Nucleotide Sequence of the 16S Ribosomal RNA Gene from the Haloalkaliphilic Archaeon (Archaebacterium) Natronobacterium magadii, and the Phylogeny of Halobacteria

Isolation and characterization of halophilic Archaea able to produce biosurfactants

Halotolerant microorganisms able to live in saline environments offer a multitude of actual or potential applications in various fields of biotechnology. This is why some strains of Halobacteria from an Algerian culture collection were screened for biosurfactant production in a standard medium using the qualitative drop-collapse test and emulsification activity assay. Five of the Halobacteria strains reduced the growth medium surface tension below 40 mN m(-1), and two of them exhibited high emulsion-stabilizing capacity. Diesel oil-in-water emulsions were stabilized over a broad range of conditions, from pH 2 to 11, with up to 35% sodium chloride or up to 25% ethanol in the aqueous phase. Emulsions were stable to three cycles of freezing and thawing. The components of the biosurfactant were determined; it contained sugar, protein and lipid. The two Halobacteria strains with enhanced biosurfactant producers, designated strain A21 and strain D21, were selected to identify by phenotypic, biochemical characteristics and by partial 16S rRNA gene sequencing. The strains have Mg(2+), and salt growth requirements are always above 15% (w/v) salts with an optimal concentration of 15-25%. Analyses of partial 16S rRNA gene sequences of the two strains suggested that they were halophiles belonging to genera of the family Halobacteriaceae, Halovivax (strain A21) and Haloarcula (strain D21). To our knowledge, this is the first report of biosurfactant production at such a high salt concentration.

Intragenomic heterogeneity and intergenomic recombination among haloarchaeal rRNA genes

More than one copy of rRNA operons, which code for both the small-subunit (SSU) and large-subunit (LSU) rRNA, are often found in prokaryotes. It is generally assumed that all rRNA operons within a single cell are almost identical. A notable exception is the extremely halophilic archaeal genus Haloarcula, most species of which are known to harbor highly divergent rRNA operons that differ at approximately 5% of the nucleotide positions in the SSU gene and at 1 to 2% of the nucleotide positions in the LSU gene. We report that such intragenomic heterogeneity is not unique to Haloarcula, as high levels of intragenomic sequence variation have been observed for the SSU genes of two other genera of extreme halophiles, Halosimplex and Natrinema. To investigate this in detail, the two rRNA operons of Halosimplex carlsbadense and the four operons of Natrinema sp. strain XA3-1 were cloned and completely sequenced. The SSU and LSU genes of H. carlsbadense show the highest levels of intragenomic heterogeneity observed so far in archaea (6.7 and 2.6%). The operons of Natrinema sp. strain XA3-1 have additional unusual characteristics, such as identical internal transcribed spacers, while one of four SSU genes is 5% divergent and all LSU genes differ from each other by 0.9 to 1.9%. The heterogeneity among the Natrinema sp. strain XA3-1 LSU genes is localized in hot spots, and one of these regions is shown to be the result of a recombination event with a distantly related halophile. This is the first example of interspecies recombination between rRNA genes in archaea, and the recombination occurred over one of the largest phylogenetic distances ever reported for such an event. We suggest that intragenomic heterogeneity of rRNA operons is an ancient and stable trait in several lineages of the Halobacteriales. The impact of this phenomenon on the taxonomy of extremely halophilic archaea is discussed.

Microbial alkaline proteases: from a bioindustrial viewpoint

Alkaline proteases are of considerable interest in view of their activity and stability at alkaline pH. This review describes the proteases that can resist extreme alkaline environments produced by a wide range of alkalophilic microorganisms. Different isolation methods are discussed which enable the screening and selection of promising organisms for industrial production. Further, strain improvement using mutagenesis and/or recombinant DNA technology can be applied to augment the efficiency of the producer strain to a commercial status. The various nutritional and environmental parameters affecting the production of alkaline proteases are delineated. The purification and properties of these proteases is discussed, and the use of alkaline proteases in diverse industrial applications is highlighted.

Sequencing of flagellin genes from Natrialba magadii provides new insight into evolutionary aspects of archaeal flagellins

We have determined the nucleotide sequence of a flagellin gene locus from the haloalkaliphilic archaeon Natrialba magadii, identified the gene products among proteins forming flagella, and demonstrated cotranscription of the genes. Based on the sequence analysis we suggest that different regions of the genes might have distinct evolutionary histories including possible genetic exchange with bacterial flagellin genes.

