A Bifan Motif Shaped by ArsR1, ArsR2, and Their Cognate Promoters Frames Arsenic Tolerance of

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2021 Mar 29

PMID 33776973

Citations 2

Authors

Gonzalo Durante-Rodriguez

David Paez-Espino

Victor de Lorenzo

Affiliations

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Abstract

Prokaryotic tolerance to inorganic arsenic is a widespread trait habitually determined by operons encoding an As (III)-responsive repressor (ArsR), an As (V)-reductase (ArsC), and an As (III)-export pump (ArsB), often accompanied by other complementary genes. Enigmatically, the genomes of many environmental bacteria typically contain two or more copies of this basic genetic device . To shed some light on the logic of such apparently unnecessary duplication(s) we have inspected the regulation-together and by separate-of the two clusters borne by the soil bacterium strain KT2440, in particular the cross talk between the two repressors ArsR1/ArsR2 and the respective promoters. DNase I footprinting and gel retardation analyses of and with their matching regulators revealed non-identical binding sequences and interaction patterns for each of the systems. However, transcription experiments exposed that the repressors could downregulate each other's promoters, albeit within a different set of parameters. The regulatory frame that emerges from these data corresponds to a particular type of bifan motif where all key interactions have a negative sign. The distinct regulatory architecture that stems from coexistence of various ArsR variants in the same cells could enter an adaptive advantage that favors the maintenance of the two proteins as separate repressors.

Citing Articles

Pavlovian-Type Learning in Environmental Bacteria: Regulation of Herbicide Resistance by Arsenic in Pseudomonas putida.

Paez-Espino D, Durante-Rodriguez G, Fernandes E, Carmona M, de Lorenzo V Environ Microbiol. 2024; 26(12):e70012.

PMID: 39667752 PMC: 11637737. DOI: 10.1111/1462-2920.70012.

Biotechnology Advances in Bioremediation of Arsenic: A Review.

Preetha J, Arun M, Vidya N, Kowsalya K, Halka J, Ondrasek G Molecules. 2023; 28(3).

PMID: 36771138 PMC: 9921067. DOI: 10.3390/molecules28031474.

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