Identification of archaea and some extremophilic bacteria using matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry

Archaea and a number of groups of environmentally important bacteria, e.g., sulfate-reducing bacteria, anoxygenic phototrophs, and some thermophiles, are difficult to characterize using current methods developed for phenotypically differentiating heterotrophic bacteria. We have evaluated matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF-MS) as a rapid method for identifying different groups of extremophilic prokaryotes using a linear mass spectrometer (Micromass, UK). The instrument is designed to acquire mass-spectral patterns from prokaryotic cell-wall components between masses of 500 and 10,000 Da in a statistically robust manner and create a database that can be used for identification. We have tested 28 archaea (10 genera, 20 spp.) and 42 bacteria (25 genera, 37 spp.) and found that all species yield reproducible, unique mass-spectral profiles. As a whole, the profiles for the archaea had fewer peaks and showed less differentiation compared to the bacteria, perhaps reflecting fundamental differences in cell-wall structure. The halophilic archaea all had consistent patterns that showed little differentiation; however, the software was able to consistently distinguish Halobacterium salinarium, Halococcus dombrowski, and Haloarcula marismortui from one another, although it could not always correctly distinguish four strains of Hb. salinarium from one another. The method was able to reliably identify 10⁵ cells of either Albidovulum inexpectatum or Thermococcus litoralis and could detect as low as 10³ cells. We found that the matrix, alpha-cyano-4-hydroxy-cinnamic acid yielded better spectra for archaea than 5-chloro-2-mercapto-benzothiazole. Overall, the method was rapid, required a minimum of sample processing, and was capable of distinguishing and identifying a very diverse group of prokaryotes.Communicated by F. Robb     

Expression and characterization of isoform 1 of human mitochondrial elongation factor G

Elongation factor G (EF-G) catalyzes the translocation step of protein biosynthesis. Genomic analysis suggests that two isoforms of this protein occur in mitochondria. The region of the cDNA coding for the mature sequence of isoform 1 of human mitochondrial EF-G (EF-G1(mt)) has been cloned and expressed in Escherichia coli. The recombinant protein has been purified to near homogeneity by chromatography on Ni-NTA resins and cation exchange high performance liquid chromatography. EF-G1(mt) is active on both bacterial and mitochondrial ribosomes. Human EF-G1(mt) is considerably more resistant to fusidic acid than many bacterial translocases. A molecular model for EF-G1(mt) has been created and analyzed in the context of its relationship to the translocases from other systems.     

The determination of homocysteine-thiolactone in biological samples

Homocysteine-thiolactone, a cyclic thioester of homocysteine, is synthesized by methionyl-tRNA synthetase in all cell types. A new assay for the determination of homocysteine-thiolactone in biological samples is described. The assay involves separation of homocysteine-thiolactone from macromolecules by ultrafiltration. Homocysteine-thiolactone is further purified and quantified by high-pressure liquid chromatography either on a reverse phase or a cation exchange micro-bore column. The detection and quantitation are obtained by monitoring the absorbance at 240 nm, a maximum in a UV spectrum of homocysteine-thiolactone. The sensitivity of detection is 5 pmol. This assay has been applied to bacteria (Escherichia coli and Mycobacterium smegmatis), the yeast Saccharomyces cerevisiae, cultured human vascular endothelial cells, and human plasma. The data support the conclusion that homocysteine-thiolactone is a ubiquitous metabolite whose levels are directly related to homocysteine levels.     

Characterizing man-made and natural modifications of microbial diversity and activity in coastal ecosystems

The impacts of growing coastal pollution and habitat alteration accompanying human encroachment are of great concern at the microbial level, where much of the ocean's primary production and biogeochemical cycling takes place. Coastal ecosystems are also under the influence of natural perturbations such as major storms and flooding. Distinguishing the impacts of natural and human stressors is essential for understanding environmentally-induced change in microbial diversity and function. The objective of this paper is to discuss the applications and merits of recently developed molecular, ecophysiological and analytical indicators and their utility in examining anthropogenic and climatic impacts on the structure and function of coastal microbial communities. The nitrogen-limited Neuse River Estuary and Pamlico Sound, North Carolina are used as examples of ecosystems experiencing both anthropogenic (i.e., accelerating eutrophication) and climatic stress (increasing frequencies of tropical storms and hurricanes). Additional examples are derived from a coastal monitoring site (LEO) on the Atlantic coast of New Jersey and Galveston Bay, on the Gulf of Mexico. In order to assess structure, function, and trophic state of these and other coastal ecosystems, molecular (DNA and RNA-based) characterizations of the microbial taxa involved in carbon, nitrogen and other nutrient transformations can be combined with diagnostic pigment-based indicators of primary producer groups. Application of these methods can reveal process-level microbial community responses to environmental variability over a range of scales. Experimental approaches combined with strategic monitoring utilizing these methods will facilitate: (a) understanding organismal and community responses to environmental change, and (b) synthesizing these responses in the context of ecosystem models that integrate physical, chemical and biotic variability with environmental controls. This revised version was published online in August 2006 with corrections to the Cover Date.     

