Bacterial resistance to arsenic protects against protist killing

Hao, Xiuli; Li, Xuanji; Pal, Chandan; Hobman, Jon L.; Larsson, D. G. Joakim; Saquib, Quaiser; Alwathnani, Hend A.; Rosen, Barry P.; Zhu, Yan; Rensing, Christopher

doi:10.1007/s10534-017-0003-4

Cited by 15 publications

(10 citation statements)

References 17 publications

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“…Plasmid PNJST258N1 (143Kb) contains a 20-gene cluster “copper pathogenicity island” that probably aids in survival in macrophages ( Hao et al, 2015 ) and an ars gene cluster also containing arsH which might aid in survival in NK cells. Survival in amoeba was enhanced by the presence of an arsRBC operon in E. coli ( Hao et al, 2017 ). Perhaps this is also true in macrophages.…”

Section: Resistance To Organoarsenicalsmentioning

confidence: 99%

Distribution of Arsenic Resistance Genes in Prokaryotes

et al. 2018

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Arsenic is a metalloid that occurs naturally in aquatic and terrestrial environments. The high toxicity of arsenic derivatives converts this element in a serious problem of public health worldwide. There is a global arsenic geocycle in which microbes play a relevant role. Ancient exposure to arsenic derivatives, both inorganic and organic, has represented a selective pressure for microbes to evolve or acquire diverse arsenic resistance genetic systems. In addition, arsenic compounds appear to have been used as a toxin in chemical warfare for a long time selecting for an extended range of arsenic resistance determinants. Arsenic resistance strategies rely mainly on membrane transport pathways that extrude the toxic compounds from the cell cytoplasm. The ars operons, first discovered in bacterial R-factors almost 50 years ago, are the most common microbial arsenic resistance systems. Numerous ars operons, with a variety of genes and different combinations of them, populate the prokaryotic genomes, including their accessory plasmids, transposons, and genomic islands. Besides these canonical, widespread ars gene clusters, which confer resistance to the inorganic forms of arsenic, additional genes have been discovered recently, which broadens the spectrum of arsenic tolerance by detoxifying organic arsenic derivatives often used as toxins. This review summarizes the presence, distribution, organization, and redundance of arsenic resistance genes in prokaryotes.

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Section: Resistance To Organoarsenicalsmentioning

confidence: 99%

Distribution of Arsenic Resistance Genes in Prokaryotes

et al. 2018

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“…Contrasting with isolates carrying only acr3 genes, those with arsBI/II-type cluster presented highest MIC values in both atmospheres, suggesting a more prominent role of this ars operon for the survival in high arseniccontaminated environments and with different oxygen levels (Tóth et al, 2016;Cui et al, 2017). Also, it was recently demonstrated that arsRBC operon is also crucial to avoid killing by a soil amoeba (Hao et al, 2017), a protozoan that was shown to have a fundamental role for Salmonella Typhimurium survival in the environment (Bleasdale et al, 2009). The WGS analysis of ars operon environments allowed to observe that S. Typhimurium and S. 4,[5],12:i:-carried two arsA and arsD genes (arsD1A1CBA2D2R) in contrast with acr3-type operon in S. Rissen (acr3arsADCR).…”

Section: Discussionmentioning

confidence: 93%

Tolerance to arsenic contaminant among multidrug‐resistant and copper‐tolerant Salmonella successful clones is associated with diverse ars operons and genetic contexts

