Life (Nov 2020)

Dual RNase and β-lactamase Activity of a Single Enzyme Encoded in Archaea

  • Seydina M. Diene,
  • Lucile Pinault,
  • Nicholas Armstrong,
  • Said Azza,
  • Vivek Keshri,
  • Saber Khelaifia,
  • Eric Chabrière,
  • Gustavo Caetano-Anolles,
  • Jean-Marc Rolain,
  • Pierre Pontarotti,
  • Didier Raoult

DOI
https://doi.org/10.3390/life10110280
Journal volume & issue
Vol. 10, no. 11
p. 280

Abstract

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β-lactam antibiotics have a well-known activity which disturbs the bacterial cell wall biosynthesis and may be cleaved by β-lactamases. However, these drugs are not active on archaea microorganisms, which are naturally resistant because of the lack of β-lactam target in their cell wall. Here, we describe that annotation of genes as β-lactamases in Archaea on the basis of homologous genes is a remnant of identification of the original activities of this group of enzymes, which in fact have multiple functions, including nuclease, ribonuclease, β-lactamase, or glyoxalase, which may specialized over time. We expressed class B β-lactamase enzyme from Methanosarcina barkeri that digest penicillin G. Moreover, while weak glyoxalase activity was detected, a significant ribonuclease activity on bacterial and synthetic RNAs was demonstrated. The β-lactamase activity was inhibited by β-lactamase inhibitor (sulbactam), but its RNAse activity was not. This gene appears to have been transferred to the Flavobacteriaceae group especially the Elizabethkingia genus, in which the expressed gene shows a more specialized activity on thienamycin, but no glyoxalase activity. The expressed class C-like β-lactamase gene, from Methanosarcina sp., also shows hydrolysis activity on nitrocefin and is more closely related to DD-peptidase enzymes. Our findings highlight the need to redefine the nomenclature of β-lactamase enzymes and the specification of multipotent enzymes in different ways in Archaea and bacteria over time.

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