF-1 has been shown to contain three members of the HMf family of archaeal histones, designated HFoA1, HFoA2, and HFoB, and their encodinig genes (hfoA1, hfoA2, and hfoB) have been cloned and sequenced. The HFo histones have primary sequences that are 75 to 82% identical to the HMf sequences and appear to share ancestry with the core histones that form the eukaryal nucleosome. The HFo proteins bind and compact DNA molecules into nucleosome-like structures apparently identical to those formed by the HMf proteins, but, in contrast to the HMf proteins, this activity of the HFo proteins is lost after incubation at 95 degrees C for 5 h.

Functional interaction of yeast and human TATA-binding proteins with an archaeal RNA polymerase and promoter

TATA boxes are common structural features of eucaryal class II and archaeal promoters. In addition, a gene encoding a polypeptide with sequence similarity to eucaryal TATA-binding protein (TBP) has recently been detected in Archaea, but its relationship to the archaeal transcription factors A (aTFA) and B (aTFB) was unclear. Here, we demonstrate that yeast and human TBP can substitute for aTFB in a Methanococcus-derived archaeal cell-free transcription system. Template-commitment studies show that eucaryal TBP is stably sequestered at the archaeal promoter and that this interaction is further stabilized in combination with aTFA. Binding studies revealed that recognition of an archaeal promoter by TBP involves specific binding to the TATA box. These findings demonstrate a common function of TBP and aTFB and imply a common evolutionary origin of eucaryal and archaeal transcriptional machinery.

Growth-phase-dependent synthesis of histones in the archaeon Methanothermus fervidus

Histone preparations from Methanothermus fervidus (HMf) contain two small polypeptides, HMfA and HMfB, which in solution are dimers and compact DNA to form nucleosome-like structures. These archaeal nucleosome-like structures constrain positive DNA supercoils, in contrast to the negatively supercoiled DNA in eukaryal nucleosomes. HMfA has been found to make up as much as 80% of HMf preparations synthesized by M. fervidus cells during the exponential growth phase of batch cultures but to decrease to approximately 50% as cultures enter the stationary phase. By using a nondenaturing polyacrylamide gel system at pH 6.1, we have demonstrated that HMf preparations contain HMfA homodimers, HMfB homodimers, and HMfA-HMfB heterodimers and that heating a mixture of recombinant HMfA and HMfB homodimers at 95 degrees C for 5 min generates HMfA-HMfB heterodimers. Circular dichroism spectroscopy indicates that HMfA and HMfB have very similar secondary structures, but based on agarose gel electrophoretic mobility shifts, DNA topology assays, and electron microscopy, they have different DNA binding properties. HMfA binding to DNA could be detected at lower protein/DNA ratios than HMfB, but HMfB binding resulted in more extensive DNA compaction. The increased HMfB synthesized in cells approaching the stationary phase and the highly compacted state of HMfB-bound DNA are consistent with preparations for the impending period of limited genome activity.

On the evolution of arginases and related enzymes

Sequence analysis of the arginase/agmatine ureohydrolase family, important enzymes in arginine/agmatine metabolism and the urea cycle, reveals the similarity of arginases to formiminoglutamate hydrolase (hutG) in Klebsiella aerogenes and to a previously unidentified open reading frame adjacent to the HMf locus of the archaebacterium Methanothermus fervidus. The gene structure and distribution of these homologous proteins across primary kingdoms suggest that this family is another example of a primordial enzyme possibly present in the universal common ancestor and that can be used as phylogenetic marker.

DNA stability at temperatures typical for hyperthermophiles

We have studied the fate of covalently-closed circular DNA in the temperature range from 95 to 107 degrees C. Supercoiled plasmid was not denatured up to the highest temperature tested. However, it was progressively transformed into open DNA by cleavage and then denatured. Thermodegradation was not dependent on the DNA supercoiling density. In particular, DNA made positively supercoiled by an archaeal reverse gyrase was not more resistant to depurination and thermodegradation than negatively supercoiled DNA. Thermodegradation was similar in aerobic or anaerobic conditions but strongly reduced in the presence of physiological concentrations of K+ or Mg2+. These results indicate that the major problem faced by covalently closed DNA in hyperthermophilic conditions is not thermodenaturation, but thermodegradation, and that intracellular salt concentration is important for stability of DNA primary structure. Our data suggest that reverse gyrase is not directly required to protect DNA against thermodegradation or thermodenaturation.

