This study represents a polyphasic analysis of microbial communities from two caves in the Hindu Kush mountain range situated in the North-West region of Pakistan. The local names of those caves are Koat Maqbari Ghaar (KMG, 34°49′13.06″N, 72°30′41.81″E) and Smasse-Rawo Ghaar (SG, 34°33′38.1″N, 71°51′03.4″ E), and they are located in the Swat and Malakand division, respectively. The KMG cave is about 2.5m wide and 15m deep, and is located at about 1260m above sea level. The SRG cave has an almost horizontal orientation and around 2m wide, 10m long, and is located at 1062m above sea level. Both caves are of dried nature and very limitedly influenced by anthropogenic activities. Sediment samples in three replicates were collected from each cave using autoclaved and sterilized bottles. The samples were collected in February 2013. All of the samples were stored at 4°C for around 20h during transportation, and were immediately processed for culturing after arriving in the laboratory. A part of each sample was stored at −80°C for metagenomic DNA extraction. No specific permission was required for sampling the studied caves. These lands were not privately owned or protected in any way and the caves are not part of a national park or reserve. Our sampling did not involve endangered or protected species.

The pH of each sample was measured using Sartorius pH meters (Denver, Germany) in a 1/10 (w/v) saturated colloid solution of sediment in deionized water. Temperature was measured using ASTM thermometers (Gilson, USA) on each site. Total soil organic matter and total nitrogen were determined using the partial oxidation method and micro Kjeldahl method.13 Total phosphorus was measured colorimetrically.13 Physicochemical analysis were performed in triplicate for each sample.

Total DNA was extracted from each homogenized cave sediment replicates using the protocol for the PowerSoil® DNA extraction kit (Mo Bio Laboratories, Carlsbad). Amplification of the 16S rRNA gene hypervariable region V4 was performed using bar-coded 515F and 806R universal primers containing A and B sequencing adaptors, following the procedure previously described.14 PCR products were quantified using high-sensitivity Qubit technology (Invitrogen, USA), and were purified using Agencourt Ampure beads (Agencourt, USA). The 454 FLX–titanium pyrosequencing platform (Roche, Basel Switzerland) was used to perform high-throughput sequencing following the manufacturer's protocol. Raw pyrosequencing data was processed using the analysis pipeline of MR DNA (Texas, USA).14 Sequence reads <150bp were removed, and the remaining reads were screened for homopolymer runs exceeding 6bp, chimeric sequences, and sequences containing Ns; all of these were also excluded. Barcodes and primers were depleted from sequences. High quality sequence reads were clustered into OTUs using a threshold of 97% sequence similarity. For singleton reads the default value of 2 reads in QIIME v1.9 software was used to exclude from further analysis.15 OTUs were taxonomically classified using BLASTn against the curated databases GreenGenes, RDP (http://rdp.cme.msu.edu), and NCBI (www.ncbi.nlm.nih.gov).16 The alpha diversity analysis was performed with Chao1 and the non-parametric Shannon formula using QIIME v1.9 software.15

Sediment samples were serially diluted for the isolation of bacterial colonies with improved culture methods, based on an increased number of inoculation plates for each dilution, longer incubation times, selection of micro-colonies, and use of modified culture media as previously described.17 Briefly, two different concentrations of R2A medium (full strength 18g/L and half strength 9g/L) and diluted nutrient broth (1/5 strength 3g/L and 1/10 strength 1.3g/L) supplemented with 1.5% agar, 20% aqueous extract of the collected cave sediment, and two incubation conditions, 17°C and 37°C, were used to culture bacteria from the caves samples. The plates were incubated in aerobic condition for one week in seal plastic bags containing wet tissue papers to avoid drying of culture media during this long incubation. Colony forming units (CFU) were counted, and the CFU of the three replicates were used to estimate the size of the bacterial population. Colonies were purified by sub-culturing and then stored using a 15% glycerol stock in cryogenic vials at −80°C. Eighty-four isolates were selected for 16S rRNA gene sequencing based on the colony morphology and growth characteristics. Genomic DNA was extracted from the isolated strains using 1% Triton X-100 (Sigma) and boiling at 95°C for 20min. The 16S rRNA gene was amplified using the universal bacterial primers, 27F and 1492R, as described previously.17 Purified PCR products were sequenced with ABI Prism Sequencer 3730 (Applied Biosystems, USA) according to manufacturer's protocol. An analysis of chimeras in the 16S rRNA gene sequences was performed using Bellerophon software.18 Sequences were blasted at the EzTaxon server (http://www.ezbiocloud.net/) to identify the related type strains.19 A multiple sequence alignment was performed, and a phylogenetic tree was constructed by the neighbor-joining distance method using Jukes-Cantor model to compute evolutionary distance in MEGA6 software.20 Bootstrap values were calculated based on 1000 replications. The 16S rDNA sequences were deposited in GenBank (NCBI) under accession numbers KF747002–KF747085.

