Stable coexistence of five bacterial strains as a cellulose-degrading community

A cellulose-degrading defined mixed culture (designated SF356) consisting of five bacterial strains (Clostridium straminisolvens CSK1, Clostridium sp. strain FG4, Pseudoxanthomonas sp. strain M1-3, Brevibacillus sp. strain M1-5, and Bordetella sp. strain M1-6) exhibited both functional and structural stability; namely, no change in cellulose-degrading efficiency was observed, and all members stably coexisted through 20 subcultures. In order to investigate the mechanisms responsible for the observed stability, "knockout communities" in which one of the members was eliminated from SF356 were constructed. The dynamics of the community structure and the cellulose degradation profiles of these mixed cultures were determined in order to evaluate the roles played by each eliminated member in situ and its impact on the other members of the community. Integration of each result gave the following estimates of the bacterial relationships. Synergistic relationships between an anaerobic cellulolytic bacterium (C. straminisolvens CSK1) and two strains of aerobic bacteria (Pseudoxanthomonas sp. strain M1-3 and Brevibacillus sp. strain M1-5) were observed; the aerobes introduced anaerobic conditions, and C. straminisolvens CSK1 supplied metabolites (acetate and glucose). In addition, there were negative relationships, such as the inhibition of cellulose degradation by producing excess amounts of acetic acid by Clostridium sp. strain FG4, and growth suppression of Bordetella sp. strain M1-6 by Brevibacillus sp. strain M1-5. The balance of the various types of relationships (both positive and negative) is thus considered to be essential for the stable coexistence of the members of this mixed culture.     

Isolation, characterization and evaluation of hyper 2-propanol producing bacteria from Singapore environment

Three hyper 2-propanol producing strains were isolated from Singapore environment using an enrichment step and a high through-put screening step. The analysis of the amplified 16S rDNA revealed that the isolates belonged to Clostridium species and they were named as Clostridium sp. BT10-1, Clostridium sp. M10-1 and Clostridium sp. PU31-4. At 1 L scale, the 2-propanol titer of these positive strains was 1.6–2.1 times of that of Clostridium beijerinckii NRRL B593, which is so far the most efficient natural 2-propanol producer. The highest 2-propanol titer was achieved by isolate BT10-6 and it was 5.26 g/L (87.5 mM). These three positive strains BT10-6, M10-1 and PU31-4 consumed glucose almost completely in 40–48 h and gave 2-propanol productivity at 0.132, 0.118 and 0.087 g/L/h, respectively, which is 3.0–4.6 times of 0.029 g/L/h given by C. beijerinckii NRRL B593. Butanol was also produced by these positive strains with a slightly lower butanol titer and higher butanol productivity, compared to butanol control strain C. beijerinckii NCIMB 8052.     

Efficiency of natural and engineered bacterial strains in the degradation of 4-chlorobenzoic acid in soil slurry

Two bacterial strains, the natural isolate Arthrobacter sp. FG1 and the engineered strain Pseudomonas putida PaW340/pDH5, were compared for their efficiency in the degradation of 4-chlorobenzoic acid in a slurry phase system. The recombinant strain was obtained by cloning the Arthrobacter sp. FG1 dehalogenase encoding genes in P. putida PaW340. In the slurry inoculated with pre-adapted cultures of Arthrobacter sp. FG1, the 4-chlorobenzoic acid degradation was found to be slower than that observed in the slurry inoculated with the recombinant strain P. putida PaW340/pDH5, regardless of the presence or absence of soil indigenous bacteria. Slurry inoculated with mixed cultures of Arthrobacter sp. FG1 and the 4-hyroxybenzoic acid degrader P. putida PaW340 did not show any improvement in 4-chlorobenzoic acid degradation.     

