Stress-Tolerance and Taxonomy of Culturable Bacterial Communities Isolated from a Central Mojave Desert Soil Sample

: The arid Mojave Desert is one of the most signiﬁcant terrestrial analogue objects for astrobiological research due to its genesis, mineralogy, and climate. However, the knowledge of culturable bacterial communities found in this extreme ecotope’s soil is yet insufﬁcient. Therefore, our research has been aimed to fulﬁl this lack of knowledge and improve the understanding of functioning of edaphic bacterial communities of the Central Mojave Desert soil. We characterized aerobic heterotrophic soil bacterial communities of the central region of the Mojave Desert. A high total number of prokaryotic cells and a high proportion of culturable forms in the soil studied were observed. Prevalence of Actinobacteria , Proteobacteria , and Firmicutes was discovered. The dominance of pigmented strains in culturable communities and high proportion of thermotolerant and pH-tolerant bacteria were detected. Resistance to a number of salts, including the ones found in Martian regolith, as well as antibiotic resistance, were also estimated.


Introduction
One of the main tasks of modern astrobiology is studying environmental factors of different space bodies and outer space and to determine surviving and functioning limits of terrestrial life forms under extraterrestrial conditions [1,2].
It is known that potentially habitable space objects are exposed to a number of extreme abiotic factors, including high-intensity ionizing radiation, reduced pressure, contrast temperature conditions, low water availability, etc. [3][4][5]. Up to date, a large amount of data on physicochemical properties of regolith and climatic and cosmic regimes of various extraterrestrial bodies, in particular Mars, have been accumulated [6]. Based on these data, it can be stated that in today's biosphere of the Earth there are ecosystems that possess some environmental parameters similar to those found on extraterrestrial bodies. Hot-arid and cold-arid deserts, permafrost sedimentary rocks and some arid soils are considered as terrestrial analogues of extraterrestrial regolith [7][8][9] and are used as model objects in astrobiological research.
Microorganisms of arid ecosystems are exposed to a wide spectrum of stress factors such as water and organic matter deficiency, exposure to winds and high-intensity ultraviolet (UV) radiation, and significant temperature fluctuations. However, these areas are not lifeless and are characterized by In this paper, we studied the aerobic heterotrophic bacterial community and the physiological characteristics of cultured bacteria, isolated from the surface soil sample collected in the central part of the Mojave Desert.

Soil Sampling
A single soil sample was collected in the central part of the Mojave Desert in the summer of 2015 in a flat area devoid of vegetation (34 • 55'39.0" N 115 • 45'33.7" W). The surface soil was taken from 0-3 cm depth with no signs of vegetation and biological soil crust and put into a sterile polypropylene container. The sample was transported and stored at room temperature in an air-dry (natural) condition. Microbiological analyses were performed within one month after the sample collection.
The central region where the sample was taken from is characterized by the most typical climate of this desert: the temperature during the year varies from −10 to 50 • C, the average annual rainfall varies from 30 to 300 mm (arid-semi-arid climate type) [22]. It has been shown that the soil of this desert can be heated up to a temperature of 67 • C [29].
The Mojave tectonic block is a part of the Basin and Range tectonic province, where many asymmetrical basins have been formed during regional extension processes. The central Mojave region was formed during localized extension which occurred between 24 and 18.5 million years ago and produced 40-60 km of extended terrain space [41]. The central Mojave Desert is characterized by a variety of geologic surfaces that includes mountain ranges of diverse rock types, playas, ancient lake deposits, lava flows, sand-dune fields, alluvial fans, and riverbeds. The region of sample studied is underlain by middle Tertiary volcanic rocks, ranging mainly from andesitic to rhyolitic compositions [42].
The sample pH was 7.2. Literature data on the soils of this region indicate the content of organic matter in the range of 0.04-0.1%, total nitrogen content varies from 0.03% to 0.09% [22]. Soil sample texture is found to be sand. Dominance of silica and iron oxide-containing minerals was visually detected and confirmed by polarized light microscopy.