Antimicrobial activities of the isolated strains on growth of the pathogenic bacteria Salmonella typhi and Staphylococcus aureus, and the yeast Candida albicans were determined by confrontation bioassay using paper discs. A concentration of 0.5 McFarland of the target strains were spread on media-agar plates. Twenty microliters of each bacterial suspension containing approximately 108cfu/mL was added to a sterile paper disk (Advantec, Japan), and then discs were placed on the target strain plates. The plates were incubated for 72h at 25°C, and zones of inhibition around the paper discs were measured.21 Chloramphenicol (30μg/disk) and amphotericin-B (20μg/disk) were used as reference to estimate the antimicrobial activities of the tested isolates against bacteria and yeast respectively.

One-way ANOVA and Tukey's HSD (Honestly Significant Difference) tests were used to statistically compare physicochemical parameters, and CFU obtained at different media compositions and incubation temperature. The Statistical Package for the Social Sciences (SPSS) version 20 was used for the statistical analysis.

The pH values of KMG (7.6±0.21) and SRG (8.0±0.25) were not significantly (p=0.29) different from one another, and the sediment of SRG was slightly basic. Temperature of KMG was 14°C and SRG 17°C. Chemical analysis indicated that both caves were nutritionally poor. Total organic matter and nitrogen content in KMG (1.7±0.08% and 0.09±0.002%) and SRG (1.05±0.02% and 0.05±0.004%) were significantly (p=0.01 and p=0.001) different between the two caves. Phosphorus level in the KGM and SRG were 191.4±0.4ppm and 82.6±0.6ppm, respectively.

Taxonomic assignment of about 44,015 high-quality pyrosequencing reads from KMG (23,838) and SRG (20,177) were obtained using the V4 region of the 16S rRNA gene. The taxonomic composition of the bacterial communities was highly diverse in both caves sediments. The majority of the identified operational taxonomic units (OTUs), defined by 97% sequence similarity, were affiliated with 21 phyla that included 19 bacterial phyla, 2 archaea, and 20 candidate phyla. Among the identified phyla, 10 phyla and 5 candidates divisions were detected in both caves. The percentage sequence reads from KMG and SRG were affiliated with 6 bacterial phyla detected at relatively higher abundance including; Proteobacteria, Bacteroidetes, Actinobacteria, Firmicutes, Verrucomicrobia and Planctomycetes (Fig. 1). Among the Proteobacteria, α-Proteobacteria (45.6% KMG and 34.1% SRG) and γ-Proteobacteria (35.2% KMG and 32.1% SRG) were dominant in both caves, followed by δ-Proteobacteria (12.6% KMG and 16.9% SRG) and β-Proteobacteria (9.2% KMG and 16.7% SRG). The phylum Deinococcus-Thermus was detected only in KMG (6.8%), and WS3 (candidate division, 4.3%) was detected in SRG. The 15 candidate divisions and 10 bacterial phyla, including 2.9% Acidobacteria, 2.8% KSB1, and 1.2% OP3 (candidate division), were detected specifically in SRG. The archaeal phylum Euryarchaeota was detected at 3.4% and 0.2% abundance in KMG and SRG, respectively. Cyanobacteria were detected at <1% abundance in both caves.

Fig. 1.

Distribution of microbial phyla and candidate divisions detected at relatively higher abundance in the KMG and SRG caves. Percentage abundance from KMG are shown on the x-axis and from SRG on the y-axis. The category “others” represents microbial phyla and candidate divisions that were present at <1% abundance in each cave. KMG, Koat Maqbari Ghaar; SRG, Smasse-Rawo Ghaar.

