Halomonas rhizosphaerae sp. nov. and Halomonas kalidii sp. nov., two novel moderate halophilic phenolic acid-degrading species isolated from saline soil.

Four vanillic acid-degrading bacterial strains, named LR5S13T, LR5S20, and M4R5S39T and LN1S58, were isolated from Kalidium cuspidatum rhizosphere and bulk soils, respectively. Phylogenetic analysis based on 16S rRNA gene as well as core genome revealed that LR5S13T and LR5S20 clustered closely with each other and with Halomonas ventosae Al12T, and that the two strains shared the highest similarities (both 99.3 %) with H. ventosae Al12T, in contrast, M4R5S39T and LN1S58 clustered together and with Halomonas heilongjiangensis 9-2T, and the two strains shared the highest similarities (99.4 and 99.2 %, respectively) with H. heilongjiangensis 9-2T. The average nucleotides identities based on BLAST (ANIb) and digital DNA-DNA hybridization (dDDH) values of strains LR5S13T to LR5S20, and M4R5S39T to LN1S58, were both higher than the threshold values for delineation of a species. The ANIb and dDDH values of the four strains to their closely relatives were lower than the threshold values. All four strains take phosphatidylethanolamine, phosphatidylglycerol, and diphosphatidylglycerol as the major polar lipids, Summed Feature 8, Summed Feature 3, and C16:0 as the major fatty acids. Based on the phylogenetic and phenotypic results, the four strains should be classified as two novel Halomonas species. Therefore, Halomonas rhizosphaerae sp. nov. (type strain LR5S13T = KCTC 8016T = CGMCC 1.62049T) and Halomonas kalidii (type strain M4R5S39T = KCTC 8015T = CGMCC 1.62047T) are proposed. The geographical distribution analysis based on 16S rRNA gene revealed that the two novel species are widely distributed across the globe, specifically in highly saline habits, especially in Central and Eastern Asia.

A comprehensive genomic analysis provides insights on the high environmental adaptability of Acinetobacter strains.

Acinetobacter is ubiquitous, and it has a high species diversity and a complex evolutionary pattern. To elucidate the mechanism of its high ability to adapt to various environment, 312 genomes of Acinetobacter strains were analyzed using the phylogenomic and comparative genomics methods. It was revealed that the Acinetobacter genus has an open pan-genome and strong genome plasticity. The pan-genome consists of 47,500 genes, with 818 shared by all the genomes of Acinetobacter, while 22,291 are unique genes. Although Acinetobacter strains do not have a complete glycolytic pathway to directly utilize glucose as carbon source, most of them harbored the n-alkane-degrading genes alkB/alkM (97.1% of tested strains) and almA (96.7% of tested strains), which were responsible for medium-and long-chain n-alkane terminal oxidation reaction, respectively. Most Acinetobacter strains also have catA (93.3% of tested strains) and benAB (92.0% of tested strains) genes that can degrade the aromatic compounds catechol and benzoic acid, respectively. These abilities enable the Acinetobacter strains to easily obtain carbon and energy sources from their environment for survival. The Acinetobacter strains can manage osmotic pressure by accumulating potassium and compatible solutes, including betaine, mannitol, trehalose, glutamic acid, and proline. They respond to oxidative stress by synthesizing superoxide dismutase, catalase, disulfide isomerase, and methionine sulfoxide reductase that repair the damage caused by reactive oxygen species. In addition, most Acinetobacter strains contain many efflux pump genes and resistance genes to manage antibiotic stress and can synthesize a variety of secondary metabolites, including arylpolyene, ß-lactone and siderophores among others, to adapt to their environment. These genes enable Acinetobacter strains to survive extreme stresses. The genome of each Acinetobacter strain contained different numbers of prophages (0-12) and genomic islands (GIs) (6-70), and genes related to antibiotic resistance were found in the GIs. The phylogenetic analysis revealed that the alkM and almA genes have a similar evolutionary position with the core genome, indicating that they may have been acquired by vertical gene transfer from their ancestor, while catA, benA, benB and the antibiotic resistance genes could have been acquired by horizontal gene transfer from the other organisms.

Idiomarina rhizosphaerae sp. nov. isolated from rhizosphere soil of Kalidium cuspidatum, and reclassification of Idiomarina andamanensis as Pseudidiomarina andamanensis comb. nov., and Idiomarina mangrovi as Pseudidiomarina mangrovi comb. nov.