Mourão

Rebelo

Ribeiro

et al. 2020

Environmental Microbiology

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Summary Emergence and expansion of frequent multidrug‐resistant (MDR) major Salmonella clones/serotypes has been a significant threat in the last years. Metal compounds, such as copper, commonly used in animal‐production settings, have been pointed out as possible contributors for the selection of such strains/clones. However, the scarcity of studies limits our understanding of the impact of other metal environmental contaminants as arsenic (used in insecticides/herbicides/coccidiostats). We analysed arsenic tolerance (AsT) dispersion by phenotypic and genotypic (PCR/sequencing/I‐CeuI/S1/XbaI‐PFGE/hybridization) assays among Salmonella with diverse epidemiological and genetic backgrounds. Then, to better understand ars operon genetic contexts, the whole genome of five representative strains was sequenced. We found a high dispersion of ars operons conferring AsT, especially among copper‐tolerant and relevant serotypes/clones related to pig‐production setting. The acr3‐type was found dispersed in the chromosome of diverse serotypes, including the emergent S. Rissen. Conversely, arsBII was almost confined to the MDR ST34 European clone of S. Typhimurium/S. 4,[5],12:i:‐, always along with copper/silver tolerance sil + pco clusters in an integrative conjugative element. These data suggest that AsT is an essential adaptive feature for the ecological success of these epidemic clones/serotypes and alerts for global strategies to reduce arsenic‐based compounds' impact thus preventing environmental/food contamination with frequent MDR foodborne pathogens.

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“…Furthermore, the industrial revolution also contributed to the rapid increase in metal production in the environment. Likewise, the presence of metal resistance genes (MRGs) in bacteria was also premediated by protist predation, in which they exploited metal poisoning to inactivate and kill bacteria (Hao et al, 2017). As a result, bacteria had evolved a new detoxification strategy against metal in order to avoid lethality by protists.…”

Section: Antibacterial Biocides and Metals Resistance Genesmentioning

confidence: 99%

Whole genome analysis and characterization of Salmonella enterica subsp. enterica serovar Typhimurium strain UPM 260 for mediated genetic manipulation

Ns¹,

Nm²,

Ar³

et al. 2020

Preprint

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Background Salmonella enterica serovar Typhimurium persists as one of the most frequent food-borne zoonoses, causing a major public health concern worldwide. Furthermore, Salmonella infection has a large economic impact. Globally, the main sources of infection for humans include the consumption of contaminated poultry meat and eggs. In animals however, Salmonella transmission usually occurs horizontally from infected birds and contaminated environments. Hence, to delve further on how the impact of this disease can be lessened, an epidemiological study needs to be performed. It is vital to determine the genomic sequences of microorganisms to understand their biology and functional characterization. Thus, we determined the whole-genome sequence and virulence profile of S. enterica serovar Typhimurium strain UPM 260 isolated from Perak, Malaysia. Whole genome sequencing (WGS) using paired-end sequencing generated 107 contigs with a total genome size of 4.9 Mbp and 52% G+C content. The contigs were annotated for phylogenetic and functional analysis. Results Through the analysis, it is revealed that the genome were resistant to a number of antimicrobial drug classes including aminoglycoside, fluoroquinolone, tetracycline and phenicol. Also found in UPM 260 genome were three intact prophages (Fels-1, Gifsy-2 and one unique prophage, mEp390). The genome housed four types of restriction-modification systems (RMS) and Type I-E subtype of CRISPR-Cas system. Two metal resistance operons (mer and cop) and six pathogenicity islands (SPIs) were also discovered in UPM 260 genome. The SPIs contributed mostly to the bacterial virulence properties since 1054 CDS were reported to be homologous to the virulence factors in the database VFDB. Conclusion This study benefits us specifically in the field of genome engineering where gene-based genetic manipulations can be applied in reducing the prevalence and pathogenicity in Salmonella.

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Bacterial resistance to arsenic protects against protist killing

Cited by 15 publications

References 17 publications

Distribution of Arsenic Resistance Genes in Prokaryotes

Distribution of Arsenic Resistance Genes in Prokaryotes

Tolerance to arsenic contaminant among multidrug‐resistant and copper‐tolerant Salmonella successful clones is associated with diverse ars operons and genetic contexts

Whole genome analysis and characterization of Salmonella enterica subsp. enterica serovar Typhimurium strain UPM 260 for mediated genetic manipulation

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