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A total of 498 different genera were detected. The highest number of genera (445) was detected in SRG, while 235 genera were present in KMG. Among these, 185 genera were present in both caves, while 53 genera were specifically detected in KMG and 263 in SRG. Moreover, 17 genera in KMG and 21 genera in SRG were present at an abundance ≥1%, accounting for 74% and 58% of the total sequence reads in the respective samples (Fig. 2). In KMG, the following bacterial genera were detected at relatively high abundances: Cellvibrio (17.1%), Saccharophagus (15.5%), Bacillus (7.6%), and Deinococcus (6.6%). In SRG, the dominant genera were Chthoniobacter (6.9%), Opitutus (6.6%), Chondromyces (3.4%), Rubrobacter (3.4%), Rhodoplanes (3.1%), and Prosthecobacter (3%). Only the genus Cytophaga was present in both caves at ≥1% abundance.

Fig. 2.

Percentage distribution of the relatively dominant genera detected in the KMG and SRG caves. KMG, Koat Maqbari Ghaar; SRG, Smasse-Rawo Ghaar.

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In the next step, we analyzed the OTUs at species level in the KMG and SRG caves. A total of 873 different species were identified, including 384 species in KMG and 628 species in SRG. Only 139 species were present in both caves. In each cave, more than 60% species were affiliated with four bacterial phyla: Proteobacteria, Firmicutes, Bacteroidetes, and Actinobacteria. In total, 170 (44.3%) identified species from KMG and 309 (35.4%) from SRG were affiliated with Proteobacteria. Among them, 89 species were commonly present in both caves including Saccharophagus degradans and Lysobacter spongicola that were present at relatively higher abundance in KMG, and were detected at <0.01% abundance in SRG (Fig. 3). The Haliangium spp. and Bradyrhizobium lupini were present at higher abundances in SRG than in KMG. The species Cellvibrio ostraviensis, Cellvibrio japonicus, and Teredinibacter turnerae were dominant and specific to KMG. While, Rhodoplanes spp., Methylosinus trichosporium, Chondromyces crocatus, Rhodocyclus tenuis, and Chondromyces apiculatus were specifically detected in SRG at ≥1% abundance. From the phylum Firmicutes, 250 different species were identified including 27 species that were commonly present in both caves. While, 79 Firmicutes associated species were specifically detected in KMG and 71 species OTUs were specific to SRG. Only the species; Ammoniphilus oxalaticus, Bacillus asahii, Sporosarcina ginsengisoli, and Virgibacillus halodenitrificans were detected at >1% abundance in KMG. Other Firmicutes species were detected at <1% abundance in KMG and SRG. From the phylum Actinobacteria, Rubrobacter xylanophilus and Acidimicrobium ferrooxidans were detected in both cave but present at relative higher abundance in SRG. Actinomadura napierensis and Candidatus solibacter were the two dominant spices detected at >1% abundance specifically in KMG and SRG, respectively. From the phylum Bacteroidetes, Cytophaga hutchinsonii was detected at a relatively high abundance in both caves. The species Chitinophaga flexibacter and Segetibacter spp. were more abundant in the SRG, and Persicobacter diffluens and Rhodothermus marinus were detected at >1% abundance in KMG. Apart from the OTUs at species level from dominant phyla, the C. solibacter usitatus, Opitutus terrae and Planctomyces brasiliensis were detected at relatively higher abundance in SRG sample. The Gram-negative bacterium Deinococcus papagonensis and Halococcus hamelinensis from archaea phylum Euryarchaeota were specifically detected in KMG (Fig. 3).

Fig. 3.

Percentage distribution of relatively dominant OTUs at species level detected in ≥1% at least in one cave. KMG, Koat Maqbari Ghaar; SRG, Smasse-Rawo Ghaar.

