Susana Benlloch

Salinibacter ruber gen. nov., sp. nov., a novel, extremely halophilic member of the Bacteria from saltern crystallizer ponds

Five brightly red-pigmented, motile, rod-shaped, extremely halophilic bacteria were isolated from saltern crystallizer ponds in Alicante (two strains) and Mallorca (three strains), Spain. They grew optimally at salt concentrations between 20 and 30% and did not grow below 15% salts. Thus, these isolates are among the most halophilic organisms known within the domain Bacteria. The temperature optimum was 37-47 degrees C. A single, yet to be identified pigment was present, with an absorption maximum at 482 nm and a shoulder at 506-510 nm. The G+C content of the DNA was 66.3-67.7 mol% and, together, they formed a homogeneous genomic group with DNA-DNA similarities above 70%. The 16S rRNA gene sequences were almost identical to sequences recovered earlier from the saltern biomass by amplification of bacterial small-subunit rRNA genes from DNA extracted from the environment. This phylotype, earlier described as Candidatus Salinibacter, was shown by fluorescence in situ hybridization to contribute between 5 and 25% of the prokaryote community of the saltern crystallizers. We have therefore succeeded in isolating a bacterium from the natural environment that, although being a major component of the community, was previously known by its phylotype only. Isolation of the organism now allows formal description of a novel genus and species, for which we propose the name Salinibacter ruber gen. nov., sp. nov. The type strain is strain M31T (= DSM 13855T = CECT 5946T).

Archaeal Biodiversity in Crystallizer Ponds from a Solar Saltern: Culture versus PCR

The culturable haloarchaeal diversity in a crystallizer pond from a solar saltern has been analyzed and compared with the biodiversity directly retrieved by analysis of rRNA genes amplified from the environment. Two different sets of culture conditions have been assayed: solid medium with yeast extract as carbon source and liquid media with either yeast extract or a mixture of fishmeal, Spirulina sp., and Artemia salina. Seventeen colonies grown on plates with yeast extract incubated at 30°C were analyzed by 16S rDNA partial sequencing. Sixteen were closely related to haloarchaea of the genus Halorubrum; 13 of them to Halorubrum coriense, a haloarchaeon isolated from a solar saltern pond in Australia, which had not been previously isolated from the pond analyzed in this study; and one to Haloarcula marismortui. Liquid cultures were analyzed by ribosomal internal spacer analysis (RISA) and partial sequencing of the 16SrRNA genes. A total of 18 sequences were analyzed, 15 corresponding to RISA bands obtained from cultures, and 3 from the environmental sample used as inoculum. Thirteen sequences obtained from cultures were related to several Halorubrum species, and 2 to Haloarcula. One of the clones obtained directly from the environmental sample was distantly related to a Natronobacterium, whereas two were related to SPhT, the phylotype most frequently retrieved from this environment by culture independent techniques. Our results show an extremely low diversity for the haloarchaea retrieved by cultivation even when modifications to the standard technique are introduced.

Sequencing of Bacterial and Archaeal 16S rRNA Genes Directly Amplified from a Hypersaline Environment

Summary The new methods based on PCR amplification and sequencing of 16S rRNA genes from DNA samples extracted directly from the environment allow the description of microbial diversity in natural ecosystems without the need for cultivation. We have applied this technique to an extreme environment presumed to have very low diversity: the crystallizer ponds of a marine saltern (salinity over NaCl saturation). The molecular methodology has shown that indeed very low diversity can be found here. Bacteria (formerly eubacteria) are largely minoritary, and only a cluster of closely related sequences was found, all distant relatives of the α-Proteohacteria (82% to Rhodopseudoinonas marina). Halophilic Archaea were shown by hybridization to be, as expected, the largest component of biomass in this environment. All the archaeal clones sequenced again were highly similar to each other suggesting that they are probably members of the same genus. However, all the sequences diverged considerably from those of the described genera of halophilic Archaea. In fact the data are consistent with the idea that the 16S rDNA genes directly amplified from the saltern correspond to members of an undescribed genus which seems to be abundant in the sample. This is remarkable since many collection strains sequenced come specifically from this same saltern. Furthermore, 16S rDNA obtained from archaeal cultures isolated from the same sample had no homology to the sequences obtained by PCR amplification, instead they appear to be members of the well known genus Haloarcula. However, this is in agreement with the findings of other authors who by culture have obtained organisms different from those indicated by the sequences retrieved directly by PCR. Possible explanations are discussed.