The sequence, and its evolutionary implications, of a Thermococcus celer protein associated with transcription

Through random search, a gene from Thermococcus celer has been identified and sequenced that appears to encode a transcription-associated protein (110 amino acid residues). The sequence has clear homology to approximately the last half of an open reading frame reported previously for Sulfolobus acidocaldarius [Langer, D. & Zillig, W. (1993) Nucleic Acids Res. 21, 2251]. The protein translations of these two archaeal genes in turn are homologs of a small subunit found in eukaryotic RNA polymerase I (A12.2) and the counterpart of this from RNA polymerase II (B12.6). Homology is also seen with the eukaryotic transcription factor TFIIS, but it involves only the terminal 45 amino acids of the archaeal proteins. Evolutionary implications of these homologies are discussed.

There must be a prokaryote somewhere: microbiology's search for itself

While early microbiologists showed considerable interest in the problem of the natural (evolutionary) relationships among prokaryotes, by the middle of this century that problem had largely been discarded as being unsolvable. In other words, the science of microbiology developed without an evolutionary framework, the lack of which kept it a weak discipline, defined largely by external forces. Modern technology has allowed microbiology finally to develop the needed evolutionary framework, and with this comes a sense of coherence, a sense of identity. Not only is this development radically changing microbiology itself, but also it will change microbiology's relationship to the other biological disciplines. Microbiology of the future will become the primary biological science, the base upon which our future understanding of the living world rests, and the font from which new understanding of it flows.

Enhanced thermotolerance and temperature-induced changes in protein composition in the hyperthermophilic archaeon ES4

The hyperthermophilic archaeon ES4, a heterotrophic sulfur reducer isolated from a deep-sea hydrothermal vent, is capable of protecting itself from thermal stress at temperatures above its optimum for growth. The thermotolerance of ES4 was determined by exposing log-phase cells to various lethal high temperatures. When ES4 was shifted from 95 to 102 degrees C, it displayed recovery from an exponential rate of death, followed by transient thermotolerance. When ES4 was shifted directly from 95 to either 105 or 108 degrees C, only exponential death occurred. However, a shift from 95 to 105 degrees C with an intermediate incubation at 102 degrees C also gave ES4 transient thermotolerance to 105 degrees C. The protein composition of ES4 was examined at temperatures ranging from 75 to 102 degrees C by one-dimensional electrophoresis. Two proteins with molecular masses of approximately 90 and 150 kDa significantly decreased in abundance with increasing growth temperature, while a 98-kDa protein, present at very low levels at normal growth temperatures (76 to 99 degrees C), was more abundant at higher temperatures. The enhanced tolerance to hyperthermal conditions after a mild hyperthermal exposure and the increased abundance of the 98-kDa protein at above-optimal temperatures imply that ES4 is capable of a heat shock-like response previously unseen in hyperthermophilic archaea.

Interaction between the Chlamydia trachomatis histone H1-like protein (Hc1) and DNA

The gene encoding the Chlamydia trachomatis histone H1-like protein (Hc1) from serovar L2 was cloned into Escherichia coli by use of expression vector pET11d. In this vector, transcription of the gene is under the control of a bacteriophage T7 promoter, and T7 RNA polymerase is inducible in the host. Following induction, the E. coli cells were lysed gently. Gel filtration of the lysate revealed comigration of DNA and Hc1 in the voided volume. Electron microscopy revealed the DNA to be complexed with protein in large aggregates, often in the form of spherical bodies. Purified recombinant Hc1 maintained its DNA-binding capacity and was able at high concentrations to form condensed aggregates with DNA (one molecule of Hc1 per base pair) independently of the form or size of the DNA but with a slight preference for supercoiled DNA. Hc1 alone is thus able to package DNA into condensed spherical bodies.

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.

Use of gel retardation to analyze protein-nucleic acid interactions

Protein-nucleic acid interactions are crucial in the regulation of many fundamental cellular processes. The nature of these interactions is susceptible to analysis by a variety of methods, but the combination of high analytical power and technical simplicity offered by the gel retardation (band shift) technique has made this perhaps the most widely used such method over the last decade. This procedure is based on the observation that the formation of protein-nucleic complexes generally reduces the electrophoretic mobility of the nucleic acid component in the gel matrix. This review attempts to give a simplified account of the physical basis of the behavior of protein-nucleic acid complexes in gels and an overview of many of the applications in which the technique has proved especially useful. The factors which contribute most to the resolution of the complex from the naked nucleic acid are the gel pore size, the relative mass of protein compared with nucleic acid, and changes in nucleic acid conformation (bending) induced by binding. The consequences of induced bending on the mobility of double-strand DNA fragments are similar to those arising from sequence-directed bends, and the latter can be used to help characterize the angle and direction of protein-induced bends. Whether a complex formed in solution is actually detected as a retarded band on a gel depends not only on resolution but also on complex stability within the gel. This is strongly influenced by the composition and, particularly, the ionic strength of the gel buffer. We discuss the applications of the technique to analyzing complex formation and stability, including characterizing cooperative binding, defining binding sites on nucleic acids, analyzing DNA conformation in complexes, assessing binding to supercoiled DNA, defining protein complexes by using cell extracts, and analyzing biological processes such as transcription and splicing.

