V. F. Gal’chenko

Adaptogenic functions of extracellular autoregulators of microorganisms

Information about the functions of extracellular autoregulators, which adapt microorganisms to the stresses “scheduled” in the development cycle of microbial cultures (stresses of new medium, starvation, or space exhaustion (high cell density)) is summarized in the review. In a number of bacteria and yeasts, derivatives of alkylhydroxybenzenes (AHB), particularly of the class of alkyl resorcinols, act as autoregulators with adaptogenic functions. The chemical structure of AHB determines their amphiphility; capacity for physical and chemical interaction with membrane lipids, proteins, and DNA; properties as natural modifiers of biological membranes and enzymes; and the expression of antioxidant activity. Increase of AHB concentration up to the critical level (10−5-10−4 M) results in cessation of cell division and in transition of the microbial culture to the stationary phase; further increase to 10−4-10−3 M induces a transition of some of the cells of a post-stationary culture to the anabiotic state with the formation of cystlike resting cells (CRC), even in non-spore-forming bacteria. AHB participate in the regulation of the phenotypic variability of bacteria. The dynamics of extra-and intracellular concentrations of AHB in growing microbial cultures and the polymodality of their effect determine the adaptogenic functions of AHB as autoinhibitors of culture growth, autoinducers of anabiosis, and autoinhibitors of germination of resting forms. Manifestation of any given function depends on the concentration of AHB, the physiological state of the recipient cells, and on environmental factors. The species nonspecificity of AHB effects points to their significant role in the regulation of the development and functioning of microbial communities.

Stabilization of enzymes by dormancy autoinducers as a possible mechanism of resistance of resting microbial forms

Alkyl-substituted hydroxybenzenes (AHBs), autoinducers of microbial dormancy (ord1 factors), were found to stabilize the structure of protein macromolecules, making them metabolically less active and more resistant to stresses. In vitro experiments with theBacillus intermedius ribonuclease and chymotrypsin showed that the degree of the physical and chemical stability of these enzymes treated with AHBs depends on their concentration and incubation time. Experiments with RNase, which is capable of refolding, i.e., renaturation after heat denaturation, revealed that AHBs efficiently interact with both intact and denatured proteins. The data obtained allow the inference to be made thatd1 factors may play the role of natural chemical chaperons, blocking metabolism in dormant cells through the formation of catalytically inactive thermostable complexes with enzymes.

Molecular analysis of high-affinity methane-oxidizing enrichment cultures isolated from a forest biocenosis and agrocenoses

Methane oxidation by microorganisms inhabiting aerobic soils is a key process involved in the regulation of the concentration of this significant greenhouse gas in the atmosphere; however, the microorganisms responsible for this process remain unknown. Three stable methane-oxidizing cultures were isolated from samples of forest soils (FS) and agricultural soils (AS) of Moscow oblast, as well as from soil samples collected from a Belgian agrocenosis (BS). The obtained enrichment cultures exhibit a high affinity for methane; their km values range from 54.2 to 176.8 nM CH4 and are comparable to those of aerobic soils. Analysis of the fragments of the ribosomal (16S rRNA) and functional (pmoA) genes of methanotrophs by PCR— DGGE and cloning demonstrated the presence of bacteria belonging to the genera Methylocystis in FS, Methylosinus in AS and BS, and Methylocella in BS. It was established that Methylocystis and Methylosinus detected in the enrichment cultures contain the genes encoding the synthesis of the active center of two membrane-bound particulate methane monooxygenases; it is likely that one of these genes (pmoA2) is responsible for the capacity of these microorganisms for oxidation of atmospheric methane.

Reactivation of dormant and nonculturable bacterial forms from paleosoils and subsoil permafrost

Methods of reactivating the dormant forms (DFs) and nonculturable cells (NCs) of the bacterial communities of buried paleosoils and subsoil permafrost stored for long periods of time (thousands to millions of years), including completely sterile samples (CFU = 0), were developed. They were based on washing the DFs and NCs to remove anabiosis autoinducers (spore germination autoinhibitors) and introducing low molecular weight extracellular growth regulators of microbial or plant origin, such as alkylhydroxybenzenes of the alkylresorcinol subtype, indoleacetic acid, and wheat germ agglutinin. It was revealed that the dormant communities of permafrost and buried soils differed in their sensitivity to reactivating factors, probably due to different natural storage conditions of the tested soil substrates and the heterogeneity of dormant populations. The latter was confirmed by FISH (fluorescent in situ hybridization): applying the reactivation methods to the cells of the dormant permafrost community resulted in an increase in the number of metabolically active cells from 5 to 77% of their total number. In contrast, the addition of microbial anabiosis autoinducers (C12-AHB) to background surface soil and permafrost samples caused the transition of bacterial cells to the dormant or the nonculturable state, depending on the C12-AHB concentration and the sensitivity of the cells from the control soil or permafrost’ to it. The data obtained contribute to our knowledge concerning the role of intercellular communication factors and the survival of microorganisms under extreme environmental conditions.