Epifluorescent Microscopy
The total number of prokaryotes in the samples was determined with epifluorescence microscopy (EFM) with acridine orange dye. Cell desorption was carried out by vortexing using Heidolph Multi Reax vortex for 30 min at 2000 rpm. The preparations were produced in six replicates, fixed by heating, then stained with water solution of acridine orange (1:10,000) for 3 min, washed in still distilled water for 20 min, dried at room temperature, and viewed under the Primo Star (Zeiss, Germany) microscope with fluorescence epi-illumination system (AmScope, Irvine, CA, USA) at 700× magnification for 20 fields of vision for each replication. Cells with green fluorescence were counted. The water used for the dilution preparation was simultaneously examined as control.
The prokaryotic cells number was calculated using the equation N = (S 1 × a × n)/(V × S 2 × c), where N is the number of cells per gram of soil; S 1 is the area of the preparation (µm 2 ); a is the number of cells in the field of view; n is the dilution index; V is the volume of the soil suspension drop placed on the glass (mL); S 2 is the field of view of the microscope (µm 2 ); and c is the sample weight (g) [43].
For the more complete characterization of the cultured bacterial community, culturing was performed at temperatures of 10, 25, and 50 • C (characteristic optima of psychrophilic, mesophilic, and thermophilic bacteria [17]) until the formation of visible macrocolonies was completed (typically for 14 days at 25 and 50 • C and 30 days at 10 • C). Colonies' morphotypes were distinguished by colour and morphology of the colonies as well as cell morphology. Isolated bacterial strains (Table A1) were deposited to the Astrobiological Collection of Microorganisms of the National Depository Bank of Live Systems "Noah's Ark" (Available at [46]).

Amplification and Sequencing of 16S rRNA Genes
For amplification of the 16S rRNA gene, biomass of pure bacterial culture that has been cultured for 2-3 days was subjected to boiling in Tris-EDTA buffer (pH 8.0) which contained 5% Triton X-100, and homogenization by mechanical destruction with sterile glass beads (250-300 µm in diameter) using a Homogenizer Minilys (Bertin Instruments, Montigny-le-Bretonneux, France) at 5000 rpm for 30 s. The resulting homogenate was centrifuged and the resulting supernatant was used as a DNA template for PCR [47].
For amplification of the gene of interest, the primer systems 27 f + Un1492 r [48,49], 63 f + 1387 r [47], 341 f + 805 r [50], and 27 f + 537 r [48,50] were used in order of priority. Amplification process was performed with cell lysate, prepared as described above. If the procedure failed to obtain the PCR product by the first primer system, the next primer system with the same DNA matrix was used and so on until a product that can be used for further sequencing was acquired [45].
The PCR products were purified and sequenced by the Research and Production Company "Evrogen" (Moscow, Russia) using the 1100 r [50], 805 r, or 537 r [51] primers (Table A2). The editing of the nucleotide sequences was carried out using Chromas Lite 2.01 [52]. For alignment, comparison and identification of nucleotide sequences, the Clustal Omega [53] and the BLAST algorithm from the GenBank database [54] were used. The sequences were deposited in GenBank under the accession numbers MK403768-MK403884.
The phylogenetic trees were constructed using MEGA 7 software [55]. Sequences were then aligned using the Clustal Omega online alignment tool [53]. The type material sequences from GenBank were predominantly used for phylogenetic trees construction. Strain identification was based upon phylogenetic analysis and similarity of the sequences with GenBank data.

Physiological Assays
The resistance spectra of all isolated cultures (121 strains) to various factor influences were obtained by culturing isolates on the same liquid medium that was used to isolate each particular strain from a natural sample; for each of the investigated factors the experiments were conducted in three replicates. To determine resistance to temperature, cultures were incubated in thermostats at temperatures of 2, 4, 10, 25, 37, 45, and 50 • C. Phosphate (KH 2 PO 4 + H 3 PO 4 final concentration of 100 mM, pH 2-6) and tris-alkaline (Tris + HCl + NaOH final concentration of 100 mM, pH 7-12) buffer systems were used to determine resistance to various pH levels. Bacterial strains' resistance to presence of salts was determined by aseptic preparation and subsequent dilution of 20% (w/v) stock solutions of NaCl, KCl, NaHCO 3 , MgSO 4 to final concentrations of 2, 5, 10, 15, and 20%; the series of magnesium perchlorate concentrations were prepared similarly by diluting a 20% (w/v) sterile stock solution to final concentrations of 0.5, 1, 2, 5, 10, and 15%. Antibiotic resistance was determined on nutrient media containing ampicillin (Amp), cephalexin (Ceph), chloramphenicol (Chl), tetracycline (Tet), doxycycline (Dox), kanamycin (Kan), or rifampicin (Rif ) (Belmed, Russia) with a final concentration of 100 µg/mL. All tests (except for resistance to temperature) were carried out at a temperature of 25 • C [44]. The growth was registered on the tenth day after inoculation for the cultures cultivated at temperatures of 10, 25, 37, 45, and 50 • C; for cultures growing at temperatures of Geosciences 2019, 9, 166 6 of 35 2 and 4 • C the incubation period was 60 and 30 days, respectively. Growth registering was performed using a Sunrise (Tecan, Menendov, Switzerland) plate photometer at a wavelength λ = 620 nm: The plates were measured immediately after inoculation and after incubation period. Detailed protocol of physiological assays is described in [44].

