Journal
MOLECULAR CELL
Volume 57, Issue 6, Pages 1088-1098Publisher
CELL PRESS
DOI: 10.1016/j.molcel.2015.02.009
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Funding
- NIH [GM081882, GM022778]
- JSPS
- Howard Hughes Medical Institute
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Bacteria regularly encounter widely varying metal concentrations in their surrounding environment. As metals become depleted or, conversely, accrue to toxicity, microbes will activate cellular responses that act to maintain metal homeostasis. A suite of metal-sensing regulatory (metalloregulatory'') proteins orchestrate these responses by allosterically coupling the selective binding of target metals to the activity of DNA-binding domains. However, we report here the discovery, validation, and structural details of a widespread class of riboswitch RNAs, whose members selectively and tightly bind the low-abundance transition metals, Ni2+ and Co2+. These riboswitches bind metal cooperatively, and with affinities in the low micromolar range. The structure of a Co2+-bound RNA reveals a network of molecular contacts that explains how it achieves cooperative binding between adjacent sites. These findings reveal that bacteria have evolved to utilize highly selective metalloregulatory riboswitches, in addition to metalloregulatory proteins, for detecting and responding to toxic levels of heavy metals.
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