Adaptation of lactic acid bacteria to unfavorable growth conditions

The adaptation of lactic acid bacteria (LAB) to unfavorable growth conditions, e.g., depletion of nutrient sources, overthreshold cell density of a population, or antibiotic impact, was shown to include: (1) formation of cyst-like dormant cells (CDC) providing for survival and species preservation and (2) realization of intra-population phenotypic variability, which is demonstrated by development of non-dominant colonies on plates inoculated with CDC suspensions. In Lactobacillus plantarum, the dormant cells, which retained viability and heat resistance for a long time, were formed in 10- and 20-fold concentrated suspensions of the stationary phase cells. In 4-month cell suspensions, two types of cells were present, CDC and L-forms. The CDC of Lactococcus lactis were formed in (1) post-stationary cultures grown under glucose limitation and (2) in stationary phase cultures resuspended in starvation medium (without glucose). Populations of CDC stored for different periods of time varied in the ability for phase variation; as a result, both variants exhibited a shift of the population’s CDC spectrum to the transition of the dominant S-colony type to the R-type up to complete substitution (by day 25). In Lactobacillus acidophilus AT-41, CDC appeared in (1) post-stationary cultures grown on a nitrogen-limited medium; (2) autolyzing cultures treated with ampicillin or erythromycin; and (3) concentrated (10- and 20-fold) suspensions of stationary-phase cells. At plating of L. acidophilus CDC, the substitution of the S-type for the dominant R-type in variants (1) (day 30), (2) (100 μg/ml ampicillin, day 10), and (3) (day 25) was 68.6%, 30.1%, and 61.2%, respectively. The S-variant of L. acidophilus was used for development of a novel lactofermented product based on vegetable (beet) juice fermentation, which sustained high titer of viable cells (2 × 106 cells/ml).

Physicochemical and Biological Factors Affecting Atmospheric Methane Oxidation in Gray Forest Soils

The decline of methane oxidizing activities in gray forest soil upon its conversion into arable land was shown to be caused by major changes in biotic and physicochemical properties of soil. Using the method of immune serums, methane-oxidizing bacteria were detected in both forest and agricultural soils, but their populations differed significantly in both abundance and composition. In the forest soil, the number of methanotrophs was an order of magnitude higher than in arable soil, amounting to 3.5 × 108 and 0.24 × 108 cells/g soil, respectively. All methane-oxidizing bacteria identified in the forest soil belonged to the genus Methylocystis, and 94% of these were represented by a single species, M. parvus. The arable soil was dominated by type I methanotrophs (Methylobacter and Methylomonas, 67.6%), occurring along with bacteria of the genus Methylocystis. In addition, arable soil is characterized by a low content of microbial biomass, lower porosity and water resistance of soil aggregates, and the predominance of nitrogen mineralization processes over those of nitrogen immobilization. These factors can also contribute to lower rates of methane oxidation in arable soil as compared to forest soil.

[Heliobacterium sulfidophilum sp. Nov. and Heliobacterium undosum sp. Nov.: sulfide-oxidizing Heliobacteria from thermal sulfidic springs].

Two new species of heliobacteria isolated from cyanobacterial mats of two alkaline sulfidic hot springs are formally described. Strains BR4 and BG29 are assigned to anoxygenic phototrophic bacteria of the familyHeliobacteriaceae, since they possess the unique properties of this taxon: strict anaerobiosis, formation of bacteriochlorophyllg, the lack of extensive intracytoplasmic membranes and chlorosomes, an unusual cell wall structure, and phylogenetic relatedness to the low G+C gram-positive eubacteria. Based on the 16S rDNA sequence similarity, strains BR4 and BG29 are assigned to the genusHeliobacterium and described as two new species of this genus:Heliobacterium sulfidophilum sp. nov. andHeliobacterium undosum sp. nov. The G+C content of the DNA is 51.3 mol % inHbt. sulfidophilum and 57.2-57.7 mol % inHbt. undosum. The cells ofHbt. sulfidophilum are rods, and the cells ofHbt. undosum are slightly twisted spirilla or short rods. Both new bacteria are motile by peritrichous flagella.Hbt. sulfidophilum produces endospores. The new bacteria are strict anaerobes growing photoheterotrophically on a limited range of organic compounds. In the dark, they can switch from photosynthesis to the slow fermentation of pyruvate. Biotin is required as a growth factor. Both species are highly tolerant to sulfide (up to 2 mM at pH 7.5) and oxidize it photoheterotrophically to elemental sulfur; photoautotrophic growth was not observed. The temperature optimal for growth ofHbt. sulfidophilum andHbt undosum is 30–35‡C, and the optimal pH is 7–8.