Multisubstrate Testing
To assess the potential metabolic activity of a microbial community, multisubstrate testing (MST) of the soil microbial community was performed [56,57]. The testing was carried out with 47 substrates including sugars, alcohols, amino acids, salts of organic acids, and polymers (all substrates are listed in [43], all tests were performed in two replicates). The soil sample was diluted (1:100) in sterile phosphate saline buffer (pH 7.4) and vortexed for 15 min at 2500 rpm using Heidolph Multi Reax vortex. The mineral particles were precipitated by centrifugation (2000 rpm, 2 min). The hydrogenase activity indicator (triphenyltetrazolium bromide) was added to the supernatant, and after mixing 200 µL aliquot was added to each well of a 96-well plate containing a set of 47 test substrates in two replicates. The plates were incubated at +28 • C for 96 h. After the incubation, the optical density of the solutions was measured photometrically at wavelength λ = 510 nm using a Sunrise (Tecan, Menendov, Switzerland) plate photometer.

Data Analysis
Statistical data processing was performed using the Microsoft Office Excel 2011 software package (Redmond, Washington, D.C., USA). For data on cell numbers, confidence intervals of the mean were calculated using Student's test at p < 0.05. When determining the physiological spectra, the results obtained in three replicates was considered a positive reaction. Indices of similarity and biodiversity of microbial communities were calculated according to Chernov and Lysak [58] at genera level of taxonomic affiliation.

Multisubstrate Testing
To assess the potential metabolic activity of a microbial community, multisubstrate testing (MST) of the soil microbial community was performed [56,57]. The testing was carried out with 47 substrates including sugars, alcohols, amino acids, salts of organic acids, and polymers (all substrates are listed in [43], all tests were performed in two replicates). The soil sample was diluted (1:100) in sterile phosphate saline buffer (pH 7.4) and vortexed for 15 min at 2500 rpm using Heidolph Multi Reax vortex. The mineral particles were precipitated by centrifugation (2000 rpm, 2 min). The hydrogenase activity indicator (triphenyltetrazolium bromide) was added to the supernatant, and after mixing 200 µL aliquot was added to each well of a 96-well plate containing a set of 47 test substrates in two replicates. The plates were incubated at +28 °C for 96 h. After the incubation, the optical density of the solutions was measured photometrically at wavelength λ = 510 nm using a Sunrise (Tecan, Menendov, Switzerland) plate photometer.

Data Analysis
Statistical data processing was performed using the Microsoft Office Excel 2011 software package (Redmond, Washington, D.C., USA). For data on cell numbers, confidence intervals of the mean were calculated using Student's test at p < 0.05. When determining the physiological spectra, the results obtained in three replicates was considered a positive reaction. Indices of similarity and biodiversity of microbial communities were calculated according to Chernov and Lysak [58] at genera level of taxonomic affiliation.

Culturable Communities' Structure
Pigmented forms of microorganisms dominated in all the cultured communities isolated from the sample. In the PYG medium plated communities, which were characterized by a higher cell counts, red-pigmented colonies were predominant and yellow-pigmented colonies were dominant on CM medium ( Figure 2). Maximum diversity of colony morphotypes was observed on PYG medium: 61 morphotypes were described in the course of culturing at mesophilic optimum; on CM medium 28 morphotypes were isolated under similar temperature conditions. At low temperature (10 • C), diversity decreased: 22 and 10 colony morphotypes were isolated on PYG and CM media, respectively ( Figure S1). In total 121 strains of aerobic heterotrophic bacteria were isolated from the investigated soil sample and subjected to further analysis.