HMt, a histone-related protein from Methanobacterium thermoautotrophicum delta H

HMt, a histone-related protein, has been isolated and characterized from Methanobacterium thermoautotrophicum delta H. HMt preparations contain two polypeptides designated HMt1 and HMt2, encoded by the hmtA and hmtB genes, respectively, that have been cloned, sequenced, and expressed in Escherichia coli. HMt1 and HMt2 are predicted to contain 68 and 67 amino acid residues, respectively, and have calculated molecular masses of 7,275 and 7,141 Da, respectively. Aligning the amino acid sequences of HMt1 and HMt2 with the sequences of HMf1 and HMf2, the subunit polypeptides of HMf, a histone-related protein from the hyperthermophile Methanothermus fervidus, revealed that 40 amino acid residues (approximately 60%) are conserved in all four polypeptides. In pairwise comparisons, these four polypeptides are 66 to 84% identical. The sequences and locations of the TATA box promoter elements and ribosome binding sites are very similar upstream of the hmtA and hmtB genes in M. thermoautotrophicum and upstream of the hmfA and hmfB genes in M. fervidus. HMt binding compacted linear pUC19 DNA molecules in vitro and therefore increased their electrophoretic mobilities through agarose gels. At protein/DNA mass ratios of < 0.2:1, HMt binding caused an increase in the overall negative superhelicity of relaxed, circular DNA molecules, but at HMt/DNA mass ratios of > 0.2:1, positive supercoils were introduced into these molecules. HMt and HMf are indistinguishable in terms of their abilities to compact and constrain DNA molecules in positive toroidal supercoils in vitro. Histone-related proteins with these properties are therefore not limited to reverse gyrase-containing hyperthermophilic species.

HMf, a histone-related protein from the hyperthermophilic archaeon Methanothermus fervidus, binds preferentially to DNA containing phased tracts of adenines

HMf, a histone-related protein from Methanothermus fervidus, was found to bind preferentially to a DNA that is intrinsically bent as a result of the presence of phased oligo(dA) tracts. The intergenic regions in M. fervidus DNA are A+T rich and frequently contain oligo(dA) tracts, some of which may have the size and phasing required to create a net bending in one direction. The binding of HMf to bent DNA could play a direct role in gene expression and stabilization of the genome of this organism.

Transcription in vivo and in vitro of the histone-encoding gene hmfB from the hyperthermophilic archaeon Methanothermus fervidus

Immediately upstream of the hmfB gene, in a DNA fragment cloned from Methanothermus fervidus, are two identical tandemly repeated copies of a 73-bp sequence that contain the sequence 5'TTTATATA, which conforms precisely to the consensus TATA box element proposed for methanogen promoters. By using this duplicated region as the template DNA and a cell-free transcription system derived from Methanococcus thermolithotrophicus, transcription in vitro was found to initiate at two identical sites 73 bp apart, each 25 bp downstream from a TATA box, thus providing strong evidence for the functional conservation of this transcriptional signal in two phylogenetically very diverse methanogens. Transcription of the hmfB gene in vivo in M. fervidus was found to occur at only one of these sites, and consistent with this observation, recloning and sequencing of this intergenic region after its amplification by the polymerase chain reaction demonstrated that the genome of M. fervidus contains only one copy of the 73-bp sequence upstream of the hmfB gene. Since the second copy of the 73-bp sequence, presumably generated artifactually during the original hmfB cloning, functioned equally well as a promoter in the M. thermolithotrophicus transcription system, all information needed by the heterologous RNA polymerase to initiate transcription accurately in vitro must be present within this sequence. The hmfB gene encodes HMf-2, one of the two subunits of HMf, an abundant DNA binding protein in M. fervidus which binds to DNA molecules in vitro, forming nucleosomelike structures. Cell-free transcription was inhibited by adding HMf or eucaryotic core histones at protein-to-DNA mass ratios of 0.3:1 and 1:1, respectively, whereas the archael histonelike protein HTa from Thermoplasma acidophilum inhibited transcription in vitro only at much higher protein-to-DNA mass ratios and the bacterial histonelike protein HU from Escherichia coli had no detectable effect on transcription.