Using Homolog Groups to Create a Whole-Genomic Tree of Free-Living Organisms: An Update

Genomic trees have been constructed based on the presence and absence of families of protein-encoding genes observed in 27 complete genomes, including genomes of 15 free-living organisms. This method does not rely on the identification of suspected orthologs in each genome, nor the specific alignment used to compare gene sequences because the protein-encoding gene families are formed by grouping any protein with a pairwise similarity score greater than a preset value. Because of this all inclusive grouping, this method is resilient to some effects of lateral gene transfer because transfers of genes are masked when the recipient genome already has a homolog (not necessarily an ortholog) of the incoming gene. Of 71 genes suspected to have been laterally transferred to the genome of Aeropyrum pernix, only approximately 7 to 15 represent genes where a lateral gene transfer appears to have generated homoplasy in our character dataset. The genomic tree of the 15 free-living taxa includes six different bacterial orders, six different archaeal orders, and two different eukaryotic kingdoms. The results are remarkably similar to results obtained by analysis of rRNA. Inclusion of the other 12 genomes resulted in a tree only broadly similar to that suggested by rRNA with at least some of the differences due to artifacts caused by the small genome size of many of these species. Very small genomes, such as those of the two Mycoplasma genomes included, fall to the base of the Bacterial domain, a result expected due to the substantial gene loss inherent to these lineages. Finally, artificial ``partial genomes' were generated by randomly selecting ORFs from the complete genomes in order to test our ability to recover the tree generated by the whole genome sequences when only partial data are available. The results indicated that partial genomic data, when sampled randomly, could robustly recover the tree generated by the whole genome sequences. Received: 30 May 2001 / Accepted: 10 October 2001     

Caffeine-inducible enzyme activity in Pseudomonas putida ATCC 700097

Caffeine (1,3,7-trimethylxanthine), a ubiquitous component of human diet has been suggested as a chemical indicator of ecosystem impacts of sewage spills and treated effluent discharges because it is not sufficiently metabolized by wastewater microorganisms. This study identified enzymes responsible for caffeine metabolism in sewage bacteria. Pseudomonas putida biotype A (ATCC 700097) originally isolated as a rare caffeine-degrading organism in domestic wastewater exhibited diauxic growth on caffeine, concomitant with the expression of a P450-type cytochrome and peroxidase enzyme activities. Initial growth phase lasted 13.8 ± 1.4 h with a growth rate that was five times slower than the secondary growth phase that lasted 5.5 ± 1.2 h. Molecular and enzymatic characteristics of the cytochrome P450-type enzyme differ from the previously described cytochrome P450 (P450_cam) of P. putida (ATCC 17453) involved in camphor metabolism. The caffeine-inducible cytochrome P450-type enzyme exhibited a carbon monoxide difference spectrum peak at 450 nm, but does not allow growth on camphor. Caffeine induced production of haem-associated peroxidase activity was confirmed with 3,3, 5,5-tetramethylbenzidine–H₂O₂ reaction in polyacrylamide gels. Polymerase chain reaction (PCR) primers derived from the gene for cytochrome P450_cam (camC) of P. putida (ATCC 17453) did not yield an amplification product when DNA extracted from P. putida strain ATCC 700097 was used as template. The data demonstrate that caffeine is metabolized through a specific biphasic pathway driven by oxygen-demanding enzymes.     

Proteolysis in hyperthermophilic microorganisms

Proteases are found in every cell, where they recognize and break down unneeded or abnormal polypeptides or peptide-based nutrients within or outside the cell. Genome sequence data can be used to compare proteolytic enzyme inventories of different organisms as they relate to physiological needs for protein modification and hydrolysis. In this review, we exploit genome sequence data to compare hyperthermophilic microorganisms from the euryarchaeotal genus Pyrococcus, the crenarchaeote Sulfolobus solfataricus, and the bacterium Thermotoga maritima. An overview of the proteases in these organisms is given based on those proteases that have been characterized and on putative proteases that have been identified from genomic sequences, but have yet to be characterized. The analysis revealed both similarities and differences in the mechanisms utilized for proteolysis by each of these hyperthermophiles and indicated how these mechanisms relate to proteolysis in less thermophilic cells and organisms.     

Bacterial community in the tunic matrix of a colonial ascidian<Emphasis Type="Italic"> Diplosoma migrans</Emphasis>

This paper provides the first information on the morphology of different morphotypes of bacteria in the tunic matrix of the colonial ascidian Diplosoma migrans. Ascidians were collected from waters near Helgoland (German Bight, North Sea). The dominant type is represented by extremely high numbers of long, needle-like rods (length 10–30 µm, width 0.5 µm). The bacteria are motile by means of bipolar monotrichous flagella, generating swift sigmoidal movement. Bacteria are already present during different embryonic stages. It is assumed that they are transferred during sexual propagation from the parental colony to its offspring. As a second morphotype, the tunic harbors screw-like bacteria in low numbers (length 4–10 µm, width 0.5 µm). Besides these conspicuous morphotypes, occasionally motile rods with spore-like globules at one end and additional coccoid forms in large quantities of unknown meaning (possibly spores) were found. The taxonomic status and ecological functions of these differently shaped bacterial groups are unclear.Communicated by H.-D. Franke     

Intraspecies variability of Desulfovibrio desulfuricans strains determined by the genetic profiles

Fifteen (soil and intestinal) strains of Desulfovibrio desulfuricans species were typed by PCR method with the use of primers specific for repetitive extragenic palindromic (REP) and enterobacterial repetitive intergenic consensus (ERIC) sequences. As a result, characteristic DNA fingerprints for the strains were obtained. Moreover, the genetic profiles were found to be useful for typing and distinguishing the strains of D. desulfuricans. According to cluster analysis, PCR with primers complementary to the sequences REP appeared to be slightly more discriminatory than PCR with ERIC primers for the investigated strains. Distinct fingerprint patterns of two isolates derived from the same patient pointed to the different origin of both strains.