Culturable Communities' Structure
Pigmented forms of microorganisms dominated in all the cultured communities isolated from the sample. In the PYG medium plated communities, which were characterized by a higher cell counts, red-pigmented colonies were predominant and yellow-pigmented colonies were dominant on CM medium ( Figure 2). Maximum diversity of colony morphotypes was observed on PYG medium: 61 morphotypes were described in the course of culturing at mesophilic optimum; on CM medium 28 morphotypes were isolated under similar temperature conditions. At low temperature (10 °C), diversity decreased: 22 and 10 colony morphotypes were isolated on PYG and CM media, respectively ( Figure S1). In total 121 strains of aerobic heterotrophic bacteria were isolated from the investigated soil sample and subjected to further analysis. Under similar conditions on CM medium, representatives of the genera Agrococcus Arthrobacter, Bacillus, Burkholderia, Cellulomonas, Massilia, Microbacterium, Paracoccus, Pontibacter, Pseudoarthrobacter, Salinibacterium, Sphingomonas, and Streptomyces were identified (listed in descending order of representation degree in the community, Figure 4).
Smaller diversity was observed in the community incubated under low temperature conditions. Bacteria of the genus Planomicrobium were dominant on PYG medium, subdominant positions were represented by species Arthrobacter agilis, and Planomicrobium glaciei, and representatives of Arthrobacter, Pseudarthrobacter, Leucobacter, Microbacterium, Massilia, Micrococcus, Pseudarthrobacter, Rhodococcus, and Sphingomonas genera were minor components of the culturable bacterial community ( Figure 5).
Smaller diversity was observed in the community incubated under low temperature conditions. Bacteria of the genus Planomicrobium were dominant on PYG medium, subdominant positions were represented by species Arthrobacter agilis, and Planomicrobium glaciei, and representatives of Arthrobacter, Pseudarthrobacter, Leucobacter, Microbacterium, Massilia, Micrococcus, Pseudarthrobacter, Rhodococcus, and Sphingomonas genera were minor components of the culturable bacterial community ( Figure 5).
On CM medium at low temperature, representatives of the Arthrobacter and Pseudarthrobacter genera accounted for 85% of all colonies cultured under these conditions; representatives of Cellulomonas and Streptomyces were identified as minor components ( Figure 6).        The coefficients of biological diversity, evenness, and similarity of bacterial communities, isolated from the examined site, are presented in Tables 1,2. The summarized communities' diversity data obtained are presented in   The coefficients of biological diversity, evenness, and similarity of bacterial communities, isolated from the examined site, are presented in Tables 1,2. The summarized communities' diversity data obtained are presented in Table A3. The phylogenetic trees of isolated strains are presented in Supplementary materials Figures S2-S4.  The coefficients of biological diversity, evenness, and similarity of bacterial communities, isolated from the examined site, are presented in Tables 1 and 2. The summarized communities' diversity data obtained are presented in Table A3. The phylogenetic trees of isolated strains are presented in Supplementary materials Figures S2-S4.

Multisubstrate Testing
Multisubstrate testing revealed a wide range of substrates suitable for development of the investigated microbial community. The most active substrate assimilation was observed on simple sugars, easily accessible polysaccharides (pullulan, starch, sucrose), lactate, Tween 80, and some amino acids (alanine, glutamine, and proline) ( Table 3).