Prokaryotic Diversity in Zostera noltii-Colonized Marine Sediments

ABSTRACT The diversity of microorganisms present in a sediment colonized by the phanerogam Zostera noltii has been analyzed. Microbial DNA was extracted and used for constructing two 16S rDNA clone libraries for Bacteria and Archaea. Bacterial diversity was very high in these samples, since 57 different sequences were found among the 60 clones analyzed. Eight major lineages of the Domain Bacteria were represented in the library. The most frequently retrieved bacterial group (36% of the clones) was δ-Proteobacteria related to sulfate-reducing bacteria. The second most abundant group (27%) was γ-Proteobacteria, including five clones closely related to S-oxidizing endosymbionts. The archaeal clone library included members of Crenarchaeota and Euryarchaeota, with nine different sequences among the 15 analyzed clones, indicating less diversity when compared to the Bacteria organisms. None of these sequences was closely related to culturedArchaea organisms.

Intragenomic 16S rDNA Divergence in Haloarcula marismortui Is an Adaptation to Different Temperatures

The halophilic archaeon Haloarcula marismortui contains three ribosomal RNA operons, designated rrnA, rrnB, and rrnC. Operons A and C are virtually identical, whereas operon B presents a high divergence in nucleotide sequence, having up to 135 nucleotide polymorphisms among the three 16S, 23S, and 5S ribosomal RNA genes. Quantitative PCR and structural analyses have been performed to elucidate whether the presence of this intragenomic heterogeneity could be an adaptation to the variable environmental conditions in the natural habitat of H. marismortui. Variation in salt concentration did not affect expression but variation in incubation temperature did produce significant changes, with operon B displaying an expression level four times higher than the other two together at 50°C and three times lower at 15°C. We show that the putative promoter region of operon B is also different. In addition, the predicted secondary structure of these genes indicated that they have distinct stabilities at different temperatures and a mutant strain lacking operon B grew slower at high temperatures. This study supports the idea that divergent rRNA genes can be adaptive, with different variants being functional under different environmental conditions (e.g., temperature). The same phenomenon could take place in other halophiles or thermophiles with intragenomic rDNA heterogeneity, where the use of 16S rDNA as a phylogenetic marker and indicator of biodiversity should be used with caution.

Description of prokaryotic biodiversity along the salinity gradient of a multipond solar saltern by direct PCR amplification of 16S rDNA

New methods based on PCR amplification of 16S rRNA genes from DNA samples extracted directly from the environment allow the description of microbial diversity in natural ecosystems without the need for cultivation. We have applied this technique to an extreme environment presumed to have very low diversity: the crystallizer ponds of a marine saltern with salinity over NaCl saturation. The molecular methodology has shown that indeed very low diversity can be found here. Prokaryotes belonging to the Bacteria domain are a minor component and only members of a closely related cluster of sequences were found, all relatives of the α-Proteobacteria (ca. 83% to Rhodopseudomonas marina). Halophilic Archaea were as expected the largest component of biomass in this environment. All the clones sequenced corresponded again to a highly homologous cluster (probably members of the same genus). However, all the sequences diverged considerably from the ones of the described genera of halophilic Archaea, in fact the data are consistent with the idea that the 16S rRNA genes directly amplified from the saltern correspond to members of an undescribed genus. This is remarkable since many collection strains sequenced come specifically from this saltern. Furthermore, 16S rDNA obtained from archaeal cultures isolated from the same sample had no homology to the sequences obtained by PCR amplification, instead they appear to be members of the well known genus Haloarcula. However, this concurs with the findings of other authors who obtained different organisms by culture from those detected by the sequences retrieved directly by PCR. A possible explanation is that culturability, in standard media, is the exception rather than the rule. To study the biodiversity gradient present along the salinity gradient found in a multi-pond solar saltern we have also applied a novel molecular strategy. This method is based on the restriction digestion of a population of 16S rDNA sequences directly amplified from an environmental sample. Digested fragments separated by polyacrylamide gel electrophoresis generate characteristic profile data for estimation of diversity and overall similarities between the organisms of different environments. The methodology has been applied to a set of five ponds covering the salinity gradient from about twice that of seawater (6.4%) to NaCI precipitation (30.8%). Bacterial (eubacterial) diversity estimated from the complexity of the banding pattern obtained by restriction of the amplicons from the different ponds decreased with increasing salinity while for Archaea (archaebacteria) the reverse was true i.e. the higher the salinity the higher the number of bands. The similarities in taxonomic composition of the prokaryotic populations present in those ponds were evaluated from the number of restriction bands shared by the different samples. The relationships found among the different environments were independent of the enzyme used for digestion and were consistent with previous descriptions obtained by the study of isolates from the different environments. This technique appears to be promising as a rapid method for microbial biodiversity fingerprinting useful to compare several environments and detect major shifts in species composition of the microbial population.

