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W4284677798 abstract "High arsenic (As) and chromium (Cr) concentrations are currently receiving attention because of their negative effects on the environment and human health. Microorganisms inhabiting contaminated environments have developed resistance mechanisms against the toxicity of these pollutants. Indeed, members of the bacterial genus Micrococcus have been isolated from different toxic metal-contaminated environments; however, knowledge concerning its resistance mechanisms to As and Cr toxicity remains limited. Micrococcus luteus strains (An24, Mh, NE2TL6, and NE2TTS4) were isolated from the endosphere and soil of two heavy metal-contaminated sites in Mexico to identify differences in the resistance mechanisms by the M. luteus group. The strains were resistant to As (As3+ and As5+), chromate, dichromate, cobalt, copper, nickel, and zinc. Genome analysis indicated that the heavy metal-resistant strains (An24, Mh, NE2TL6, and NE2TTS4) could be assigned to the M. luteus group and had more heavy metal-resistant genes (transporters, chaperones, and enzymes) compared to reference strains of the M. luteus group, M. luteus NCTC 2665T and Micrococcus endophyticus JCM 16951T. The resistant bacteria were able to biotransform As3+ and As5+ through a carbon source-dependent mechanism. The biotransformation of As5+ was potentially carried out in the cytoplasm through a thioredoxin-dependent pathway, which may be coupled with biosorption. A qualitative analysis of organic acids (OAs) identified a change in the OA profile of the metal-resistant strains that was As- or Cr-dependent. Our genomic and phenotypic findings suggest that the four M. luteus group strains evaluated in the current study have developed resistance mechanisms that may enable their survival in contaminated sites." @default.
W4284677798 created "2022-07-08" @default.
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W4284677798 date "2023-08-01" @default.
W4284677798 modified "2023-10-14" @default.
W4284677798 title "Arsenic and chromium resistance mechanisms in the Micrococcus luteus group" @default.
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W4284677798 doi "https://doi.org/10.1016/j.pedsph.2022.07.013" @default.
W4284677798 hasPublicationYear "2023" @default.
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