The alpha-operon equivalent genome region in the extreme halophilic archaebacterium Haloarcula (Halobacterium) marismortui

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.

Cloning, sequencing, and characterization of ribosomal protein and RNA polymerase genes from the region analogous to the alpha-operon of escherichia coli in halophilic archaea, halobacterium halobium

A determination was made of the nucleotide sequence of the 3215-bp region of a ribosomal protein gene cluster (HS13, HS4, HS11, and HeL18), RNA polymerase (RNA poly D), and tRNA genes (tRNAser and tRNAarg) of halophilic Archaea Halobacterium halobium, which is analogous to the alpha-operon of Escherichia coli (tRNAser-HS13-HS4-HS11-RNA poly D-tRNAarg-HeL18). The seven-gene string was preceded by a pseudoknot-like structure similar to the proposed S4 ribosomal protein binding site of the alpha-operon mRNA leader in E. coli. Using an inducible expression system H. halobium HS4 was produced in large amounts in E. coli, and immunoblot analysis showed the S4 to constitute a 21-kDa polypeptide component of the ribosome. Analysis of the deduced amino acids sequence revealed that the HS13, HS4, and HS11 sequences including the RNA polymerase subunit are more similar to their eukaryotic than to their bacterial counterparts. HeL18, located downstream of the gene cluster analogous to the E. coli alpha-operon (S13-S11-S4-RNA poly D-L17), was similar to both the eukaryotic (eL18) and eubacterial ribosomal protein L15 located in the spc-operon, but not to L17 positioned as the terminal gene of the bacterial alpha-operon.

Transcription analysis of two disparate rRNA operons in the halophilic archaeon Haloarcula marismortui

The genome of the halophilic archaeon Haloarcula marismortui contains two rRNA operons designated rrnA and rrnB. Genomic clones of the two operons and their flanking regions have been sequenced, and primary transcripts and processing intermediates derived from each operon have been characterized. The 16S, 23S, and 5S genes from the two operons were found to differ at 74 of 1,472 positions, 39 of 2,922 positions, and 2 of 122 positions, respectively. This degree of sequence divergence for multicopy (paralogous) rRNA genes was 10- to 50-fold or more higher than anticipated. The two operons exhibit other profound differences that include (i) the presence in rrnA and the absence in rrnB of tRNAAla and tRNACys genes in the intergenic and distal regions, respectively, (ii) divergent 5' flanking sequences, and (iii) distinct pathways for processing and maturation of 16S rRNA. Processing and maturation of 16S and 23S rRNA from rrnA operon transcripts and of 23S rRNA from rrnB operon transcripts follow the canonical halophilic pathway, whereas maturation of 16S rRNA from rrnB operon transcripts follows an unusual and different pathway that is apparently devoid of any 5' processing intermediate.

Cartography of ribosomal proteins of the 30S subunit from the halophilic Haloarcula marismortui and complete sequence analysis of protein HS26

By two-dimensional polyacrylamide gel electrophoresis of 30S ribosomal subunit proteins (S proteins) from Haloarcula marismortui we identified 27 distinct spots and analyzed all of them by protein sequence analysis. We demonstrated that protein HmaS2 (HS2) is encoded by the open reading frame orfMSG and has sequence similarities to the S2 ribosomal protein family. The proteins HmaS5 and HmaS14 were identified as spots HS7 and HS21/HS22, respectively. Protein HS4 was characterized by amino-terminal sequence analysis. The spot HS25 was recognized as an individual protein and also characterized by sequence analysis. Furthermore, the complete primary sequence of HS26 is reported, showing similarity only to eukaryotic ribosomal proteins. The sequence data of a further basic protein shows a high degree of similarity to ribosomal protein S12, therefore, it was designated HmaS12. Slightly different results compared to published sequence data were obtained for the protein HS12 and HmaS19. The putative 'ribosomal' protein HSH could not be localized in the two-dimensional pattern of the total 30S ribosomal subunit proteins of H. marismortui. Therefore, it seems to be unlikely that this protein is a real constituent of the H. marismortui ribosome.

