E. V. Demkina

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.

Comparative analysis of the functional activity and composition of hydrolytic microbial complexes from the lower Volga barrow and modern chestnut soils

The structure and specific characteristics of the hydrolytic microbial complexes from chestnut paleosols buried under the barrows of different ages (∼4500 and ∼3500 years) was compared with their modern analogue in microcosm experiments. Potential activity of the hydrolytic complex of the microbial community of the barrow paleosols was found to be higher than in the modern soil complex. The share of metabolically active cells revealed by FISH after the introduction of a growth-stimulating polysaccharide into the paleosol microcosm was 50% of the whole prokaryotic cell number. The paleosol community exhibited a more pronounced response to addition of the substrate than the modern soil community. The differences in the phylogenetic taxonomic structure of the prokaryotic metabolically active hydrolytic complex in the buried and modern soils were revealed. The hydrolytic complex of modern soil was more diverse, while the dominant hydrolytic organisms revealed in paleosols were unicellular and mycelial Actinobacteria, as well as Proteobacteria.

Comparison of the adaptive potential of the Arthrobacter oxydans and Acinetobacter lwoffii isolates from permafrost sedimentary rock and the analogous collection strains

A comparative study was conducted on the adaptive mechanisms of the strains Arthrobacter oxydans K14 and Acinetobacter lwoffii EK30A isolated from permafrost subsoil sediments and of those of the analogous collection strains (Ac-1114 Type and BSW-27, respectively). In each pair of the strains compared, the strains differed in terms of (i) growth-related, physiological, and biochemical properties; (ii) resistance to stress factors; (iii) capacity for generation of dormant forms (DFs) under growth arrest conditions, and (iv) intrapopulation production of phase variants. The strains isolated from permafrost displayed a lower growth rate but were more resistant to repeated freezing-thawing treatment than the collection strains. Under the same growth conditions, the permafrost strains formed larger numbers of cystlike anabiotic DFs, extraordinarily small cells, and forms that became nonculturable during long-term storage. Resuscitation of the nonculturable forms resulted in a 2- to-7-fold increase in the percentage of FISH-detectable metabolically active cells. The permafrost strains were also distinguished by increased genome lability. This facilitated their dissociation into intrapopulation variants with phenotypically distinct colonial and morphological properties and different antibiotic resistance. The phenotypic variability was more prominent in Arthrobacter (for which it was not reported previously) than in Acinetobacter. In the populations produced by plating the dormant bacterial forms, the qualitative and quantitative characteristics of the phase variant spectra varied depending on the formation conditions and the composition of the solid media used for the plating. Thus, the permafrost isolates of A. oxydans and Ac. lwoffii were distinguished from their collection analogs by a more manifest adaptive potential including stress resistance, the intensity of DF generation under growth arrest conditions, and increased intrapopulation variability.

Characterization of the structure of the prokaryotic complex of Antarctic permafrost by molecular genetic techniques

A prokaryotic mesophilic organotrophic community responsible for 10% of the total microbial number determined by epifluorescence microscopy was reactivated in the samples of Antarctic permafrost retrieved from the environment favoring long-term preservation of microbial communities (7500 years). No culturable forms were obtained without resuscitation procedures (CFU = 0). Proteobacteria, Actinobacteria, and Firmicutes were the dominant microbial groups in the complex. Initiation of the reactivated microbial complex by addition of chitin (0.1% wt/vol) resulted in an increased share of metabolically active biomass (up to 50%) due to the functional domination of chitinolytics caused by the target resource. Thus, sequential application of resuscitation procedures and initiation of a specific physiological group (in this case, chitinolytics) to a permafrost-preserved microbial community made it possible to reveal a prokaryotic complex capable of reversion of metabolic activity (FISH data), to determine its phylogenetic structure by metagenomic analysis, and to isolate a pure culture of the dominant microorganism with high chitinolytic activity.

Resting forms of Sinorhizobium meliloti

The ability of the symbiotrophic rhizobium Sinorhizobium meliloti P221 to produce cells having all the properties of resting forms (RFs) during the development cycles of the culture or after addition of the threshold concentrations of anabiosis autoinducers was demonstrated. The numbers, properties, and ultra-structure of S. meliloti resting forms depended on the conditions of growth and poststationary-phase incubation. In the four-month poststationary-phase, cultures grown in media deficient in some nutrient elements and energy sources (nitrogen, phosphorus, or oxygen), numerous cells (24–76% of the number of CFUs in the stationary-phase cultures) exhibiting a high degree of heat resistance and reversibly inhibited metabolic activity (the absence of endogenous respiration) were detected. According to their ultrastructure, all the resting forms detected in starving cultures were divided into three groups: (1) cystlike resting cells (CRCs) with thick cell envelopes and compacted nucleoids, (2) CRCs containing numerous (up to three-quarters of their volumes) polyhydroxyalkanoate inclusions, and (3) RFs similar to Azotobacter cysts. The resting forms obtained in the culture grown at high concentrations (5 × 10−5 M) of C12-AHB, a chemical analogue of microbial anabiosis autoregulators, were incapable of endogenous respiration and retained the colony-forming ability. The CFU number after plating of these resting forms was twice as high as in the control culture; the heat resistance of these cells (55°C, 10 min) was an order of magnitude higher. The bacterial cells obtained from the resting forms either had a mixed (Swa+Gri+) type of motility in semisolid agar, typical of the dominant phenotype of the parent cells, or switched to the Gri+ type. Emergence of different motility phenotypes depended on the conditions of RF formation. More severe stress conditions of RF formation induced the emergence of the Gri+ type of cell motility. The results obtained can be used for development of a new generation of bacterial preparations based on bacterial CRCs which are able to preserve their viability for a long time and are highly resistant to stress impacts.