Isolation,identification of sludge-lysing strain and its utilization in thermophilic aerobic digestion for waste activated sludge

A strain of sludge-lysing bacteria was isolated from waste activated sludge (WAS) in this study. The result of 16S rRNA gene analysis demonstrated that it was a species of new genus Brevibacillus (named Brevibacillus sp. KH3). The strain could release the protease with molecule weight of about 40 kDa which could enhance the efficiency of sludge thermophilic aerobic digestion. During the sterilized sludge digestion experiment inoculated with Brevibacillus sp. KH3, the maximum protease activity was 0.41 U/ml at pH 8 and 50 °C, and maximum TSS removal ratio achieved 32.8% after 120 h digestion at pH 8 and 50 °C. In the case of un-sterilized sludge digestion inoculated with Brevibacillus sp. KH3, TSS removal ratio in inoculated-group was 54.8%, increasing at 11.86% compared with un-inoculation (46.2%). The result demonstrated that inoculation of Brevibacillus sp. KH3 could help to degrade the EPS and promote the collapse of cells and inhibit the growth of certain kinds of microorganisms. It indicated that Brevibacillus sp. KH3 strain had a high potential to enhance WAS-degradation efficiency in thermophilic aerobic digestion.     

Enrichment,isolation, and characterization of phenol-degrading Pseudomonas resinovorans strain P-1 and Brevibacillus sp. strain P-6

The objectives of this research were to isolate pure phenol-degrading strains from enriched mixed cultures, monitoring the variations of species during the enrichment period. Two strains were isolated from the acclimated mixed culture. They were identified as Pseudomonas resinovorans strain P-1 and Brevibacillus sp. strain P-6. DGGE indicated that strain P. resinovorans appeared at the beginning, and maintained well during the enrichment period. The second strain, Brevibacillus sp., did not appear in the initial stage, but showed up after 2 weeks of enrichment. The optimum growth temperatures for P. resinovorans and Brevibacillus sp. were 31 and 39 °C, respectively. P. resinovorans could degrade phenol completely within 57.5 h, when the initial phenol concentration was lower than 600 mg l⁻¹. If the initial phenol concentration was lower than 200 mg l⁻¹, Brevibacillus sp. could remove phenol completely within 93.1 h. It was obvious that the phenol-degrading ability of P. resinovorans was much better than that of Brevibacillus sp. The metabolic pathway for P. resinovorans phenol degradation was assigned to the meta-cleavage activity of catechol 2,3-dioxygenase.     

Enrichment and characterization of an anaerobic cellulolytic microbial consortium SQD-1.1 from mangrove soil

Enrichment of microbial consortia provides an approach to simulate and investigate microbial communities in natural environments. In this study, a cellulolytic microbial consortium SQD-1.1 was enriched from mangrove soil of Qinglan port (Hainan, China) by 27 times continuous subcultivation under anaerobic static conditions. The consortium could completely degrade 0.2 % (w/v) filter paper within 3 days and utilized it as the sole carbon source. PCR-denaturing gradient gel electrophoresis analysis revealed a stable microbial community structure in the incubation process of 10 days and in the procedure of subcultivation. Twenty-four operational taxonomic units belonging to seven phyla were obtained from the full-length 16S rRNA gene library. Five clones, closest related to the genera Alkaliflexus, Clostridium, Alistipes, Spirochaeta, and Trichococcus, were the predominant ones. Among them, M117, phylogeneticly showing high similarity (16S rRNA gene identity, 95.3 %) with the cellulolytic anaerobic bacterium Clostridium straminisolvens CSK1^T, was the potential key cellulolytic bacterium. Using the plate cultivation method, 12 strains, including one potential new species and four potential new species of new genera, were isolated. The strain P2, corresponding to the most frequently detected clone (M05) in the 16S rRNA gene library, showed both CMCase and xylanase activity and may be another important cellulolytic bacterium. The findings of cellulase activity in cell pellet and cohesion and dockerin domains in metagenome data further suggested the potential of utilization of cellulosomes by the consortium to degrade cellulose. Consortium SQD-1.1 provides a candidate for investigating the mechanism of cellulose degradation under anoxic conditions in natural environments.     