Physiological Assays
Physiological assays were performed for all isolated 121 strains. Strains that were able to metabolize at low temperatures (up to 2 • C) were found to be more common than those that were able to grow at high temperatures. Thermotolerant strains that were able to metabolize at a temperature of 45 • C were found in communities isolated on both media at 25 • C. These strains made up 39% and 10% of the total number of strains in communities cultured on PYG and CM media, respectively. The strains capable to grow at 50 • C were only found in the community isolated on a rich medium at 25 • C, and made up 22% of the total number of isolates under these conditions (Figure 7a,b). Twenty percent of the strains isolated on PYG at 25 • C were able to metabolize at 2 • C and the same percentage was able to grow at 50 • C. At the same time, less than 20% of the community isolated on CM medium under similar conditions were metabolicaly active at 2 • C and only 10% of the community were able to grow at 45 • C. Higher levels of resistance to low temperatures were detected for strains isolated on CM medium at 10 • C. Amongst all investigated bacteria 10 strains were able to metabolize in extremely wide temperature range (2-4 -45-50 • C). Detailed characteristics of strain resistance are presented in Table S1.
All of the isolated strains were able to metabolize in the pH range of 6-8. The greatest resistance to pH of the medium was observed in the community isolated on CM medium at 25 • C: more than a half of the isolates were able to metabolize in a medium with pH of 3 and the same percentage was observed for pH of 12. Among communities isolated at 10 • C, the community isolated on CM medium (Figure 7c,d) was also characterized by a higher (by 20% on average) proportion of pH-tolerant strains. The pH range of strains' metabolic activity was shifted to the alkaline region and ranged from 3-12 pH units. Among all investigated bacteria 44 strains were able to metabolize in extremely wide pH range (3-4 -12 units). Detailed characteristics of strains' resistance are presented in Table S1.   Tests on media with addition of sodium chloride or potassium chloride revealed a moderate halotolerance of all the studied communities. Less than 50% of the strains retained metabolic activity in the presence of 5% NaCl. At the same time, 14% of the community isolated on PYG medium at 25 • C were capable to grow in the presence of 10% sodium chloride and 6% of the same community were able to metabolize on media containing 15% sodium chloride. In addition, almost the same level of resistance was revealed for the communities isolated on CM medium at 10 • C and 25 • C (Figure 7e,f).
Potassium chloride had a smaller inhibitory effect (on average two times smaller) on the examined communities: 14% of the strains isolated on PYG at 25 • C metabolized in a medium containing 15% of this salt; similarly to sodium chloride resistance, 80% of the strains isolated on CM at 25 • C were resistant to the presence of 2% KCl, and 10% were resistant in 10% solution (Figure 7g,h).
The presence of magnesium sulphate in the medium had a low inhibitory effect on all of the studied communities: 39% and 50% of the strains isolated on PYG medium at 25 • C and 10 • C respectively retained metabolic activity in presence of 20% magnesium sulphate. Seventy-three percent and 60% of the strains isolated on CM medium at 25 • C and 10 • C retained metabolic activity in the same conditions (Figure 8a,b).

Discussion
The total number of prokaryotes and numbers of culturable bacteria revealed in soil studied are in accordance with the previously obtained data for the soils of other regions of the Mojave Desert Sodium bicarbonate had the highest inhibitory effect among the studied water-soluble salts: few strains resistant to 5% of this salt in the culture medium were detected among the communities isolated on PYG and CM media at 25 • C (9% and 3% of strains, respectively) and among the community isolated on CM at 10 • C (10% of strains) (Figure 9).

Discussion
The total number of prokaryotes and numbers of culturable bacteria revealed in soil studied are in accordance with the previously obtained data for the soils of other regions of the Mojave Desert [32,36,37]. Different cell numbers observed in different regions of the desert could be caused by the high heterogeneity of soil composition and the high heterogeneity of soil resources in this desert, as well as past and current climatic conditions or plant associations which influence bacterial Strains of the community isolated on CM medium at 25 • C (33% of strains) were resistant to the presence of 10% magnesium perchlorate. The community isolated on PYG at 25 • C was resistant to concentrations of up to 5% of magnesium perchlorate (28% of strains) (Figure 8c,d). Furthermore, higher (on average by 20%) proportion of the strains isolated on CM medium showed high resistance to the presence of this salt in the medium compared to the strains isolated on PYG medium.
The individual ranges of resistance of the isolated strains to physicochemical stress factors are presented in supplementary materials (Table S1).
In general, the investigated communities showed low resistance to the presence of antibiotics-about 20% of isolates in each of the four communities were capable to grow in the presence of a single clinical antibiotic.
High resistance of strains isolated on CM medium at 25 • C to ampicillin, tetracycline, and cephalexin is noteworthy (Figure 8e,f). In all the communities the strains characterized with multiple antibiotic resistance were found. These strains were related to the genera Bacillus, Agrococcus, Arthrobacter, Leucobacter, Pseudarthrobacter, Planomicrobium, Massilia, Microbacterium, and Pontibacter (Table S2).

