The aeroponic rhizosphere microbiome: community dynamics in early succession suggest strong selectional forces.

In the last decade there has been increased interest in the manipulation of rhizosphere microbial communities in soilless systems (hydroponics) through the addition of plant growth promoting microbes (PGPMs) to increase plant nutrition, lower plant stress response, and control pathogens. This method of crop management requires documenting patterns in communities living in plant roots throughout the growing season to inform decisions on timing of application and composition of the supplemental PGPM consortium. As a contribution to this effort, we measured changes in the bacterial community through early succession (first 26 days) in plant root biofilms growing in an indoor commercial aeroponic system where roots were sprayed with a mist of nutrient-amended water. By 12 days following seed germination, a root-associated community had established that was distinct from the source communities found circulating in the system. Successional patterns in the community over the following 2 weeks (12-26 days) included changes in abundance of bacterial groups that have been documented in published literature as able to utilize plant root exudates, release plant hormones, or augment nutrient availability. Six bacterial families/genera (Hydrogenophilaceae, Rhizobium, Legionellaceae, Methylophilus, Massilia, or Herbaspirillum) were the most abundant in each root sample, comprising 8-37% of the microbiome. Given the absence of soil-associated microbial communities in hydroponic systems, they provide an ideal design for isolating plant-microbial interactions and identifying key components possibly contributing to plant health.

Comparison of the Wild-Type Obligate Methylotrophic Bacterium Methylophilus quaylei and its Isogenic Streptomycin-Resistant Mutant via Metal Nanoparticle Generation.

Metal nanoparticles synthesized by green methods with the use of microorganisms are currently one of the most closely studied types of nanomaterials. It has accurately been shown that the characteristics of metal nanoparticles generated in the presence of different bacteria vary. For the two isogenic strains of obligate methylotrophic bacteria of the wild type (M. quaylei MTT) and its streptomycin-resistant mutant (M. quaylei SMR), the pleiotropic character of streptomycin resistance mutation in the SMR cells has been revealed. It has been shown that both cultures can generate silver nanoparticles. There is a dramatic difference in the formation of palladium nanoparticles, which are formed only in the presence of cells of the streptomycin-resistant mutant M. quaylei SMR. This study shows that closely related isogenic strains of obligate methylotrophic bacteria can be distinguished by the spectra of biogenic nanoparticles of two noble metals. While palladium nanoparticles are only generated by the cells of the streptomycin-resistant mutant M. quaylei SMR, biogenic silver nanoparticles can be generated from both cultures. Thus, the assessment of the ability of microorganisms to form biogenic nanoparticles of different metals allows the revelation of subtle metabolic differences of even close cultures.

The Draft Genome Sequence of Methylophilus sp. D22, Capable of Growing Under High Concentration of Methanol.

In this study, a wild type Methylophilus sp. strain D22 belonging to the family Methylophilus was isolated and characterized, which shows high tolerance towards methanol, as it can grow under 50 g/L of methanol. Methylophilus sp. strain D22 was isolated from the lake sludge in Nanjing Tech University, China. The assembled draft genome contains one circular chromosome with 3,004,398 bp, 49.7% of GC content, and 2107 predicted encoding proteins. Sequence-based genomic analysis demonstrates that the assimilation pathway of ribulose monophosphate (RuMP) pathway and dissimilation pathway of tetrahydromethanopterin (H4MPT) pathway are co-existing and contribute to the high methanol utilization efficiency.

Evidence for photolytic and microbial degradation processes in the dissipation of leptospermone, a natural ß-triketone herbicide.

Bioherbicides appear as an ecofriendly alternative to synthetic herbicides, generally used for weed management, because they are supposed to have low side on human health and ecosystems. In this context, our work aims to study abiotic (i.e., photolysis) and biotic (i.e,. biodegradation) processes involved in the fate of leptospermone, a natural ß-triketone herbicide, by combining chemical and microbiological approaches. Under controlled conditions, the photolysis of leptospermone was sensitive to pH. Leptospermone has a half-life of 72 h under simulated solar light irradiations. Several transformation products, including hydroxy-leptospermone, were identified. For the first time, a bacterial strain able to degrade leptospermone was isolated from an arable soil. Based on its 16S ribosomal RNA (rRNA) gene sequence, it was affiliated to the Methylophilus group and was accordingly named as Methylophilus sp. LS1. Interestingly, we report that the abundance of OTUs, similar to the 16S rRNA gene sequence of Methylophilus sp. LS1, was strongly increased in soil treated with leptospermone. The leptospermone was completely dissipated by this bacteria, with a half-life time of 6 days, allowing concomitantly its growth. Hydroxy-leptospermone was identified in the bacterial culture as a major transformation product, allowing us to propose a pathway of transformation of leptospermone including both abiotic and biotic processes.