Isolation and Characterization of a New Clostridium sp. That Performs Effective Cellulosic Waste Digestion in a Thermophilic Methanogenic Bioreactor

A methanogenic bioreactor that utilized wastepaper was developed and operated at 55°C. Microbial community structure analysis showed the presence of a group of clostridia that specifically occurred during the period of high fermentation efficiency. To isolate the effective cellulose digester, the sludge that exhibited high fermentation efficiency was inoculated into a synthetic medium that contained cellulose powder as the sole carbon source and was successively cultivated. A comprehensive 16S rRNA gene sequencing study revealed that the enriched culture contained various clostridia that had diverse phylogenetic positions. The microorganisms were further enriched by successive cultivation with filter paper as the substrate, as well as the bait carrier. A resultant isolate, strain EBR45 (= Clostridium sp. strain NBRC101661), was a new member of the order Clostridiales phylogenetically and physiologically related to Clostridium thermocellum and Clostridium straminisolvens. Specific PCR-based monitoring demonstrated that strain EBR45 specifically occurred during the high fermentation efficiency period in the original methanogenic sludge. Strain EBR45 effectively digested office paper in its pure cultivation system with a synthetic medium.     

Metabolites produced by <Emphasis Type="Italic">Pseudomonas</Emphasis> sp. enable a Gram-positive bacterium to achieve extracellular electron transfer

Previous studies revealed the abundance of Pseudomonas sp. in the microbial community of a microbial fuel cell (MFC). These bacteria can transfer electrons to the electrode via self-produced phenazine-based mediators. A MFC fed with acetate where several Pseudomonas sp. were present was found to be rich in a Gram-positive bacterium, identified as Brevibacillus sp. PTH1. Remarkably, MFCs operated with only the Brevibacillus strain in their anodes had poor electricity generation. Upon replacement of the anodic aqueous part of Brevibacillus containing MFCs with the cell-free anodic supernatants of MFCs operated with Pseudomonas sp. CMR12a, a strain producing considerable amounts of phenazine-1-carboxamide (PCN) and biosurfactants, the electricity generation was improved significantly. Supernatants of Pseudomonas sp. CMR12a_Reg, a regulatory mutant lacking the ability to produce PCN, had no similar improvement effect. Purified PCN, together with rhamnolipids as biosurfactants (1 mg L⁻¹), could clearly improve electricity generation by Brevibacillus sp. PTH1, as well as enable this bacterium to oxidize acetate with concomitant reduction of ferric iron, supplied as goethite (FeOOH). When added alone, PCN had no observable effects on Brevibacillus’ electron transfer. This work demonstrates that metabolites produced by Pseudomonas sp. enable Gram-positive bacteria to achieve extracellular electron transfer. Possibly, this bacterial interaction is a key process in the anodic electron transfer of a MFC, enabling Brevibacillus sp. PTH1 to achieve its dominance. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

UVC-mutagenesis in acetogens: resistance to methanol,ethanol, acetone,or n-butanol in recombinants with tailored genomes as the step in engineering of commercial biocatalysts for continuous CO2/H2 blend fermentations

Time- and cost-efficient six-step UVC-mutagenesis was developed and validated to generate acetogen mutants with preliminary reduced genomes to prevent product inhibition in the to-be-engineered commercial biocatalysts. Genome reduction was performed via elimination of pta, ack, spo0A, spo0J and some pro-phage genes. UVC-mutants such as Clostridium sp. MT1784RG, Clostridium sp. MT653RG, Clostridium sp. MT896RG, and Clostridium sp. MT1962RG (all 4 share 97 % DNA homology with Clostridium ljungdahlii ATCC 55383) were selected based on resistance to methanol (3 M), ethanol (3.6 M), acetone (2.5 M), or n-butanol (0.688 M), respectively. As a part of the biocatalyst engineering algorithm, genome reduction step was associated with integration of attTn7 recognition sequence to the chromosomes of each of the above strains to prepare the defined integration sites for future integration of multi-copy synthetic operons encoding biosynthesis of methanol, ethanol, acetone or n-butanol. Reduced genome mutants had cell duplication times decreased compared to the same for the respective parental strains. All groups of mutants had decreased share of palmitic (C16:0) and increased share of oleic (C18:1) acids along with detection of isopropylstearate (C20) compared to the parental strains. Mutants resistant to acetone and n-butanol also had monounsaturated fatty acid (C20:1) not found in parental strains. Cyclopropane fatty acid (C21) was identified only in n-butanol resistant mutants.     