Involvement of alkylhydroxybenzenes, microbial autoregulators, in controlling the expression of stress regulons

Alkylhydroxybenzenes (AHB) were found to control the activation of protective functions of microorganisms by inducing stress gene expression and increasing the frequency of the intrapopulation phase transitions which are responsible for the phenotypic variability of bacteria. We established the dependence of the regulatory effects of AHB on their structure (alkyl radical length) and concentration. A reversion assay using the tryptophan auxotrophic strain Bacillus subtilis trpA5 B 1733 indicated a relationship between the reversion frequency that was 40–120 times higher than the background value and phase transition’s intensity (with R → S transition rates up to 87% in contrast to 2% in the control experiment) induced by specific doses (5–100 mg/ml) of long-chain AHB such as C12-AHB acting for a short time (1 h) on vegetative (dividing or stationary-phase) B. subtilis cells. Using four test strains constructed from Escherichia coli C600 thi, thr, leuΔ(pro-lac) with transcriptional or translational vectors containing the hybrid umuD-lacZ or osmE-lacZ operons, we demonstrated that AHB perform the regulatory functions involved in controlling the SOS response gene expression and the general rpoS -dependent stationary-phase regulon, respectively. The dose-dependent effect of long-chain AHB (within the 50–100 µg/ml range) resulting in a two- to threefold increase in the stress gene expression, similar to the effect of natural stress factors such as UV irradiation and starvation, provides evidence that AHB function as alarmones (danger signals). From the fact that the osm E gene is upregulated by 35–70 µg/ml C12-AHB (its regulation level is increased up to twofold), it follows that C12-AHB controls rpoS-dependent regulation and the transition to the stationary phase. The effect of the short-chain homologue C7-AHB substantially differs from that of C12-AHB. C7-AHB in concentrations of 10–100µg/ml causes a significant decrease in osmE and umuD expression. A 30-min preincubation of cells with 10–100µg/ml C7-AHB protected them from UV irradiation, as was observed as a 3.6-fold decrease in umuD expression. Comparative analysis of the marker gene’s expression values in the strains with the transcriptional and translational vectors demonstrates that AHB nonspecifically activate stress regulons at the transcription level.

Dormant state and phenotypic variability of Staphylococcus aureus and Corynebacterium pseudodiphtheriticum

Ability to produce dormant forms (DF) was demonstrated for non-spore-forming bacteria Staphylococcus aureus (a nonpathogenic strain) and Corynebacterium pseudodiphtheriticum (an organism of the normal oropharyngeal flora). The salient features of the sthaphylococcal and corynebacterial DF were (1) prolonged (4 months) preservation of viability; (2) resistance to damaging factors (heat treatment); and (3) specific morphology and ultrastructure. The optimal conditions for DF formation were (1) transfer of stationary-phase cultures into saline solution with CaCl2 (10–300 mM) (for S. aureus); (2) growth in SR1 synthetic medium with fivefold nitrogen limitation (for C. pseudodiphtheriticum); and (3) incubation with (1–5) × 10−4 M of C12-AHB, an alkylhydroxybenzene akin to microbial anabiosis autoinducers. Increase of C12-AHB concentration to 7 × 10−4–2 × 10−3 M resulted in “mummification” of cells with irreversible loss of viability without autolytic processes. Germination of dormant forms was followed by increasing of phenotypic variability, as seen from (1) diversity of colony types and (2) emergence of antibiotic-resistant clones on selective media. The share of kanamycin-resistant S. aureus variants was most numerous (0.002–0.01%) in 4-month DF suspensions in SALINE with CaCl2. In the C. pseudodiphtheriticum DF produced under the effect of C12-AHB, the share of kanamycin-resistant variants was also found to increase. These data point to an association between the emergence of antibiotic-resistant variants of bacteria and their persistence in dormant state mediated by starvation stress and regulated by AHB.

Dominant phylotypes in the 16S rRNA gene clone libraries from bacterial mats of the Uzon caldera (Kamchatka, Russia) hydrothermal springs

In situ analysis of the 16S rRNA genes from bacterial mats of five hydrothermal springs (36–58°C) in the Uzon caldera (Kamchatka, Russia) was carried out using clone libraries. Eight clone libraries contained 18 dominant phylotypes (over 4–5%). In most clone libraries, the phylotype of the green sulfur bacterium Chlorobaculum sp. was among the dominant ones. The phylotypes of the green nonsulfur bacteria Chloroflexus and Roseiflexus and of purple nonsulfur bacteria Rhodoblastus, Rhodopseudomonas, and Rhodoferax were also among the dominant ones. Cyanobacteria were represented by one dominant phylotype in a single spring. Among nonphototrophic bacteria, the dominant phylotypes belonged to Sulfyrihydrogenibium sp., Geothrix sp., Acidobacterium sp., Meiothermus sp., Thiomonas sp., Thiofaba sp., and Spirochaeta sp. Three phylotypes were not identified at the genus level. Most genera of phototrophic and nonphototrophic organisms corresponding to the phylotypes from Uzon hydrotherms have been previously revealed in the hydrotherms of volcanically active regions of America, Asia, and Europe. These results indicate predominance of bacterial mats carrying out anaerobic photosynthesis in the hydrotherms of the Uzon caldera.