Complete genome sequence of Methylophilus sp. TWE2 isolated from methane oxidation enrichment culture of tap-water.

The non-methane-utilizing methylotroph, Methylophilus sp. TWE2, was isolated from tap-water during the enrichment of methanotrophs with methane. The complete genome sequence of strain TWE2 showed that this bacterium may convert methanol to formaldehyde via catalysis of methanol dehydrogenase (MDH), after which formaldehyde would be assimilated to biomass through the ribulose monophosphate (RuMP) pathway or dissimilated via the tetrahydromethanopterin (H4MPT) pathway. The deficiency of glycolysis and the TCA cycle indicate that strain TWE2 may be an obligate methylotroph. This is the first complete genome sequence of the genus Methylophilus.

Salt stress tolerance of methylotrophic bacteria Methylophilus sp. and Methylobacterium sp. isolated from coal mine spoils.

Two methylotrophic strains of Bina coalmine spoil BNV7b and BRV25 were identified based on physiological traits and 16S rDNA sequence as Methylophilus and Methylobacterium species.' The strains exhibited similar carbon utilization but differed in N utilization and their response to the metabolic inhibitors. Methylophilus sp. was less tolerant to salt stress and it viability declined to one tenth within 4 h of incubation in 2M NaCI due to membrane damage and leakage of the intracellular electrolytes as evident from malondiaaldehyde (MDA) assay. In 200 mM NaCI, they exhibited increased superoxide dismutase (SOD), catalase (CAT) and ascorbate peroxidase (APX) activity while in 500 mM NaCI, enzyme activities declined in Methylophilus sp. and increased in Methylobacterium sp. Among exogenously applied osmoprotectants proline was most efficient; however, polyols (mannitol, sorbitol and glycerol) also supported growth under lethal NaCI concentration.

Methylophilus glucosoxydans sp. nov., a restricted facultative methylotroph from rice rhizosphere.

Two restricted facultatively methylotrophic strains, designed B(T) and P, were isolated from rice roots. The isolates were strictly aerobic, Gram-negative, asporogenous, mesophilic, neutrophilic, motile rods that multiplied by binary fission and were able to synthesize indole-3-acetate. The cellular fatty acid profiles of the two strains were dominated by C(16:0), C(16:1)ω7c and C(16:0) 2-OH. The major ubiquinone was Q-8. The predominant phospholipids were phosphatidylethanolamine and phosphatidylglycerol. Cardiolipin (diphosphatidylglycerol) was absent. The two strains assimilated methanol carbon at the level of formaldehyde via the ribulose monophosphate cycle (2-keto-3-deoxy-6-phosphogluconate variant). They lacked α-ketoglutarate dehydrogenase and glutamate dehydrogenase. They assimilated ammonium via the glutamate cycle enzymes glutamine synthetase and glutamate synthase. The DNA G+C contents of strains B(T) and P were 52.5 and 51.5 mol% (T(m)), respectively. The level of DNA-DNA reassociation between these strains was 78%, indicating that they belong to one species. Phylogenetic analysis of strain B(T) based on 16S rRNA and methanol dehydrogenase (mxaF) gene sequences showed a high level of similarity to members of the genus Methylophilus. As the two isolates were clearly distinct from all recognized members of the genus Methylophilus based on phenotypic data and levels of DNA-DNA relatedness (30-46%), they are considered to represent a novel species, for which the name Methylophilus glucosoxydans sp. nov. is proposed; the type strain is B(T) (=VKM B-1607(T)=CCUG 59685(T)=DSM 5898(T)).

Methylophilus flavus sp. nov. and Methylophilus luteus sp. nov., aerobic, methylotrophic bacteria associated with plants.