Identification, Detection, and Spatial Resolution of Clostridium Populations Responsible for Cellulose Degradation in a Methanogenic Landfill Leachate Bioreactor

An anaerobic landfill leachate bioreactor was operated with crystalline cellulose and sterile landfill leachate until a steady state was reached. Cellulose hydrolysis, acidogenesis, and methanogenesis were measured. Microorganisms attached to the cellulose surfaces were hypothesized to be the cellulose hydrolyzers. 16S rRNA gene clone libraries were prepared from this attached fraction and also from the mixed fraction (biomass associated with cellulose particles and in the planktonic phase). Both clone libraries were dominated by Firmicutes phylum sequences (100% of the attached library and 90% of the mixed library), and the majority fell into one of five lineages of the clostridia. Clone group 1 (most closely related to Clostridium stercorarium), clone group 2 (most closely related to Clostridium thermocellum), and clone group 5 (most closely related to Bacteroides cellulosolvens) comprised sequences in Clostridium group III. Clone group 3 sequences were in Clostridium group XIVa (most closely related to Clostridium sp. strain XB90). Clone group 4 sequences were affiliated with a deeply branching clostridial lineage peripherally associated with Clostridium group VI. This monophyletic group comprises a new Clostridium cluster, designated cluster VIa. Specific fluorescence in situ hybridization (FISH) probes for the five groups were designed and synthesized, and it was demonstrated in FISH experiments that bacteria targeted by the probes for clone groups 1, 2, 4, and 5 were very abundant on the surfaces of the cellulose particles and likely the key cellulolytic microorganisms in the landfill bioreactor. The FISH probe for clone group 3 targeted cells in the planktonic phase, and these organisms were hypothesized to be glucose fermenters.     

Characterization of biosurfactant produced by Pseudoxanthomonas sp. PNK-04 and its application in bioremediation

Biosurfactant producing bacterium was identified as Pseudoxanthomonas sp. PNK-04 based on morphological, physiological, biochemical tests and 16S rRNA gene sequencing. This strain was screened for biosurfactant production using different carbon sources by measuring the surface tension of the medium at different time intervals, and hemolytic activity. The produced biosurfactant was found to be a rhamnolipid based on the formation of dark blue haloes around the colonies in CTAB–methylene blue agar plates and the content of rhamnose sugar. The rhamnolipids produced by this bacterium were found to contain mono- and dirhamnose units linked to β-hydroxy alkonic acids containing 8–12 carbon atoms. This biosurfactant has high emulsifying activity when compared to chemical surfactants such as Tween-80 and Triton X-100 with respect to aliphatic and aromatic hydrocarbons. Further, the biosurfactant stimulates the degradation of 2-chlorobenzoic acid, 3-chlorobenzoic acid and 1-methyl naphthalene by Pseudoxanthomonas sp. PNK-04 probably by aiding in the uptake and increasing the solubility.     

Identification, purification and characterization of laterosporulin, a novel bacteriocin produced by Brevibacillus sp. strain GI-9

Background

Bacteriocins are antimicrobial peptides that are produced by bacteria as a defense mechanism in complex environments. Identification and characterization of novel bacteriocins in novel strains of bacteria is one of the important fields in bacteriology.