The structural protein E of the archaeal virus phiCh1: evidence for processing in Natrialba magadii during virus maturation

phiCh1 is a lysogenic virus for the haloalkalophilic archaeon Natrialba magadii. The virus morphology resembles other members of Myoviridae infecting Halobacterium species. The gene of the major capsid protein E of virus phiCh1 was cloned and the DNA sequence was determined. Gene E was mapped to a 3.2-kbp ClaI fragment, localized to the 5'-end of the phiCh1 genome. The complete nucleotide sequence of this region was determined and the identity of gene E was confirmed by comparing the experimentally determined N-terminal amino acid sequence of the purified protein to the translated DNA sequence of its open reading frame. We present evidence that the gene E product is proteolytically cleaved between Lys(16) and Asn(17) to yield the 305 residue polypeptides found in the mature viral capsid. Processing of the protein itself during virus development was determined by 2D gel electrophoresis using protein E-specific antibodies. Sequence similarity studies revealed an 80% identity to capsid protein Hp32 of phiH, infecting Halobacterium salinarum. RT-PCR analysis as well as Western blot studies revealed gene E as a late gene. Transcripts and proteins could be detected shortly before onset of lysis of the lysogenic strain N. magadii L11.

Nucleotide sequence of the 235 rRNA from Haloferax mediterranei and phylogenetic analysis of halophilic archaea based on LSU rRNA

23S rRNA gene from the halophilic archaeon Haloferax mediterranei (strain ATCC 33500) was cloned and sequenced. Proceeding from the 2,912 nucleotides long sequence, the secondary structure of Haloferax genus large subunit rRNA was proposed. Haloferax mediterranei intergenic spacers 16S/23S and 23S/5S were also sequenced, and found to be 382 and 116 nucleotides long respectively. The 16S/23S spacer showed an Ala-tRNA intervening sequence, which is a common feature in Euryarchaeota. Sequence analysis of 23S rRNA and 16S rRNA was performed for the six organisms from the family Halobacteriaceae with both available gene sequences. Phylogenetic trees with completely different topology were obtained using both molecules.

The archaeal halophilic virus-encoded Dam-like methyltransferase M. phiCh1-I methylates adenine residues and complements dam mutants in the low salt environment of Escherichia coli

The genome of the archaeal virus phiCh1, infecting Natrialba magadii (formerly Natronobacterium magadii), is composed of 58.5 kbp linear ds DNA. Virus particles contain several RNA species in sizes of 100-800 nucleotides. A fraction of phiCh1 genomes is modified within 5'-GATC-3' and related sequences, as determined by various restriction enzyme digestion analyses. High performance liquid chromatography revealed a fifth base, in addition to the four nucleosides, which was identified as N6-methyladenosine. Genetic analyses and subsequent sequencing led to the identification of a DNA (N6-adenine) methyltransferase (mtase) gene. The protein product was designated M.phiCh1-I. By the localization of the most conserved motifs (a DPPY motif occurring before FxGxG), the enzyme was placed within the beta-subgroup of the (N6-adenine) methyltransferase class. The mtase gene of phiCh1 was classified as a 'late' gene, as determined by measuring the kinetics of mRNA and protein expression in N. magadii during the lytic cycle of phiCh1. After infection of cells, M.phiCh1-I mRNA and protein could be detected in lower amounts than in the situation of virus induction from lysogenic cells. Consequently, only about 5% of the phiCh1 progeny genomes after infection of N. magadii carry the M.phiCh1-I methylation in contrast to 50% of virus genomes generated by induction of phiCh1-lysogenic N. magadii cells. Heterologous expression of the mtase from a halophile with 3 M cytoplasmic salt concentration showed an unexpected feature: the protein was active in the low environment of Escherichia coli and was able to methylate DNA in vivo. Interestingly, it seemed to exhibit a higher sequence specificity in E. coli that resulted in adenine methylation exclusively in the sequence 5'-GATC-3'. Additionally, expression of M.phiCh1-I in dam- E. coli cells led to a complete substitution of the function of M. Dam in DNA mismatch repair.