DNA binding by the archaeal histone HMf results in positive supercoiling

HMf, a histone from the hyperthermophilic archaeon Methanothermus fervidus binds double-stranded DNA molecules in vitro, forming compact structures that visibly resemble eukaryal nucleosomes. We show here that HMf binding increases the helical periodicity of DNA molecules to approximately 11 base pairs (bp) per turn and that DNA molecules in these nucleosome-like structures are constrained in positive toroidal supercoils. Based on the mass of HMf needed to cause a change in linking number (delta Lk), the maximum delta Lk introduced into circular DNA molecules of known sizes, and electron microscopy, we estimate that each HMf-DNA structure contains between 90 and 150 bp of DNA wrapped in 1.5 positive toroidal supercoils around a core of four HMf molecules. A model and pathway for the formation of these structures in vitro are presented and the possible role of positive toroidal wrapping of the M. fervidus genome in vivo is discussed.

The gene for a halophilic glutamate dehydrogenase: sequence, transcription analysis and phylogenetic implications

We have isolated and sequenced the gene for a putative NADP-dependent glutamate dehydrogenase from the extremely halophilic archaebacterium Halobacterium salinarium. This gene is transcribed as a unique RNA molecule of about 1700 nucleotides. The 5' end of the transcript contains characteristic consensus transcription initiation and promoter sequences observed in halophilic archaebacteria. The encoded polypeptide, with a predicted length of 435 amino acids, shows significant overall homology and conservation of functional domains when compared with different eubacterial and eukaryotic glutamate dehydrogenases. Surprisingly, the archaebacterial protein shares a larger number of identical amino acid residues with homologous polypeptides from higher eukaryotes than with those from unicellular eukaryotes and eubacteria.

Cloning and sequencing of a multigene family encoding the flagellins of Methanococcus voltae

The flagellins of Methanococcus voltae are encoded by a multigene family of four related genes (flaA, flaB1, flaB2, and flaB3). All four genes map within the same region of the genome, with the last three arranged in a direct tandem. Northern (RNA) blot and primer extension analyses of total cellular RNA indicate that all four genes are transcribed. The flaB1, flaB2, and flaB3 flagellins are transcribed as part of a large polycistronic message which encodes at least one more protein which is not a flagellin. An intercistronic stem-loop followed by a poly(T) tract located between the flaB2 and flaB3 genes appears to increase the resistance of the flaB1/flaB2 portion of this polycistronic message to digestion by endogenous RNases. The flaA gene, located approximately 600 bp upstream from the tandem, is transcribed as a separate message at very low levels. The four open reading frames encode proteins of molecular weights 23,900, 22,400, 22,800, and 25,500, much less than the Mr values of 33,000 and 31,000 for the flagellins calculated from sodium dodecyl sulfate-polyacrylamide gel electrophoresis of isolated flagellar filaments. Each flagellin contains multiple eukaryotic glycosylation signals (Arg-X-Ser/Thr), although they do not appear to be glycoproteins, and each has an 11- or 12-amino-acid leader peptide. The N termini of all four flagellins (amino acids 1 through 47 of the mature protein) are very hydrophobic, and this region shows a high degree of homology with the flagellins from Halobacterium halobium.

Analysis and nucleotide sequence of the genes encoding the surface-layer glycoproteins of the hyperthermophilic methanogens Methanothermus fervidus and Methanothermus sociabilis

The genes (slgA) encoding the surface-layer glycoproteins of the hyperthermophilic methanogens Methano-thermus pervidus and Methanothermus sociabilis were cloned and sequenced. The nucleotide sequences of these genes differ at only nine positions, resulting in three amino acid differences. In both organisms, the transcription start site was localized by primer extension analyses. The DNA sequence at this site conforms to the promotor box B motif for promotors of archaea. 24 nucleotides upstream of the transcription start is an A + T-rich region, which closely resembles the consensus box A motif of promoters of methanogens. Ribosome binding sites are exactly complementary to the 3' end of the 16S rRNA of these methanogens. Both slgA genes encode for a precursor of the mature surface-layer protein containing 593 amino acid residues with a putative N-terminal signal sequence of 22 amino acid residues. The deduced protein sequences contain 20 sequon structures representing possible carbohydrate-binding sites. In comparison with other surface-layer proteins, these obtained from the two hyperthermophilic methanogens contain unusually high amounts of isoleucine, asparagine and cysteine residues. Predicted secondary structures have a high content of beta-sheet structure (44%) and only 7% alpha-helix structures.