Very stable enzymes from extremely thermophilic archaebacteria and eubacteria

Summary Thirty-six thermophilic archaebacteria and nine extremely thermophilic eubacteria have been screened on solid media for extracellular amylase, protease, hemicellulase (xylanase), cellulase, pectinase and lipase activities. Extracellular enzymes were detected in 14 archaebacteria belonging to three different orders. Twelve of these were able to degrade starch and casein and the two Thermofilum strains were able to degrade starch, xylan and carboxymethylcellulose. Three of the eubacteria could degrade only starch. The other six (including four Thermotoga strains) all had activity against starch, xylan and carboxymethylcellulose, and one also had activity against casein. Some of the amylolytic archaebacteria released -glucosidase, -glucosidase, amylase and transglucosylase activities into liquid media containing starch or maltose. Thermotoga strain FjSS3B.1 released amylase, xylanase, cellulase and -glucosidase activities into the medium when grown in the presence of substrates. When the partially purified enzymes from Thermotoga and some of the archaebacteria were compared with known thermostable enzymes the majority were found to be the most thermostable of their type. The -glucosidase, xylanase and cellulase from Thermotoga and two -glucosidases, a -glucosidase, an amylase and a pullulanase from archaebacteria all have half-lives of at least 15 min at 105°C.     

DNA substrate specificity of reverse gyrase from extremely thermophilic archaebacteria

It has been shown earlier that eukaryotic type I DNA topoisomerases act on duplex DNA regions, while eubacterial type I topoisomerases require single-stranded regions. The present paper demonstrates that the type I topoisomerase from extremely thermophilic archaebacteria, reverse gyrase, winds DNA by binding to single-stranded DNA regions. Thus, type I topoisomerases, both relaxing one in eubacteria and reverse gyrase in extremely thermophilic archaebacteria share a substrate specificity to melted DNA regions. The important consequence of this specificity is that the cellular DNA superhelical stress actively controlled by bacterial topoisomerases is confined to a narrow range characterized by a low stability of the double helix. Hence we suppose that bacterial topoisomerase systems control duplex stability near its minimum, for which purpose they create an appropriate negative superhelicity at moderate temperatures or a positive one at extremely high temperatures, the feedback being ensured by the aforesaid specificity of type I bacterial topoisomerases.     

Thermococcus litoralis sp. nov.: A new species of extremely thermophilic marine archaebacteria

We describe a new species, Thermococcus litoralis, which is different from the type species Thermococcus celer in molecular, morphological and physiological characteristics.Abbreviations 3 x SSC (standard saline citrate) - 0.45 M NaCl 0.045 M Na₃-citrate     

Pyrite oxidation by thermophilic archaebacteria.

Three species of thermophilic archaebacteria of the genera Sulfolobus (Sulfolobus acidocaldarius and S. solfataricus) and Acidianus (Acidianus brierleyi) were tested for their ability to oxidize pyrite and to grow autotrophically on pyrite, to explore their potential for use in coal desulfurization. Only A. brierleyi was able to oxidize and grow autotrophically on pyrite. Jarosite was formed during the pyrite oxidation, resulting in the precipitation of sulfate and iron. The medium composition affected the extent of jarosite formation.     

Aminoglycoside-induced mistranslation in thermophilic archaebacteria

Summary The effect of selected aminoglycoside antibiotics on the translational accuracy of poly(U) programmed ribosomes derived from the thermophilic archaebacteria Thermoplasma acidophilum, Sulfolobus solfataricus, Thermococcus celer and Desulfurococcus mobilis has been determined. Under optimum temperature and ionic conditions for polyphenylalanine synthesis, the four species investigated are found to be markedly diverse in their response to the miscoding-inducing action of aminoglycoside antibiotics. T. acidophilum is sensitive to all of the compounds tested except streptomycin; S. solfataricus responds to paromomycin and to hygromycin B; T. celer is only affected by neomycin, and D. mobilis is refractory to all drugs. The only feature shared by the four species under study, and by all archaebacteria so far investigated, is their complete insensitivity to streptomycin. The structural and phylogenetic implications of the remarkable diversity encountered among archaebacterial ribosomes in their susceptibility to aminoglycosides are discussed.     