Amino acid biosynthesis in the halophilic archaeon Haloarcula hispanica

Biosynthesis of proteinogenic amino acids in the extremely halophilic archaeon Haloarcula hispanica was explored by using biosynthetically directed fractional 13C labeling with a mixture of 90% unlabeled and 10% uniformly 13C-labeled glycerol. The resulting 13C-labeling patterns in the amino acids were analyzed by two-dimensional 13C,1H correlation spectroscopy. The experimental data provided evidence for a split pathway for isoleucine biosynthesis, with 56% of the total Ile originating from threonine and pyruvate via the threonine pathway and 44% originating from pyruvate and acetyl coenzyme A via the pyruvate pathway. In addition, the diaminopimelate pathway involving diaminopimelate dehydrogenase was shown to lead to lysine biosynthesis and an analysis of the 13C-labeling pattern in tyrosine indicated novel biosynthetic pathways that have so far not been further characterized. For the 17 other proteinogenic amino acids, the data were consistent with data for commonly found biosynthetic pathways. A comparison of our data with the amino acid metabolisms of eucarya and bacteria supports the theory that pathways for synthesis of proteinogenic amino acids were established before ancient cells diverged into archaea, bacteria, and eucarya.

Phylogenetic analyses of some extremely halophilic archaea isolated from Dead Sea water, determined on the basis of their 16S rRNA sequences

Twenty-two extremely halophilic aerobic archaeal strains were isolated from enrichments prepared from Dead Sea water samples collected 57 years ago. The isolates were phenotypically clustered into five different groups, and a representative from each group was chosen for further study. Almost the entire sequences of the 16S rRNA genes of these representatives, and of Haloarcula hispanica ATCC 33960, were determined to establish their phylogenetic positions. The sequences of these strains were compared to previously published sequences of 27 reference halophilic archaea (members of the family Halobacteriaceae) and two other archaea, Methanobacterium formicicum DSM 1312 and Methanospirillum hungatei DSM 864. Phylogenetic analysis using approximately 1,400 base comparisons of 16S rRNA-encoding gene sequences demonstrated that the five isolates clustered closely to species belonging to three different genera--Haloferax, Halobacterium, and Haloarcula. Strains E1 and E8 were closely related and identified as members of the species Haloferax volcanii, and strain E12 was closely related and identified as a member of the species Halobacterium salinarum. However, strains E2 and E11 clustered in the Haloarcula branch with Haloarcula hispanica as the closest relative at 98.9 and 98.8% similarity, respectively. Strains E2 and E11 could represent two new species of the genus Haloarcula. However, because strains of these two new species were isolated from a single source, they will not be named until additional strains are isolated from other sources and fully characterized.

Characterization and phylogeny of mcrII, a gene cluster encoding an isoenzyme of methyl coenzyme M reductase from hyperthermophilic Methanothermus fervidus

A 5.7 kb region of chromosomal DNA from Methanothermus fervidus, harbouring a second mcr gene cluster, was cloned and sequenced. This gene cluster, termed mcrII, encodes an isoenzyme of methyl coenzyme M reductase (MCR). In contrast to the known mcr gene clusters from other methanogens, mcrII lacks mcrC, a gene of unknown function. But the remaining mcrII genes B, D, G and A are arranged in the same order as in previously sequenced mcr gene clusters. The mcrII genes from M. fervidus are located 3' to the open reading frame (ORF) B of the methylviologen-reducing hydrogenase (mvh) gene cluster. The genes of mcrII are cotranscribed, resulting in an mRNA of 4500 nucleotides. The transcriptional initiation and termination sites were identified. Phylogenetic reconstructions reveal that the mcr gene clusters fall into two different types, I and II, and that the ancestral mcr gene cluster was duplicated before the segregation of methanogens into three major orders occurred.

Partial sequence of the gene for a serine protease from a halophilic archaeum Haloferax mediterranei R4, and nucleotide sequences of 16S rRNA encoding genes from several halophilic archaea

A part of the gene coding for a halophilic serine protease from a halophilic archaeum Haloferax mediterranei R4 was amplified by PCR and its 672 nucleotide sequence was determined. Tentative translation to the amino acid sequence suggested that the enzyme was quite similar to halolysin produced by another halophilic archaeum strain 172P1. Nucleotide sequences of 16S rRNA encoding genes from 9 halophilic archaea were determined. Alignment of 19 sequences known so far showed that there are more than 20 positions carrying bases or deletions specific for each halobacterial genus: Halobacterium, Haloarcula, Haloferax, and Halococcus.