Novel yellow, obligately methylotrophic and restricted facultatively methylotrophic bacteria, respectively designated strains Ship(T) and Mim(T), with the ribulose monophosphate pathway of C(1) assimilation are described. Cells were strictly aerobic, Gram-negative, asporogenous, non-motile rods that multiply by binary fission, were mesophilic and neutrophilic and synthesized indole-3-acetic acid and exopolysaccharide. The predominant cellular fatty acids were C(16 : 0) and C(16 : 1). The major ubiquinone was Q-8. The predominant phospholipids were phosphatidylethanolamine and phosphatidylglycerol; diphosphatidylglycerol was absent. The two strains lacked α-ketoglutarate dehydrogenase and glutamate dehydrogenase. They assimilated ammonium via the glutamate cycle enzymes glutamine synthetase and glutamate synthase. The DNA G+C contents of strains Ship(T) and Mim(T) were 50.7 and 54.5 mol% (T(m)), respectively. The level of 16S rRNA gene sequence similarity between these strains was very high (99.8 %) but they shared a low level of DNA-DNA relatedness (44 %). Based on 16S rRNA gene sequence analysis and low levels of DNA-DNA relatedness with the type strains of recognized species of the genus Methylophilus (31-36 %), strains Ship(T) and Mim(T) are considered to represent novel species of the genus Methylophilus, for which the names Methylophilus flavus sp. nov. (type strain Ship(T) =DSM 23073(T) =VKM B-2547(T) =CCUG 58411(T)) and Methylophilus luteus sp. nov. (type strain Mim(T) =DSM 22949(T) =VKM B-2548(T) =CCUG 58412(T)) are proposed.

Endosymbionts of Acanthamoeba isolated from domestic tap water in Korea.

In a previous study, we reported our discovery of Acanthamoeba contamination in domestic tap water; in that study, we determined that some Acanthamoeba strains harbor endosymbiotic bacteria, via our molecular characterization by mitochondrial DNA restriction fragment length polymorphism (Mt DNA RFLP). Five (29.4%) among 17 Acanthamoeba isolates contained endosymbionts in their cytoplasm, as demonstrated via orcein staining. In order to estimate their pathogenicity, we conducted a genetic characterization of the endosymbionts in Acanthamoeba isolated from domestic tap water via 16S rDNA sequencing. The endosymbionts of Acanthamoeba sp. KA/WP3 and KA/WP4 evidenced the highest level of similarity, at 97% of the recently published 16S rDNA sequence of the bacterium, Candidatus Amoebophilus asiaticus. The endosymbionts of Acanthamoeba sp. KA/WP8 and KA/WP12 shared a 97% sequence similarity with each other, and were also highly similar to Candidatus Odyssella thessalonicensis, a member of the alpha-proteobacteria. The endosymbiont of Acanthamoeba sp. KA/WP9 exhibits a high degree of similarity (85-95%) with genus Methylophilus, which is not yet known to harbor any endosymbionts. This is the first report, to the best of our knowledge, to show that Methylophilus spp. can live in the cytoplasm of Acanthamoeba.

Methylophilus rhizosphaerae sp. nov., a restricted facultative methylotroph isolated from rice rhizosphere soil.

Three facultative methylotrophic bacterial strains, designated CBMB127(T), CBMB145 and CBMB147, were isolated from the rhizosphere soil of rice and characterized. The strains produced indole-3-acetic acid and siderophores, had 1-aminocyclopropane-1-carboxylate deaminase activity and sulfur oxidation property and also methanol dehydrogenase. Phylogenetic analysis based on the 16S rRNA and methanol dehydrogenase (mxaF) gene sequences showed that Methylophilus methylotrophus was their close relative. The results of the phenotypic, phylogenetic and genotypic analyses showed that strains CBMB127(T) and CBMB145, with 99.4 % 16S rRNA gene sequence similarity and 99 % DNA-DNA hybridization, could be distinguished from recognized species of Methylophilus. Therefore strain CBMB127(T) and CBMB145 are considered to represent a novel species of Methylophilus, for which the name Methylophilus rhizosphaerae sp. nov. is proposed, with CBMB127(T) (=KACC 13099(T)=NCCB 100233(T)) as the type strain. Strain CBMB147 represents a novel strain of the species Methylophilus methylotrophus.

Fluorescence lifetimes of tyrosine residues in cytochrome c'' as local probes to study protein unfolding.

Time-resolved fluorescence spectroscopy was used to show that multiple tyrosine residues of a protein can serve as localized probes of structural changes during thermal unfolding. Cytochrome c'' from Methylophilus methylotrophus, which has four tyrosine residues, was chosen as a model protein. The procedure involved, first, the assignment of the experimental decay times to the tyrosine residues, followed by the interpretation of the changes in the decay times and pre-exponential coefficients with temperature. We found that the fluorescence decays of cytochrome c'' are double-exponential from 23 to 80 degrees C, with decay times much shorter than those of the parent compound N-acetyl-tyrosinamide; this quenching was ascribed to dipole-dipole energy transfer from the tyrosine residues to the heme. The tyrosine-heme distances (R) and theoretical decay times, tau(comp), were estimated for each tyrosine residue. The analysis of the simulated decay generated with tau(comp), showed that a double-exponential fit is sufficient to describe the four decay times with two pre-exponential coefficients close to values observed from the experimental decay. Therefore, the decay times at 23 degrees C could be assigned to the individual tyrosine residues as tau(1) to Tyr-10 and Tyr-23 (at 20.3 A) and tau(2) to Tyr-12 and Tyr-115 (at 12-14 A). On the basis of this assignment and MD simulations, the temperature dependence of the decay times and pre-exponential coefficients suggest that upon unfolding, Tyr-12 is displaced from the heme, with loss of the structure of alpha-helix I. Moreover, Tyr-115 remains close to the heme and the structure in this region of the protein is not altered significantly. Altogether the data support the view that the protein core, comprising the heme and the four alpha-helices II to V, is clearly more stable than the remaining region that includes alpha-helix I and the loop between residues 19-27.

