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Red Soils Harbor Diverse Culturable Actinomycetes That Are Promising Sources of Novel Secondary Metabolites

Guo, Xiaoxuan ; Liu, Ning ; Li, Xiaomin ; [et al.]

American Society for Microbiology ; 2015

In: Applied and Environmental Microbiology Vol. 81, No. 9 ( 2015-05), p. 3086-3103

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In: Applied and Environmental Microbiology, American Society for Microbiology, Vol. 81, No. 9 ( 2015-05), p. 3086-3103

Abstract: Red soils, which are widely distributed in tropical and subtropical regions of southern China, are characterized by low organic carbon, high content of iron oxides, and acidity and, hence, are likely to be ideal habitats for acidophilic actinomycetes. However, the diversity and biosynthetic potential of actinomycetes in such habitats are underexplored. Here, a total of 600 actinomycete strains were isolated from red soils collected in Jiangxi Province in southeast China. 16S rRNA gene sequence analysis revealed a high diversity of the isolates, which were distributed into 26 genera, 10 families, and 7 orders within the class Actinobacteria ; these taxa contained at least 49 phylotypes that are likely to represent new species within 15 genera. The isolates showed good physiological potentials for biosynthesis and biocontrol. Chemical screening of 107 semirandomly selected isolates spanning 20 genera revealed the presence of at least 193 secondary metabolites from 52 isolates, of which 125 compounds from 39 isolates of 12 genera were putatively novel. Macrolides, polyethers, diketopiperazines, and siderophores accounted for most of the known compounds. The structures of six novel compounds were elucidated, two of which had a unique skeleton and represented characteristic secondary metabolites of a putative novel Streptomyces phylotype. These results demonstrate that red soils are rich reservoirs for diverse culturable actinomycetes, notably members of the families Streptomycetaceae , Pseudonocardiaceae , and Streptosporangiaceae , with the capacity to synthesize novel bioactive compounds.

Type of Medium: Online Resource

ISSN: 0099-2240 , 1098-5336

URL: Article

DOI: 10.1128/AEM.03859-14

RVK:

WA 15000

Language: English

Publisher: American Society for Microbiology

Publication Date: 2015

detail.hit.zdb_id: 223011-2

detail.hit.zdb_id: 1478346-0

SSG: 12

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Molecular Mechanism of Chloramphenicol and Thiamphenicol Resistance Mediated by a Novel Oxidase, CmO, in Sphingomonadaceae

Ma, Xiaodan ; Zhang, Liying ; Ren, Yijun ; [et al.]

American Society for Microbiology ; 2023

In: Applied and Environmental Microbiology Vol. 89, No. 1 ( 2023-01-31)

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In: Applied and Environmental Microbiology, American Society for Microbiology, Vol. 89, No. 1 ( 2023-01-31)

Abstract: Antibiotic resistance mediated by bacterial enzyme inactivation plays a crucial role in the degradation of antibiotics in the environment. Chloramphenicol (CAP) resistance by enzymatic inactivation comprises nitro reduction, amide bond hydrolysis, and acetylation modification. However, the molecular mechanism of enzymatic oxidation of CAP remains unknown. Here, a novel oxidase gene, cmO , was identified and confirmed biochemically. The encoded CmO oxidase could catalyze the oxidation at the C-1′ and C-3′ positions of CAP and thiamphenicol (TAP) in Sphingobium sp. strain CAP-1. CmO is highly conserved in members of the family Sphingomonadaceae and shares the highest amino acid similarity of 41.05% with the biochemically identified glucose methanol choline (GMC) oxidoreductases. Molecular docking and site-directed mutagenesis analyses demonstrated that CAP was anchored inside the protein pocket of CmO with the hydrogen bonding of key residues glycine (G) 99, asparagine (N) 518, methionine (M) 474, and tyrosine (Y) 380. CAP sensitivity tests demonstrated that the acetyltransferase and CmO could enable a higher level of resistance to CAP than the amide bond-hydrolyzing esterase and nitroreductase. This study provides a better theoretical basis and a novel diagnostic gene for understanding and assessing the fate and resistance risk of CAP and TAP in the environment. IMPORTANCE Rising levels of antibiotic resistance are undermining ecological and human health as a result of the indiscriminate usage of antibiotics. Various resistance mechanisms have been characterized—for example, genes encoding proteins that degrade antibiotics—and yet, this requires further exploration. In this study, we report a novel gene encoding an oxidase involved in the inactivation of typical amphenicol antibiotics (chloramphenicol and thiamphenicol), and the molecular mechanism is elucidated. The findings provide novel data with which to understand the capabilities of bacteria to tackle antibiotic stress, as well as the complex function of enzymes in the contexts of antibiotic resistance development and antibiotic removal. The reported gene can be further employed as an indicator to monitor amphenicol’s fate in the environment, thus benefiting risk assessment in this era of antibiotic resistance.

Type of Medium: Online Resource

ISSN: 0099-2240 , 1098-5336

URL: Article

DOI: 10.1128/aem.01547-22

RVK:

WA 15000

Language: English

Publisher: American Society for Microbiology

Publication Date: 2023

detail.hit.zdb_id: 223011-2

detail.hit.zdb_id: 1478346-0

SSG: 12

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