In vivo definition of an archaeal promoter

We have used a plasmid-based transcriptional reporter system to examine the transcriptional effects of 33 single point mutations in the box A region (TATA-like sequence) of the Haloferax volcanii tRNA(Lys) promoter. The most pronounced effects on transcriptional efficiency were found when the nucleotides corresponding to the TATA-like region were altered. Promoters with wild-type or higher levels of transcriptional activity conformed to the general archaeal box A consensus, 5'-T/CTTAT/AA-3'. The preference for a pyrimidine residue in the 5' position of this region and the exclusion of guanine and cytosine in the next four positions in the 3' direction are defining characteristics shared by all efficient archaeal promoters. We have also observed that replacement of a 10-nucleotide purine-rich sequence, located 5' of the H. volcanii tRNA(Lys) box A element, completely abolished transcription from this promoter. These data show that the H. volcanii tRNA(Lys) promoter is dependent on two separate, and essential, sequence elements. The possible functions of these sequences, in view of the recent descriptions of eucaryal-like transcription factors for Archaea, are discussed.

Halobacterial S9 operon contains two genes encoding proteins homologous to subunits shared by eukaryotic RNA polymerases I, II, and III

One key component of the eukaryotic transcriptional apparatus is the multisubunit enzyme RNA polymerase II. We have discovered that two of the subunits shared by the three nuclear RNA polymerases in the yeast Saccharomyces cerevisiae, RPB6 and RPB10, have counterparts among the Archaea.

The Drosophila melanogaster homolog of ribosomal protein S18

The sequence of the cDNA encoding the Drosophila melanogaster homolog of the human and rat small-subunit ribosomal protein, S18 (rpS18), is presented. The deduced 152-amino-acid (aa) sequence exhibits 76% identity to that of the human and rat rpS18 (152 aa), and is, like them, a member of the larger rpS13 family which includes archaebacterial, eubacterial and plant mitochondrial (mt) rpS13. The D. melanogaster rpS18 gene is single copy and maps at 56F, a chromosome region encompassing a previously characterised Minute locus, M(2)56F. The rpS18 gene gives rise to a single 700-nucleotide transcript present throughout development. A comparison of the rpS13 family members suggests that conservation is greatest at the N- and C-termini, whilst additional insertions are present in the Drosophila, mammalian and archaebacterial proteins relative to the eubacterial and plant mt proteins.

N-terminal modification and amino-acid sequence of the ribosomal protein HmaS7 from Haloarcula marismortui and homology studies to other ribosomal proteins

The ribosomal protein HmaS7 from the 30S subunit of the extreme halophilic archaeum Haloarcula marismortui was isolated by semi-preparative RP-HPLC. The complete amino-acid sequence of this protein was determined by automated microsequence analysis of appropriate peptide fragments from several proteinase digests. The entire protein consists of 205 amino acids with a corresponding molecular mass of 22580 Da. The modification at the amino-terminal amino acid was deblocked so that the N-terminal amino acids could be sequenced and the type of the modification was identified as an acetyl group by electrospray mass spectrometry of suitable peptides. Homology studies of HmaS7 showed similarities to ribosomal proteins derived from organisms of all three urkingdoms, such as to EcoS7, HmoS7, MvaS7, SacS7 and RatS7; due to the strong sequence homologies found within the archaebacterial ribosomal proteins we conclude that the protein sequence which was determined for S7 from Methanococcus vannielii by nucleotide sequencing of the gene should be about 20 or 30 amino acids longer than previously published (Lechner, K., Heller, G. & Böck, A. (1989) J. Mol. Evol. 29, 20-27).

Nucleotide sequence of the genes for ribosomal proteins HS15 and HSH from Haloarcula marismortui: an archaeon-specific gene cluster

The nucleotide sequences of the genes for two ribosomal proteins, HS15 and HSH, from the archaeon Haloarcula marismortui, have been determined. The genes were found in a cluster together with another open reading frame with a probable regulatory function. HS15 and HSH have counterparts in eucarya. HS15 is significantly homologous to S19 from frog (Xenopus laevis). HSH is related to S37 from yeast (Saccharomyces cerevisiae) and S27 from fly (Drosophila melanogaster), as well as to other members of the S27 family. Eubacterial counterparts were not found, suggesting that these proteins are 'extra proteins' that are absent in eubacterial ribosomes.