Methodology/Findings

The strain GI-9 was identified as Brevibacillus sp. by 16 S rRNA gene sequence analysis. The bacteriocin produced by strain GI-9, namely, laterosporulin was purified from supernatant of the culture grown under optimal conditions using hydrophobic interaction chromatography and reverse-phase HPLC. The bacteriocin was active against a wide range of Gram-positive and Gram-negative bacteria. MALDI-TOF experiments determined the precise molecular mass of the peptide to be of 5.6 kDa and N-terminal sequencing of the thermo-stable peptide revealed low similarity with existing antimicrobial peptides. The putative open reading frame (ORF) encoding laterosporulin and its surrounding genomic region was fished out from the draft genome sequence of GI-9. Sequence analysis of the putative bacteriocin gene did not show significant similarity to any reported bacteriocin producing genes in database.

Conclusions

We have identified a bacteriocin producing strain GI-9, belonging to the genus Brevibacillus sp. Biochemical and genomic characterization of laterosporulin suggests it as a novel bacteriocin with broad spectrum antibacterial activity.     

Bile Salt Degradation by Nonfermentative Clostridia

Eight strains of nonfermentative clostridia were characterized on the basis of their intracellular nicotine adenine dinucleotide- and nicotinamide adenine dinucleotide phosphate-dependent hydroxysteroid dehydrogenase (HSDH) content, ability to deconjugate taurocholate, growth characteristics, and metabolic products, including utilization of lactate and pyruvate. Two cultures of Clostridium sporosphaeroides (representing one strain obtained from two different sources), one strain of Clostridium irregularis, four strains of an unnamed species (Clostridium group SPH-1), and one strain of an unnamed species (Clostridium group P) were studied. Both cultures of C. sporosphaeroides contained low amounts of 7α-HSDH; C. irregularis contained only a low amount of 3α-HSDH. All four strains of Clostridium SPH-1 contained both 12α- and 7α-HSDH in the ratio of approximately 10:1. The strain of Clostridium group P contained only 12α-HSDH and was devoid of any other bile salt oxidoreductases. The enzyme preparation from Clostridium group P was useful in spectrophotometric quantitative studies of 12α-OH groups. Correlation of bile salt degradative activities with other phenotypic tests for characterization of and differentiation among such organisms is discussed.     

Molecular characterization and estimation of cellulolytic potential of gut bacteria isolated from four white grub species native to Indian Himalayas

An investigation was carried out to isolate, identify and molecularly characterize the cellulose-degrading bacterial isolates from the guts of four white grub species (Anomala bengalensis, Brahmina coriacea, Holotrichia longipennis and Holotrichia setticollis) native to Uttarakhand, Himalayas through 16S rRNA sequencing. A total of 178 bacterial strains were isolated from different gut compartments of selected white grub species, of which 95 bacterial isolates showed cellulose metabolizing activities in the CMC assay. Maximum degraders i.e., 38 were isolated from A. bengalensis, of which 18 were isolated from the fermentation chamber. The value of cellulolytic index ranged between 0.05 and 16 showing a variable cellulolytic activity by degraders. A total of 25 potent strains of cellulose-degrading bacteria recording cellulolytic activity > 1 were isolated and sequenced for 16S rRNA gene. Bacillus stratosphericus strain CBG4MG1 (10.78 ± 4.18), Bacillus cereus strain CBG2FC1 (10.33 ± 3.53), Bacillus sp. strain CBG3MG2 (7.28 ± 0.16) and Paenibacillus ginsengagri strain CBG1FC2 (5.66 ± 2.67) were the most potent cellulose-degrading bacteria isolated from the gut of B. coriacea, H. longipennis, H. setticollis and A. bengalensis, respectively. Thus, the cellulolytic bacteria isolated from the gut of selected white grub species may be good sources for profiling novel isolates for industrial use besides identifying eco-friendly solutions for agro-waste management.     