The prokaryotic community of subglacial bottom sediments of Antarctic Lake Untersee: Detection by cultural and direct microscopic techniques

The heterotrophic mesophilic microbial component was studied in microbial communities of the samples of frozen regolith collected from the glacier near Lake Untersee collected in 2011 during the joint Russian-American expedition to central Dronning Maud Land (Eastern Antarctica). Cultural techniques revealed high bacterial numbers in the samples. For enumeration of viable cells, the most probable numbers (MPN) method proved more efficient than plating on agar media. Fluorescent in situ hybridization with the relevant oligonucleotide probes revealed members of the groups Eubacteria (Actinobacteria, Firmicutes) and Archaea. The application of the methods of cell resuscitation, such as the use of diluted media and prevention of oxidative stress, did not result in a significant increase in the numbers of viable cells retrieved from subglacial sediment samples. Our previous investigations demonstrated the necessity for special procedures for efficient reactivation of the cells from microbial communities of replace with buried soil and permafrost samples collected in the Arctic zone. The differing responses to the special resuscitation procedures may reflect the differences in the physiological and morphological state of bacterial cells in microbial communities subject to continuous or periodic low temperatures and dehydration.

Model of the regulation of activity of immobilized enzymes (amylases) in soil

The preservation of activity of extracellular enzymes in soil is presently associated with their immobilization on organic or inorganic carriers. Enzyme immobilization results, however, in a significant decrease in enzymatic activity. In the present work, the mechanism responsible for promotion of the catalytic activity was revealed, as well as the favorable effect of low-molecular alkylhydrozybenzenes of the class of alkylresorcinols, which are common in soil organic matter, on stability of immobilized enzymes (exemplified by amylases) by their post-translational modification. Optimal conditions (enzyme to sorbent ratio, pH optimum, CaCl2 concentration, and sorption time) for amylase sorption on a biological sorbent (yeast cell walls) were determined and decreased activity of the immobilized enzyme compared to its dissolved state was confirmed. Alkylresorcinols (C7AHB) at concentrations of 1.6 to 80 mM were found to cause an increase of amylase activity both in the case of already sorbed enzymes (by 30%) and in the case of a free dissolved enzyme with its subsequent immobilization (by 50–60%). In both cases, the optimal C7AHB concentration was 16 mM. Amylase stability was determined for C7AHB-modified and unmodified enzymes immobilized on the biological sorbent after two cycles of freezing (–20°C) and thawing (4°C). Inverse dependence was revealed between increasing stability of C7AHB-modified enzymes and an increase in their activity, as well as higher stability of immobilized modified amylases than of the dissolved modified enzyme. Investigation of the effect of C7HOB-modification in the preservation of activity in immobilized amylases after four freeze–thaw cycles revealed: (1) better preservation of activity by the modified immobilized enzymes compared to immobilized ones; (2) differences in the dynamics of activity loss within compared pairs, with activity of immobilized amylases decreasing after the second cycle to a lower level (42%) than activity of the modified immobilized enzymes after the fourth cycle (48%). These results demonstrate that in the preservation of activity of extracellular enzymes in soil both stabilization mechanisms are of importance: immobilization on organic carriers and modification of the enzyme conformation by low-molecular compounds with the functions of chemical chaperones.

Effect of Inherent Immunity Factors of Development of Antibiotic Tolerance and Survival of Bacterial Populations under Antibiotic Attack

Effect of human inherent immunity factors, a gene-encoded antibacterial peptide indolicidin (Ind) and a cytokine interleukin 1 (IL-1), on formation of antibiotic-tolerant persister cells surviving in the presence of ciprofloxacin (Cpf, 100 μg/mL) and ampicillin (Amp, 100 μg/mL) in submerged bacterial cultures (Staphylococcus aureus FGA 209P, Escherichia coli K12, and Pseudomonas aeruginosa PAO1) was studied. While Ind in physiological concentrations (0.3 and 3.0 μg/mL) introduced to the lagor exponentialphase cultures of test organisms exhibited no reliable effect on population growth, the number of persisters increased at 3.0 μg/mL. Bactericidal Ind concentrations (9 μg/mL) suppressed S. aureus growth (~0.1% of surviving cells) with subsequent recovery due to development of the more antibiotic-tolerant white variant. Treatment with Cpf after Ind addition resulted in mutual potentiation of their antimicrobial activity, with the number of S. aureus persisters 2 to 3 orders of magnitude lower than in the case of the antibiotic alone. IL-1, another immunity factor, when introduced (0.1–1 ng/mL) to the exponentially growing S. aureus culture (but not to the lag phase culture) had a temporary growth-static effect, with the number of persisters surviving Cpf treatment (100 μg/mL) increasing by 1 to 2 orders of magnitude. Electron microscopy revealed significant alterations in the outer cell wall layer of surviving S. aureus cells, which should be associated with their changed antigenic properties. Thus, the factors of human inherent immunity have a dose-dependent effect on the growth of bacterial populations. In combination with antibiotics, they exhibit synergism of antimicrobial action (indolicidin) and minimize (indolicidin) or increase (interleukin 1) the frequency of formation of persister cells responsible for survival of a population subjected to an antibiotic attack.