Discussion
The total number of prokaryotes and numbers of culturable bacteria revealed in soil studied are in accordance with the previously obtained data for the soils of other regions of the Mojave Desert [32,36,37]. Different cell numbers observed in different regions of the desert could be caused by the high heterogeneity of soil composition and the high heterogeneity of soil resources in this desert, as well as past and current climatic conditions or plant associations which influence bacterial communities [59,60]. At the same time, considering the climatic regime of the studied region, the absence of growth during the isolation of culturable bacteria at high (50 • C) temperature is worth noticing, whereas some strains isolated at lower temperatures (10 • C, 25 • C) were capable of growing at this temperature in axenic culture. This is probably due to the conditions of culturing and intra-and interpopulation interactions between microorganisms, which can complicate the transition from the state of metabolic dormancy to grow under stressful conditions [61][62][63]. It is notable that the numbers of bacteria cultured at 10 • C and 25 • C were virtually equal. Based on these data, it is possible to assume that there is a high proportion of strains with psychrotolerant properties in the investigated soil, as was previously found for bacteria isolated from the Sahara and the Gibson Desert soils [44].
Lower numbers of CFUs for CM nutrient medium could be explained by lack of vegetation coverage at the sampling site and, as a result, the rareness of plant origin carbon sources (such as starch and sucrose in CM medium) in the soil in situ [39]. In addition, these compounds require preliminary hydrolysis for further assimilation by the cells. However, not all bacteria can produce hydrolytic enzymes for assimilation of these substrates [61].
The predominance of pigmented bacteria in the studied surface soil of the Mojave Desert is not surprising due to the role of pigments in protecting cells from damaging ultraviolet radiation [63,64]. The maximum diversity of the community detected on the rich PYG medium under the conditions of mesophilic temperature optimum indicates a predominantly mesophilic strategy of development for the majority of the microbial community studied. Diversity decreases along with decreasing culturing temperatures and limiting of easily available carbon sources and growth factors (such as amino acids and vitamins) in the composition of the nutrient medium. Mesophilic development strategy common for the acquired isolates is probably due to the climatic conditions experienced by the soil sample. The development of psychrotolerant properties could be caused by a high contrast of both diurnal and seasonal temperatures and can be considered to be an adaptive feature under these conditions. The higher biodiversity of cultured bacteria on PYG medium is due to the diversity of carbon sources and the presence of growth factors (such as vitamins and amino acids), which can be used by a larger number of bacteria. The presence of growth factors may also contribute to the reactivation of cells that were in a state of metabolic rest [62].
Representatives of the Actinobacteria phylum were predominant in all of the cultured communities, representatives of the Proteobacteria phylum were the second most common ones, Firmicutes and Bacteriodetes were identified as minor components. The dominance of representatives of Proteobacteria phylum in the edaphic bacterial communities of the Mojave Desert has been shown based on the molecular-genetic tests [21,24]. Simultaneously, the results we obtained reveal the similar structure of bacterial communities in the studied soil of this desert, consistent with culture-independent data published earlier [10,32,33]. The predominance of Actinobacteria in the community is quite natural, considering the fact that many species among them are resistant to desiccation, UV radiation, and other stress effects [22]. Low abundance of representatives of the Firmicutes phylum was previously detected in the Mojave Desert [24]. Among all isolated strains low relative abundance of spore-forming bacteria was observed (seven isolates only), while a high abundance of genes associated with spore formation processes was found in situ by culture-independent methods [33].
The bacteria of genera Arthrobacter, Bacillus, Kocuria, Leucobacter, Massilia, Mycetocola, Microbacterium, Paracoccus, Planomicrobium, Pseudarthrobacter, Rufibacter, Sphingomonas, and Streptomyces were previously isolated from other hot deserts [44,[63][64][65]. Bacteria of the genus Agrococcus were previously cultured from cold deserts [66]. Among the representatives of the genus Brachybacterium several species connected to the root systems of halophilic plants were described and characterized by having plant growth-promoting potential [67]. Members of the genus Plantibacter, which have not been previously isolated from deserts, are also considered to be associated with herbaceous plants [68]. Representatives of the genus Cellulomonas are often isolated from soil [69] with some of them known to be halotolerant species [70]. Bacteria of the genus Pontibacter have been previously isolated from arid soils [71,72].
In this research, bacteria of the genera Janthinobacterium, which were found dominant in the meltwaters of glaciers [73], Salinibacterium, previously found in marine ecosystems and glaciers [74,75], and Labedella were isolated from desert soil for the first time.
Noteworthy is the discovery of the bacteria Planomicrobium glaciei in the desert soil. This species was first isolated from glacier, and after that from desert, ecosystems [76]. This allows us to assume that the intracellular mechanisms that determine the resistance and survivability of the species turn out to be adaptive in both cold and hot deserts.
According to community structure diagrams and ecological indices of communities' similarity, all the obtained communities differ from each other significantly. It indicates that culturing conditions (such as medium composition and cultivation temperature) are the main factors influencing the structure of the communities isolated from studied soil. Nevertheless, the genera represented in all cultured communities are quite similar.