Pyrite oxidation by thermophilic archaebacteria

Three species of thermophilic archaebacteria of the genera Sulfolobus (Sulfolobus acidocaldarius and S. solfataricus) and Acidianus (Acidianus brierleyi) were tested for their ability to oxidize pyrite and to grow autotrophically on pyrite, to explore their potential for use in coal desulfurization. Only A. brierleyi was able to oxidize and grow autotrophically on pyrite. Jarosite was formed during the pyrite oxidation, resulting in the precipitation of sulfate and iron. The medium composition affected the extent of jarosite formation.     

Isolation and characterization of extremely thermophilic archaebacteria related to the genus Thermococcus from deep-sea hydrothermal guaymas basin

During the Guaynaut oceanographic cruise performed by IFREMER in November 1991, sediment cores were collected from high-temperature and petroleum-rich deposits in an active hydrothermal zone, at the Guaymas basin (Central gulf of California). Those samples were collected by the French deep-sea manned submersible Nautile at a depth of 2000 meters. Four sediment cores of 20–40-cm length were drilled at the bottom of a block assemblage of active smokers inside sediments whose temperatures were 3.5°C on the top to 105°C at 20 cm depth. They were subsampled in 22 slices of 5-cm thickness and used for isolation of heterotrophic hyperthermophilic microorganisms, after inoculation in sulfur-free SME liquid medium. From those enrichments 18 isolates were obtained, 2 growing at 95°C and 16 at 80°C, and their taxonomic characterization was undertaken. Lipid analysis indicated the presence of diethers and tetraethers in the cell walls and membranes, characteristic of Archaebacteria. Examinations by scanning electron microscopy showed that isolates were cocci of heterogeneous sizes (diameter from 0.1 to 0.5 micrometers) or thick, piled-up discs 0.5 m thick and 1 m in diameter. Both forms were embedded in a dense fiber network. Physiologically they were found to be anaerobic, heterotrophic, and hyperthermophilic (80°–95°C). Determination of the DNA base composition resulted in G + C mol % values ranging from 36 to 57. Qualitative hybridizations of the 18 isolate DNAs with hyperthermophilic Archaebacteria reference strain DNAs showed that hybridizations occurred neither with the two species of Pyrococcus nor with the two species of Desulfurococcus, nor with Staphylothermus marinus. On the other hand, all isolates hybridized with at least one of the three species of Thermococcus tested (T. celer, T. stetteri, T. litoralis). Restriction polymorphism on a PCR-amplified fragment of the rrn operon showed that 12 isolates had the same profile as T. celer and T. stetteri, 4 isolates had the same profile as T. litoralis, and 2 had new profiles, suggestive that they are new species.     

Emulsifying activity in thermophilic and extremely thermophilic microorganisms

Thermophilic and extremely thermophilic enrichments from several different environments produced cell-associated emulsifiers as did several pure cultures ofArchaea. The bioemulsifiers were effective over a wide range of pH, at NaCl concentrations up to 200 g L^–1, and at temperatures up to 80°C. The emulsifying activity in cell-free extracts ofMethanobacterium thermoautotrophicum was a cell-associated protein with a molecular weight greater than 5000 Da. This emulsifier formed viscous emulsions, but did not reduce the surface tension of water or the interfacial tension between water and hexadecane. The emulsifier had the greatest activity with alkanes with carbon numbers greater than 10. The characteristics of the bioemulsifier fromM. thermoautotrophicum makes it suitable for use in saline or thermophilic oil reservoirs as a mobility control agent or in well-bore clean up processes.     

Glucose transport into the extremely halophilic archaebacteria

Penetration of glucose into cells of several extremely halophilic archaebacteria of the Halobacterium and Haloferax genera (Halobacterium saccharovorum and Halobacterium salinarium, Haloferax volcanii and Haloferax mediterranei) has been studied. Some characteristics of transport systems of carbohydrate-utilizing halobacteria Halobacterium saccharovorum, Haloferax mediterranei and Haloferax volcanii (pH and temperature optima, stereospecificity, kinetic parameters) have been determined. Inability of H. salinarium cells for active glucose transport has been shown. The dependence of glucose transport on the Na⁺ ions gradient (on the whole cells and membrane vesicles) has been demonstrated. Cells or membrane vesicles of carbohydrate-utilizing halobacteria grown in media containing this sugar indicated the activation of glucose transport, whereas cells grown in media without sugars did not. This fact has allowed us to conclude that corresponding transport systems are inducible.     

Mitochondrial ribosome assembly in Neurospora crassa: mutants with defects in mitochondrial ribosome assembly.