ε-Caprolactam Utilization by Proteus sp. and Bordetella sp. Isolated From Solid Waste Dumpsites in Lagos State, Nigeria, First Report

The ε-caprolactam is the monomer of the synthetic non-degradable nylon-6 and often found as nonreactive component of nylon-6 manufacturing waste effluent. Environmental consequences of its toxicity to natural habitats and humans pose a global public concern. Soil samples were collected from three designated solid waste dumpsites, namely, Abule-Egba, Olusosun and Isheri-Igando in Lagos State, Nigeria. Sixteen bacteria isolated from these samples were found to utilize the ε-caprolactam as a sole source of carbon and nitrogen at concentration of ≤20 g l^?1. The isolates were characterized using their 16S rRNA gene sequence and showed similarity with Pseudomonas sp., Proteus sp., Providencia sp., Corynebacterium sp., Lysinibacillus sp., Leucobacter sp., Alcaligenes sp. and Bordetella sp. Their optimal growth conditions were found to be at temperature range of 30 to 35 °C and pH range of 7.0–7.5. High Performance liquid chromatography analysis of the ε-caprolactam from supernatant of growth medium revealed that these isolates have potential to remove 31.6–95.7 % of ε-caprolactam. To the best of our knowledge, this study is first to report the ability of Proteus sp. and Bordetella sp. for ε-caprolactam utilization.     

Carbon Monoxide, Hydrogen, and Formate Metabolism during Methanogenesis from Acetate by Thermophilic Cultures of Methanosarcina and Methanothrix Strains

CO and H₂ have been implicated in methanogenesis from acetate, but it is unclear whether they are directly involved in methanogenesis or electron transfer in acetotrophic methanogens. We compared metabolism of H₂, CO, and formate by cultures of the thermophilic acetotrophic methanogens Methanosarcina thermophila TM-1 and Methanothrix sp. strain CALS-1. M. thermophila accumulated H₂ to partial pressures of 40 to 70 Pa (1 Pa = 0.987 × 10^-5 atm), as has been previously reported for this and other Methanosarcina cultures. In contrast, Methanothrix sp. strain CALS-1 accumulated H₂ to maximum partial pressures near 1 Pa. Growing cultures of Methanothrix sp. strain CALS-1 initially accumulated CO, which reached partial pressures near 0.6 Pa (some CO came from the rubber stopper) during the middle of methanogenesis; this was followed by a decrease in CO partial pressures to less than 0.01 Pa by the end of methanogenesis. Accumulation or consumption of CO by cultures of M. thermophila growing on acetate was not detected. Late-exponential-phase cultures of Methanothrix sp. strain CALS-1, in which the CO partial pressure was decreased by flushing with N₂-CO₂, accumulated CO to 0.16 Pa, whereas cultures to which ca. 0.5 Pa of CO was added consumed CO until it reached this partial pressure. Cyanide (1 mM) blocked CO consumption but not production. High partial pressures of H₂ (40 kPa) inhibited methanogenesis from acetate by M. thermophila but not by Methanothrix sp. strain CALS-1, and 2 kPa of CO was not inhibitory to M. thermophila but was inhibitory to Methanothrix sp. strain CALS-1. Levels of CO dehydrogenase, hydrogenase, and formate dehydrogenase in Methanothrix sp. strain CALS-1 were 9.1, 0.045, and 5.8 μmol of viologen reduced min^-1 mg of protein^-1. These results suggest that CO plays a role in Methanothrix sp. strain CALS-1 similar to that of H₂ in M. thermophila and are consistent with the conclusion that CO is an intermediate in a catabolic or anabolic pathway in Methanothrix sp. strain CALS-1; however, they could also be explained by passive equilibration of CO with a metabolic intermediate.     