[Phylogenetic analysis of aerobic methylotrophic bacteria, using dichloromethane]. / Filogeneticheskii analiz aérobnykh metilotrofnykh bakterii, ispol'zuiushchikh dikhlormetan.

The phylogenetic relationships of 12 aerobic dichloromethane-degrading bacteria that implement different C1-assimilation pathways was determined based on 16S ribosomal RNA sequences and DNA-DNA hybridization data. The restricted facultative methylotroph "Methylophilus leisingerii" DM11 with the ribulose monophosphate pathway was found to belong to the genus Methylophilus cluster of the beta subdivision of the phylogenetic kingdom Proteobacteria. The facultative methylotroph Methylorhabdus multivorans DM13 was assigned to a separate branch of the alpha-2 group of Proteobacteria. Paracoccus methylutens DM12, which utilizes C1-compounds via the Calvin cycle was found to belong to the alpha-3 group of the Proteobacteria (more precisely, to the genus Paracoccus cluster). Thus, phylogenetic analysis confirmed the taxonomic status of these recently characterized bacteria. According to the degree of DNA homology, several novel strains of methylotrophic bacteria were divided into three genotypic groups within the alpha-2 group of the Proteobacteria. Genotypic group 1, comprising strains DM1, DM3, and DM5 through DM9, and genotypic group 3, comprising strain DM10, were phylogenetically close to the methylotrophic bacteria of the genus Methylopila, whereas genotypic group 2 (strain DM4) was close to bacteria of the genus Methylobacterium. The genotypic groups obviously represent distinct taxa of methylotrophic bacteria, whose status should be confirmed by phenotypic analysis.

Sequence variation in dichloromethane dehalogenases/glutathione S-transferases.

Dichloromethane dehalogenase/glutathione S-transferase allows methylotrophic bacteria to grow with dichloromethane (DCM), a predominantly man-made compound. Bacteria growing with DCM by virtue of this enzyme have been readily isolated in the past. So far, the sequence of the dcmA gene encoding DCM dehalogenase has been determined for Methylobacterium dichloromethanicum DM4 and Methylophilus sp. DM11. DCM dehalogenase genes closely related to that of strain DM4 were amplified by PCR and cloned from total DNA from 14 different DCM-degrading strains, enrichment cultures and sludge samples from wastewater treatment plants. In total, eight different sequences encoding seven different protein sequences were obtained. Sequences of different origin were identical in several instances. Sequence variation was limited to base substitutions; strikingly, 16 of the 19 substitutions in the dcmA gene itself encoded amino acids that were different from those of the DM4 sequence. The kinetic parameters k(cat) and K:(m), the pH optimum and the stability of representative DCM dehalogenase variants were investigated, revealing minor differences between the properties of DCM dehalogenases related to that from strain DM4.

Structure of the phylogenetically most conserved domain of SRP RNA.

The signal recognition particle (SRP) is a phylogenetically conserved ribonucleoprotein required for cotranslational targeting of proteins to the membrane of the endoplasmic reticulum of the bacterial plasma membrane. Domain IV of SRP RNA consists of a short stem-loop structure with two internal loops that contain the most conserved nucleotides of the molecule. All known essential interactions of SRP occur in that moiety containing domain IV. The solution structure of a 43-nt RNA comprising the complete Escherichia coli domain IV was determined by multidimensional NMR and restrained molecular dynamics refinement. Our data confirm the previously determined rigid structure of a smaller subfragment containing the most conserved, symmetric internal loop A (Schmitz et al., Nat Struct Biol, 1999, 6:634-638), where all conserved nucleotides are involved in nucleotide-specific structural interactions. Asymmetric internal loop B provides a hinge in the RNA molecule; it is partially flexible, yet also uniquely structured. The longer strand of internal loop B extends the major groove by creating a ledge-like arrangement; for loop B however, there is no obvious structural role for the conserved nucleotides. The structure of domain IV suggests that loop A is the initial site for the RNA/protein interaction creating specificity, whereas loop B provides a secondary interaction site.