A Gram-stain-negative, strictly aerobic, gliding motile, non-spore forming, rod-shaped indole-3-acetic acid producing bacterial strain, designated M1R2S28T, was isolated from the rhizosphere soil of Kalidium cuspidatum, in Tumd Right Banner, Inner Mongolia, China. Strain M1R2S28T grew at pH 5.0-10.0 (optimum 8.0), 10-45 °C (optimum 37 °C), in the presence of 0-20% (w/v) NaCl (optimum 5%). The phylogenetic trees based on the 16S rRNA gene sequences and the core-genome both revealed that strain M1R2S28T clustered tightly with Idiomarina loihiensis L2-TRT, and shared 99.3, 99.2, 98.7, and < 98.7% of the 16S rRNA gene sequence similarities with I. loihiensis L2-TRT, I. abyssalis KMM 227 T, I. ramblicola R22T, and all the other current type strains. The strain contained ubiquinone-8 (Q-8) as the sole respiratory quinone. Its major polar lipids were phosphatidylethanolamine, phosphatidylglycerol, diphosphatidylglycerol, an unidentified aminolipid, an unidentified phospholipid, and three unidentified lipids. Its major fatty acids were iso-C15:0, iso-C17:0, and iso-C17:1 ω9c. The genomic DNA G + C content was 46.8%. The average nucleotide identity based on BLAST (ANIb) and the digital DNA-DNA hybridization (dDDH) values of strain M1R2S28T to I. loihiensis L2-TRT, I. ramblicola R22T, and I. abyssalis KMM 227 T were 93.0, 82.9, and 81.8%, and 51.2, 26.0, and 25.0%, respectively. The phylogenetic and physiological results allowed the discrimination of strain M1R2S28T from its phylogenetic relatives. Idiomarina rhizosphaerae sp. nov. is, therefore, proposed with strain M1R2S28T (= CGMCC 1.19026 T = KCTC 92133 T) as the type strain. Additionally, based on the phylogenomic and genomic analysis results, Idiomarina andamanensis and Idiomarina mangrovi were transferred into genus Pseudidiomarina and be named Pseudidiomarina andamanensis comb. nov. and Pseudidiomarina mangrovi comb. nov., respectively.

Luteimonas saliphila sp. nov. and Luteimonas salinisoli sp. nov., two novel strains isolated from saline soils.

Two Gram-stain-negative, motile with single polar flagellum, rod-shaped bacterial strains, named SJ-9T and SJ-92T, were isolated from saline soils from Inner Mongolia, PR China. SJ-9T and SJ-92T grew at pH 6.5-10.0 and 7.0-11.0, 10-35 °C, and in the presence of 0-5 % and 0-8 % NaCl, respectively. Both strains were positive for oxidase, and negative for catalase. The results of phylogenetic analysis based on 16S rRNA gene sequences indicated that SJ-9T clustered with Luteimonas marina FR1330T (sharing 97.9 % 16S rRNA gene similarity), Luteimonas huabeiensis HB2T (96.5 %), 'Luteimonas wenzhouensis' YD-1 (96.6 %), and Luteimonas composti CC-YY255T (95.1 %), and shared low 16S rRNA gene similarities (<97.0 %) with all the other type strains; while SJ-92T clustered with Luteimonas aestuarii B9T (98.2 %), and shared low 16S rRNA gene similarities (<98.0 %) with all the other type strains. The two strains shared 97.4 % 16S rRNA gene similarity with each other. The major cellular fatty acids of both strains are iso-C15 : 0 and summed feature 9 (C16 : 0 10-methyl and/or iso-C17 : 1ω9c). The major polar lipids of both strains are diphosphatidylglycerol, phosphatidylglycerol and phosphatidylethanolamine. The only respiratory quinone for both strains is ubiquinone-8 (Q-8). The genomic DNA G+C contents are 69.3 and 70.4 mol%, respectively. The digital DNA-DNA hybridization (dDDH) and average nucleotide identity by blast (ANIb) values between the two strains were 22.6 and 77.5 %, while the values between SJ-9T and 'L. wenzhouensis' YD-1, L. marina FR1330T, and L. huabeiensis HB2T were 38.1, 39.2, and 21.9 %, and 82.5, 84.4, and 78.5 %, while those between SJ-92T and L. aestuarii B9T were 21.3 and 76.7 %. On the basis of the phenotypic, physiological and phylogenetic results, SJ-9T and SJ-92T represent two novel species of the genus Luteimonas, for which the names Luteimonas saliphila [type stain SJ-9T (=CGMCC 1.17377T=KCTC 82248T)] and Luteimonas salinisoli [type strain SJ-92T (=CGMCC 1.17695T=KCTC 82208T)] are proposed.

Effect of Sophora flavescens on the pharmacokinetics of carbamazepine in rats.

Carbamazepine (CBZ), an antiepileptic with narrow therapeutic window, is a substrate of CYP 3A4 which metabolizes CBZ to carbamazepine-10,11-epoxide (CBZE). CBZE is an active and toxicity metabolite, and it is a substrate of MRP-2. Using CBZ for a long time can cause hepatic injury. Sophora flavescens (SF) is a medicinal herb used for the protected hepatic injury. This study investigated the acute and chronic effects of SF on the pharmacokinetics of CBZ in rats. The concentrations of CBZ and CBZE in plasma and tissues were determined by HPLC method. The results showed that SF which significantly decreased the AUC0-t of CBZ, increased CBZE conversely. Tissue analysis showed that the concentrations of CBZ and CBZE in brain and liver were decreased by SF. In addition, the distribution of CBZE in kidney was reduced significantly, which influenced the CBZE excretion and increased the drug toxic potentially. Results in the current study suggest that patients using CBZ might be cautioned in the use of SF extract or Sophora-derived products. Meanwhile, patients receiving drugs which are substrates of CYP 3A4 and/or MRP-2 should be advised of the potential herb-drug interaction to reduce the risk of therapeutic failure or increased toxicity of conventional drug therapy.