Antimicrobial peptides produced by <Emphasis Type="Italic">Brevibacillus</Emphasis> spp.: structure,classification and bioactivity: a mini review

Species that are currently listed under the genus Brevibacillus (formerly, Bacillus brevis cluster) have been a rich source of antimicrobial peptides for many decades. The first known peptide antibiotic, gramicidin, is presumed to be produced by a Brevibacillus sp. Members of the genus are widely spread in nature. They can be found in a variety of environments including intestinal tracts of animals, seawater, and soil. Some Brevibacillus strains have been used commercially as probiotics. Bioactive peptides produced by Brevibacillus spp. include antibacterial, antifungal and anti-invertebrate agents. Brevibacillus antimicrobial peptides are synthesized through ribosomal or nonribosomal pathway; these two groups can be further categorized based on specific structural features such as cyclization and presence of lipid chain. Some of the antimicrobial compounds produced by this genus share structural similarities that were overlooked previously. For example, the structural similarity between BT peptide, brevibacillin, and bogorol was revealed only recently. Here we review and classify Brevibacillus antimicrobial peptides and summarize their bioactivities and potential applications.     

A Brevibacillus sp. antagonistic to mycotoxigenic Fusarium spp.

Antagonistic microbes were isolated from soils to control mycotoxin contamination of cereals by limiting the growth of mycotoxigenic Fusarium species. In total, 341 bacterial isolates were examined for antifungal activity against eight mycotoxigenic Fusarium species using dual culture assays. The screening identified 11 isolates that inhibited mycelial growth of all Fusarium species tested. The culture filtrates of 2 of the 11 isolates completely inhibited germination of conidia up to 21 days of incubation. These two isolates exhibited identical activity toward the fungi tested and were identified as Brevibacillus spp. based on 16S rRNA sequence homology. The most closely related species based on phylogenetic analysis was Brevibacillus reuszeri. Additional dual culturing using further fungal species showed that the antagonistic Brevibacillus inhibited the growth of most Fusarium species tested (39 of 46 species), two Epicoccum spp., one Alternaria sp., three Aspergillus spp. (3 of 11), and three Penicillium spp. (3 of 8). The in vivo assay was performed to test the efficacy of antagonistic Brevibacillus isolates on maize ears and revealed that the application of microbes suppressed ear rot (ANOVA, p = 0.0020). This Brevibacillus sp. may be an antagonist of the majority of Fusarium species, including mycotoxigenic species.     

Complex interactions between diverse mobile genetic elements drive the evolution of metal-resistant bacterial genomes

In this study, we compared the genomes of three metal-resistant bacteria isolated from mercury-contaminated soil. We identified diverse and novel MGEs with evidence of multiple LGT events shaping their genomic structure and heavy metal resistance. Among the three metal-resistant strains, Sphingobium sp SA2 and Sphingopyxis sp SE2 were resistant to multiple metals including mercury, cadmium, copper, zinc and lead. Pseudoxanthomonas sp SE1 showed resistance to mercury only. Whole genome sequencing by Illumina and Oxford Nanopore technologies was undertaken to obtain comprehensive genomic data. The Sphingobium and Sphingopyxis strains contained multiple chromosomes and plasmids, whereas the Pseudoxanthomonas strain contained one circular chromosome. Consistent with their metal resistance profiles, the strains of Sphingobium and Sphingopyxis contained a higher quantity of diverse metal resistance genes across their chromosomes and plasmids compared to the single-metal resistant Pseudoxanthomonas SE1. In all three strains, metal resistance genes were principally associated with various novel MGEs including genomic islands (GIs), integrative conjugative elements (ICEs), transposons, insertion sequences (IS), recombinase in trio (RIT) elements and group II introns, indicating their importance in facilitating metal resistance adaptation in a contaminated environment. In the Pseudoxanthomonas strain, metal resistance regions were largely situated on a GI. The chromosomes of the strains of Sphingobium and Sphingopyxis contained multiple metal resistance regions, which were likely acquired by several GIs, ICEs, numerous IS elements, several Tn3 family transposons and RIT elements. Two of the plasmids of Sphingobium were impacted by Tn3 family transposons and ISs likely integrating metal resistance genes. The two plasmids of Sphingopyxis harboured transposons, IS elements, an RIT element and a group II intron. This study provides a comprehensive annotation of complex genomic regions of metal resistance associated with novel MGEs. It highlights the critical importance of LGT in the evolution of metal resistance of bacteria in contaminated environments.