Summary We have examined mitochondrial (mt) ribosome assembly and-function in five nuclear and six extranuclear mutants of Neurospora crassa which had previously been characterized as deficient in cytochromes b and aa ₃. All six extranuclear mutants showed phenotypes similar to that previously described for the extranuclear [poky] mutant: small subunit-deficient with 19 S rRNA rapidly degraded. The nuclear mutants have the following phenotypes: 297-24 is mt small subunit deficient with 19 S RNA rapidly degraded. 289-56 is mt small subunit deficient but contains normal ratios of 19 S to 25 S RNA in whole mitochondria. 289-67 and 299-9 show defects in the processing of 25 S RNA leading to accumulation of a large precursor RNA. 289-4 is deficient in large subunits although a substantial, but less than normal, amount of 25 S RNA is present in the mitochondria.The present work provides new insight into the phenotypes of mt small subunit-deficient mutants. Previous studies using chloramphenicol suggest that some defects in the assembly of mt small subunits may arise secondarily as a result of inhibition of mt protein synthesis (LaPolla and Lambowitz, 1977; Lambowitz et al., 1979). Three mutants (289-56, 289-67 and 299-9) appear to show such defects. These strains contain incomplete mt small subunits which sediment more slowly than normal and are deficient in at least two proteins, S-5 and S-9. Correlation of mutant phenotypes with rates of mt protein synthesis in the different strains suggests that mt protein synthesis must be decreased to less than one half of the wild-type rate before secondary defects in mt small subunit assembly are observed. This threshold value is much lower than that which leads to gross deficiencies of cytochromes b and aa ₃. Although several mutants have phenotypes suggestive of alterations in mt ribosomal proteins, no such alterations could be identified by two dimensional gel electrophoresis.     

Tolerance of extremely halophilic archaebacteria towards bromide

The tolerance of halophilic archaebacteria towards bromide was tested in view of the fact that bromide occurs in natural brines in concentrations of up to 66 mM. It was found that, while concentrations of up to 0.8–1M are tolerated well by all halobacterial types examined, great differences exist between species with respect to bromide tolerance. WhileHalobacterium (H. salinarium, H. halobium, andH. sodomense) andNatronobacterium species are only moderately tolerant,Haloarcula (H. vallismortis, H. marismortui), andHaloferax species (H. mediterranei, H. gibbonsii) tolerate higher concentrations.Haloferax volcanii proved extremely tolerant and showed growth in bromide media at very low chloride concentrations (below 50 mM). No correlation was found between bromide tolerance and the bromide concentration in the habitat from which the strains were isolated. Iodide proved much more toxic than bromide. Bromide-tolerant strains also proved relatively resistant to growth inhibition by iodide.     

Comparison of plasmid DNA topology among mesophilic and thermophilic eubacteria and archaebacteria.

Several plasmid DNAs have been isolated from mesophilic and thermophilic archaebacteria. Their superhelical densities were estimated at their host strain's optimal growth temperature, and in some representative strains, the presence of reverse gyrase activity (positive DNA supercoiling) was investigated. We show here that these plasmids can be grouped in two clusters with respect to their topological state. The group I plasmids have a highly negatively supercoiled DNA and belong to the mesophilic archaebacteria and all types of eubacteria. The group II plasmids have DNA which is close to the relaxed state and belong exclusively to the thermophilic archaebacteria. All archaebacteria containing a relaxed plasmid, with the exception of the moderately thermophilic methanogen Methanobacterium thermoautotrophicum Marburg, also exhibit reverse gyrase activity. These findings show that extrachromosomal DNAs with very different topological states coexist in the archaebacterial domain.     

Chaperoning ribosome assembly

Reconstitution of bacterial ribosomes in vitro from RNA and protein constituents requires a heating step to rearrange conformation of an intermediate. In this issue of Molecular Cell, Maki et al. demonstrate that the DnaK chaperone system circumvents the requirement for heating.     

Acdidophilic thermophilic archaebacteria: Potential application for metals recovery

Abstract The acidophilic thermophilic archaebacteria Sulfolobus and Acidianus have the potential for applid use in the recovery of metal values from ores through the process of baterial leaching. These microbes readily adapt to the conditions of low pH and high concentrations of metals required for bacterial leaching. In addition, these archaebacteria can exist at high temperatures which can occur during the oxidation of metal sulfides in bioleaching reactors. The acidophilic of copper and molybdenum from chalcopyrite and molybdenite minerals, respectively. The microbes can also enhance the recovery of gold by oxidation of pyrite which occludes gold preventing recovery by standard metallurgical procedures. The ability of this group of microbes to facilitate metals recovery is yet to be developed on a commercial scale.     