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Chao1 and Shannon indices were calculated to estimate alpha diversity. Rarefaction curves were established at a 97% sequence similarity level to define OTUs. In rarefaction curves, both samples were tended to approach saturation plateau, and the samples SRG was plotted in the upper part of the graph (Fig. 4A). The Chao1 analysis demonstrated a decreased trend of richness in the sample KMG (3622) compared to SRG (4701, Fig. 4B). The Shannon diversity index for KMG was 9.0 and for SRG was 10.0, indicating high diversity in both caves (Fig. 4C). However, species diversity in SRG was higher than that of KMG.

Fig. 4.

Alpha diversity of the sequence reads. (A) Rarefaction curves of the experimentally observed OTUs versus diversity (B) estimated by Chao1. (C) Boxplots of the Shannon index. KMG, Koat Maqbari Ghaar; SRG, Smasse-Rawo Ghaar.

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Incubation at 37°C and in full-strength R2A medium yielded higher numbers of bacteria from both caves KMG (8.5) and SRG (8.4) (counts expressed as log10cfu/g) that were significantly (p<0.05) higher than the CFU obtained from all other tested culture media and temperature used in this study. From incubation at 17°C, significantly higher numbers of bacteria were noticed on half-strength R2A from KMG (7.5), and on full-strength R2A from SRG (7.7) compared to other tested media with respective samples. Overall, the recovery of viable bacteria colonies was higher at 37°C than at 17°C. Initially, 350 strains were purified on the basis of colony morphologies and were screened for antimicrobial activity. The 16S rRNA genes of 84 isolates from the two caves were sequenced, and they displayed 96.2–100% identity to the sequences available in GenBank, and were assigned to major bacterial groups using phylogenetic analysis (Fig. 5). Three strains showed <97% sequence similarity with the closest related type strain, suggesting as candidate novel species. Proteobacteria was the dominant phylum among KMG isolates (52.6%), and representing 25.9% of isolates from SRG. The γ-Proteobacteria sequences represented majority of isolates from KMG (43.5%) and SRG (11.1%). α-Proteobacteria and β-Proteobacteria sequences were evident in 8.8% of KMG isolates, and 14.8% of isolates from SRG were affiliated with α-Proteobacteria. Firmicutes and Actinobacteria accounted for 40.4% and 7%, respectively, of isolates from KMG. Firmicutes was the dominant phylum in SRG (71.4%), and no Actinobacteria isolates were detected from SRG. Cultured isolates from both caves were classified into 14 distinct genera. Majority of the isolates were associated with the genera Pseudomonas (40.3% KMG and 11.1% SRG) and Bacillus (22.8% KMG and 44.4% SRG). In total 39 distinct species were identified among the cultured isolates from both caves. Four species were common between the two caves. Twenty-six species were unique to KMG, and 9 species were specifically detected in SRG. The following four species, Exiguobacterium undae, Pseudomonas koreensis, Sphingomonas melonis, and Pseudomonas mosselii were isolated from the sediment of both caves. In KMG, the dominant cultured species was P. koreensis, followed by Bacillus humi, Pseudomonas peli, Pseudomonas baetica, and Pseudomonas cremoricolorata. In SRG, the dominant cultured species were Paenibacillus lautus, Bacillus timonensis, Bacillus simplex, and Caulobacter vibrioides.

Fig. 5.

Phylogenetic analysis based on 16S rRNA gene sequences of the bacterial isolates. The neighbor-joining clustering method was used to construct the tree. Bootstrap values were calculated based on 1000 replications and are shown at branch points. The bar represents 0.01 sequence divergence. Sequences derived from the NCBI GenBank database are shown with their accession numbers. Filled circles following the experimental sequence names correspond to KMG, and non-filled circles correspond to SRG. KMG, Koat Maqbari Ghaar; SRG, Smasse-Rawo Ghaar.

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Thirty strains showed antimicrobial activity among the total isolates from both caves (Table 1). Fifteen strains showed antibacterial activity against S. typhi, and 20 strains were active against S. aureus. Six strains showed antibacterial activity against both bacterial pathogens tested. Isolated strains belonging to the genera Pseudomonas and Bacillus were more antagonistic, as demonstrated strong antimicrobial activity against tested pathogenic bacteria. Only two strains, which showed around 100% sequence similarity with Brevibacillus borstelensis and P. mosselii, inhibited the growth of the human fungal pathogen C. albicans.