It should be considered that transport of microorganisms by winds is possible [15], which is especially important in case of surface soil sampling. According to this fact, the presence of introduced bacteria could not being excluded. Both culture-dependent and culture-independent methods could not separate indigenous and introduced microorganisms. However, the sampling site is located in the central part of the Mojave Desert, thus minimizing the chance to long distant cell transport from non-desert regions. Thus, even if some of the isolates were not indigenous, they probably were introduced from the other desert sites. Moreover, virtually all representatives of genera isolated were previously detected in different desert soils. The resistance data obtained also testifies to the high adaptation to the desert conditions and confirms predominantly desert-associated strains were isolated.
Substrates on which the most active development of the examined community was observed, could be produced as metabolites of cyanobacteria [8]. This suggests a functional relationship between the previously shown metabolically active cyanobacterial communities in the studied soil of the Mojave Desert and the heterotrophic community studied by us that exists due to the presence of the primary organic substance of cyanobacterial origin. Based on the aforementioned facts and data on the taxonomic and morphological diversity of isolates, it can be presumed that the culturable bacterial community of the studied site in central Mojave Desert, which is considered to be a Mars analogue site, is functionally differentiated, and is highly adapted to harsh physicochemical conditions. These results are consistent with the data obtained previously in the other regions of this desert [32,33].
The analysis of the resistance of isolates to temperature reveals the thermotolerant properties of communities cultured at 25 • C. The expansion of the range of temperatures suitable for growth occurs mainly in the region of low temperatures, which is probably caused by daily and seasonal temperature fluctuations [19]. The highest resistance was recorded for the community isolated on PYG media at 25 • C, which is probably due to the high number of cells and diversity of this community.
The wide pH ranges in which the metabolic activity is maintained can be explained by contrast temperature conditions and precipitation regimes leading to a change in the solubility of the substances in the soil solution [22]. Higher levels of pH resistance of strains isolated on CM could be caused by their hydrolytic activity, often associated with changes in the pH of the solution [61].
The studied region is characterized by a low content of water-soluble salts [19,20,24], which could mean that the abundance of salts present in the studied sample is low. It explains the moderate general resistance of isolated communities to the presence of sodium chloride or potassium chloride. However, strains with high resistance (up to 15%) to sodium chloride were found. It was previously shown that the same physiological mechanism provides resistance for both desiccation and salinization, which could explains the obtained result [77,78].
High resistance to magnesium sulphate was previously shown for bacterial communities isolated from desert soils [44]. It is probably associated with the assimilation of the components of this salt as elements of mineral nutrition. Low resistance to sodium bicarbonate is associated with the hydrolytic alkaline nature of this salt and its local distribution in the desert in the form of soda lakes. The presence of resistant forms is probably caused by a slight aeolian transfer of sodium bicarbonate and bacteria adapted to its presence, as well as by the formation of this salt in situ during weathering processes [42,44].
High resistance to magnesium perchlorate is particularly important in the astrobiology-oriented review of the obtained results. Maintenance of metabolic activity in vitro in the presence of perchlorates, at concentrations significantly exceeding those found in the regolith of Mars [79], testifies their non-limiting role in the regolith. Resistance to oxidizing agents is also likely due to the physiological adaptation of bacteria to arid conditions [78]. The higher level of resistance of the community isolated on a rich medium (PYG) at 10 • C, compared with the one isolated at 25 • C on the same medium, can be explained by the physiological connection of processes that ensure adaptation to low temperatures and the presence of oxidizers [80]. It has previously been shown that bacterial communities of other desert soils are resistant to high perchlorate concentrations [44].
The highest levels of resistance to physicochemical stress factors were found in representatives of the genera Arthrobacter, Bacillus, Kocuria, Leucobacter, Microbacterium, Planomicrobium, and Pontibacter (Table S1). Representatives of these genera are widely distributed in desert soils and have previously demonstrated high resistance to various types of stress effects [15,17,22,25,44,59,66].
For the representatives of majority genera isolated from soil studied resistance to ionizing and UV radiation was shown ( [22,43,[81][82][83][84][85][86][87][88][89] and references therein). It is in accordance with pigmented colonies' high proportion data and it allows to suggest the presence of high UV-and radioresistance of the strains studied. Data on the resistance to physicochemical factors combined with the literature data on UV and ionizing radiation resistance could be considered as additional evidence of potential survivability of this bacterial community in Martian-like conditions. UV-and radioresistance of the isolates should be confirmed in further research.
The low resistance of the studied strains to antibiotics suggests that there is no active antibiotics-dependant competition in the communities. It is possible that the communities are realizing a co-metabolism strategy [90], as indirectly confirmed by the results of culturing on PYG medium and MST analysis: they revealed the most intensive growth of a cultured community on peptone containing various oligopeptides, amino acids, and vitamins. A similar result was obtained earlier in the study of the number of antibiotic resistance genes copies in the soils of the Mojave Desert [33]. At the same time, the discovery of a high number of antibiotic-resistant bacteria in the community isolated on CM medium at 25 • C is probably due to the signal role of antibiotics as quorum sensing agents [91,92] for activation of hydrolytic processes in the community. We have not found any previously published data on antibiotic resistance of representatives of Planomicrobium, Salinibacterium, and Labedella genera.