Thalassospira lucentensis gen. nov., sp. nov., a new marine member of the alpha-Proteobacteria.

A novel bacterium from the Mediterranean Sea was isolated under oligotrophic conditions at in situ temperature after prolonged continuous culture. The isolates were initially characterized by partial 16S rRNA gene sequencing. Similarity searches of one of the isolates, QMT2T, indicated high sequence identity to the well-characterized Rhodospirillum rubrum, [Aquaspirillum] itersonii and [Oceanospirillum] pusillum micro-organisms, which are representatives of the alpha-subclass of the Proteobacteria. The highest level of similarity of the complete 165 rRNA gene with respect to these microorganisms was 89%. Features such as the low similarities of 165 rRNA of QMT2T with its phylogenetically close neighbours, the distinct G+C content, and the differences in phenotypic features, including pigmentation, fatty acid composition, salt tolerance, the lack of bacteriochlorophyll a, and the capacity to use carbohydrates as carbon sources, are indicative of the novel nature of the isolate QMT2T among the alpha-Proteobacteria. This report describes the classification of strain QMT2T (= DSM 14000T = CECT 5390T) as a new genus and species, Thalassospira lucentensis gen. nov, sp. nov., in the family Rhodospirillaceae.

Red, Extremely Halophilic, but not Archaeal: The Physiology and Ecology of Salinibacter ruber, a Bacterium Isolated from Saltern Crystallizer Ponds

Solar saltern evaporation ponds, found in many locations worldwide in subtropical and tropical coastal areas, provide us with excellent model systems for the study of microbial processes at high salt concentrations.In multi-pond saltern environments a broad range of salt concentrations is found, increasing from seawater (around 35 g dissolved salts per liter) to brines with salt concentrations exceeding 350 g l−1 (see, e.g., Rodriguez-Valera et al. 1981; Oren 1993; Litchfield et al. 2000). Many of the halophilic and halotolerant microorganisms in culture have been isolated from such salterns, and considerable efforts have been devoted toward the understanding of the microbial transformations in the water and the sediments of saltern evaporation and crystallizer ponds (Javor 1989; Oren 1993).

Heterotrophic bacteria, activity and bacterial diversity in two coastal lagoons as detected by culture and 16S rRNA genes PCR amplification and partial sequencing

Activity and numbers of heterotrophic bacteria have indicated that, as expected, Prevost Lagoon is more eutrophic than Arcachon Bay. Amplification and sequence analysis of the 16S rRNA genes from DNA samples extracted directly from the environment allow the determination of phylogenetic relationships among members of microbial communities in natural ecosystems without the need for cultivation. Analysis of partial 16S rRNA gene sequences obtained from Stations A and 11 revealed that, in both environments, a relatively large number of clones related to Cytophaga/FlexibacterBacteroides as well as to α-Proteobacteria were found. One hundred percent similarity with the sequences of the data bases were not found for any of the more than a hundred clones studied. In fact for most clones maximum similarity was below 95% for the nucleotide series sequenced. Similarity was not higher with any of the sequences found for the 14 isolates (pure cultures) obtained from the same samples. Redundancy, i.e. number of identical sequences, was higher in the samples from Arcachon. In addition, sequences related to representatives of ten major phylogenetic branches of Eubacteria were obtained from Prevost Lagoon, however only five branches were represented by the data from Arcachon. These findings indicate a higher bacterial diversity in Prévost Lagoon.