Ultrastructure of an extremely thermophilic acidophilic micro-organism.

A thermoacidophilic micro-organism, isolated from volcanic hot springs near Naples, was cultivated in vitro, and examined by electron microscopy in sections and after negative staining. The cells were almost spherical, with a diameter of about 0.7 to 1.0 mum. Their morphology was very primitive: the protoplasm was composed only of ground cytoplasm, ribosomes, and randomly distributed DNA strands. They were surrounded by a plasma membrane and by an extracellular coat about 20 nm thick which displayed a regular hexagonal pattern. Cell replication occurred by binary fission with median constriction during which a bipolar localization of nuclear material was observable. The morphology is compared with that of other known micro-organisms living in similar habitats.     

Efficient hydroxylamine mutagenesis ofHaloferax mediterranei and other extremely halophilic archaebacteria

The lethal and mutagenic effects of hydroxylamine onHaloferax mediterranei and five other extremely halophilic archaebacteria are described for the first time. Although previous studies have shown thatH. mediterranei was very resistant to the lethal action of other DNA-damaging agents, this strain was found to be relatively sensitive to hydroxylamine, but also more successfully mutated by the latter. The efficiency of the mutagenicity obtained with the hydroxylamine treatment was tested under a variety of conditions, and optimal procedures are described that yielded a number of useful auxotrophic mutant strains ofH. mediterranei. Likewise, a strong induced mutagenicity after hydroxylamine mutagenesis was achieved for the majority of the other archaebacteria tested.     

Distribution of folates and modified folates in extremely thermophilic bacteria.

Analyses were made of the structures and levels of folates and modified folates present in extremely thermophilic bacteria. These procedures involved the chemical analysis of products resulting from the oxidative cleavage of the 6-substituted, folatelike tetrahydropterins present in the cells. Air-oxidized cell extracts of extreme thermophiles from two members of the archaebacterial order Thermococcales, Thermococcus celer and Pyrococcus furiosus, contained only 7-methylpterin, indicating that these cells contain a modified folate with a methylated pterin. Cell extracts also contained 6-acetyl-7-methyl-7,8-dihydropterin, another product derived from the oxidative cleavage of a dimethylated folate, demonstrating that both the C-7 and C-9 carbons of the pterin were methylated. Extracts, however, contained neither p-aminobenzoylpolyglutamates nor methaniline, the oxidative cleavage products of folates and methanopterin, respectively, indicating that they contain a previously undescribed C1 carrier(s). On the basis of the level of the 7-methylpterin isolated, the levels of modified folate were 2 to 10 times higher than those typically found in mesophilic bacteria and 10 to 100 times less than the level of methanopterin found in the methanogenic bacteria. Oxidized cell extracts of Sulfolobus spp. of the archaebacterial order Sulfolobales contained only pterin, and, like members of the order Thermococcales, they contained neither-p-aminobenzoylpolyglutamates nor methaniline. Oxidized cell extracts of the extreme thermophiles Pyrobaculum sp. strain H10 and Pyrodictium occultum, from the archaebacterial orders Thermoproteales and Pyrodictiales, respectively, and Thermotoga maritima from the eubacterial order Thermotogales, contained pterin and p-aminobenzoylpolyglutamates, indicating that these cells contained unmodified folates. The levels of p-aminobenzoylpolyglutamates in these archaebacterial cell extracts indicate that the folates were present in the cells at levels 4 to 10 times higher than generally found in those mesophilic eubacteria which do not folates in energy metabolism. The levels and chain lengths of the of p-aminobenzoylpolyglutamates present in Thermotoga maritima were typical of those found in mesophilic eubacteria.     

RNA folding and ribosome assembly

Ribosome synthesis is a tightly regulated process that is crucial for cell survival. Chemical footprinting, mass spectrometry, and cryo-electron microscopy are revealing how these complex cellular machines are assembled. Rapid folding of the rRNA provides a platform for protein-induced assembly of the bacterial 30S ribosome. Multiple assembly pathways increase the flexibility of the assembly process, while accessory factors and modification enzymes chaperone the late stages of assembly and control the quality of the mature subunits.