Conclusions
Stress effects, such as low water availability, nutrients deficiencies, high levels of solar radiation, and wide temperature fluctuations in the surface soil of the Mojave Desert lead to the formation of physiological survival strategies for prokaryotes existing under these conditions [2,3]. Our study revealed a high diversity (both taxonomic and morphophysiological) of culturable bacteria in the investigated soil. Species typical for various soils, including arid soils, and species that have not been previously isolated from hot arid soils were found in isolated bacterial communities. This suggests that the mechanisms of adaptation to cryo-arid and xero-arid conditions include similar physiological processes and adaptations. The obtained spectra of metabolic activity in the gradients of physicochemical factors indicate predominantly mesophilic and neutrophilic optima of all the studied strains, mostly capable of maintaining metabolic activity in a wide range of conditions, up to extreme ones for individual strains. Extreme resistance levels were identified in bacteria of Arthrobacter, Microbacterium, Bacillus, Planomicrobium, Kocuria, Leucobacter, and Pontibacter genera.
The obtained results, considered together with the data of previous works [25,41,64], testify in favour of viability, functionality, and taxonomical diversity of soil bacterial communities in the central part of the Mojave Desert studied, which is considered as a terrestrial analogue of Martian regolith. The isolated strains require further characterization and description for potential biotechnological applications. Due to the low similarity of the nucleotide sequences of some individual strains to those found in the database, these isolates could be the representatives of undescribed species of culturable bacteria. The most resistant strains that have been found could be used as model objects in further astrobiological studies.
As mentioned earlier, the Mojave Desert has undergone processes similar to those that took place on Mars and formed its current state. The properties of culturable bacterial communities revealed in this study indicate that they have adapted to survive in aggressive changing environmental conditions. Consequently, such communities could be considered as a model for further research of the Martian regolith habitability and the ability of terrestrial bacteria to adapt to extraterrestrial conditions. Supplementary Materials: The following are available online at http://www.mdpi.com/2076-3263/9/4/166/s1; Figure S1. Number of colonies' morphotypes in the communities studied; Figure S2a. Phylogenetic analysis tree of 16S rRNA genes of the strains isolated from the Mojave Desert soil, which were sequenced using 1100r primer; Figure S2b. Phylogenetic analysis subtree of 16S rRNA genes of the strains isolated from the Mojave Desert soil, which were sequenced using 1100 r primer; Figure S2c. Phylogenetic analysis subtree of 16S rRNA genes of the strains isolated from the Mojave Desert soil, which were sequenced using 1100 r primer; Figure S3. Phylogenetic analysis tree of 16S rRNA genes of the strains isolated from the Mojave Desert soil, which were sequenced using 805r primer; Figure S4. Phylogenetic analysis tree of 16S rRNA genes of the strains isolated from the Mojave Desert soil, which were sequenced using 537r primer; Table S1. Physiological characteristics of isolated bacteria, Table S2. Antibiotic resistance spectra of isolated strains.

Acknowledgments:
The authors express their respect to T. Yu. Ulyanova, who provided the soil sample from the Mojave Desert. The authors thank anonymous reviewers for the help in improving the article. The authors thank George A. Abashin for the help in language improving the article.

Conflicts of Interest:
The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing the manuscript, and in the decision to publish the results.