Literature DB >> 26424398

B1-Metallo-β-Lactamases: Where Do We Stand?

Maria F Mojica, Robert A Bonomo1, Walter Fast2.   

Abstract

Metallo-β-Lactamases (MBLs) are class Bβ-lactamases that hydrolyze almost all clinically-availableβ-lactam antibiotics. MBLs feature the distinctive αβ/βα sandwich fold of the metallo-hydrolase/oxidoreductase superfamily and possess a shallow active-site groove containing one or two divalent zinc ions, flanked by flexible loops. According to sequence identity and zinc ion dependence, MBLs are classified into three subclasses (B1, B2 and B3), of which the B1 subclass enzymes have emerged as the most clinically significant. Differences among the active site architectures, the nature of zinc ligands, and the catalytic mechanisms have limited the development of a common inhibitor. In this review, we will describe the molecular epidemiology and structural studies of the most prominent representatives of class B1 MBLs (NDM-1, IMP-1 and VIM-2) and describe the implications for inhibitor design to counter this growing clinical threat.

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Year:  2016        PMID: 26424398      PMCID: PMC4814356          DOI: 10.2174/1389450116666151001105622

Source DB:  PubMed          Journal:  Curr Drug Targets        ISSN: 1389-4501            Impact factor:   3.465


  163 in total

Review 1.  Expansion of the zinc metallo-hydrolase family of the beta-lactamase fold.

Authors:  H Daiyasu; K Osaka; Y Ishino; H Toh
Journal:  FEBS Lett       Date:  2001-08-10       Impact factor: 4.124

2.  Analysis of the importance of the metallo-beta-lactamase active site loop in substrate binding and catalysis.

Authors:  Catherine Moali; Christine Anne; Josette Lamotte-Brasseur; Sylvie Groslambert; Bart Devreese; Jozef Van Beeumen; Moreno Galleni; Jean Marie Frère
Journal:  Chem Biol       Date:  2003-04

3.  Hydroxyl groups in the (beta)beta sandwich of metallo-beta-lactamases favor enzyme activity: a computational protein design study.

Authors:  Peter Oelschlaeger; Stephen L Mayo
Journal:  J Mol Biol       Date:  2005-07-15       Impact factor: 5.469

Review 4.  Targeting metallo-β-lactamase enzymes in antibiotic resistance.

Authors:  Dustin T King; Natalie C J Strynadka
Journal:  Future Med Chem       Date:  2013-07       Impact factor: 3.808

Review 5.  Mode of action of beta-lactam antibiotics.

Authors:  D J Tipper
Journal:  Pharmacol Ther       Date:  1985       Impact factor: 12.310

6.  Increased prevalence and clonal dissemination of multidrug-resistant Pseudomonas aeruginosa with the blaIMP-1 gene cassette in Hiroshima.

Authors:  Syuntaro Kouda; Masaru Ohara; Makoto Onodera; Yoshihiro Fujiue; Megumi Sasaki; Tadahiro Kohara; Seiya Kashiyama; Shizue Hayashida; Toshie Harino; Takahiro Tsuji; Hideyuki Itaha; Naomasa Gotoh; Akio Matsubara; Tsuguru Usui; Motoyuki Sugai
Journal:  J Antimicrob Chemother       Date:  2009-04-27       Impact factor: 5.790

7.  Molecular characterization of an enterobacterial metallo beta-lactamase found in a clinical isolate of Serratia marcescens that shows imipenem resistance.

Authors:  E Osano; Y Arakawa; R Wacharotayankun; M Ohta; T Horii; H Ito; F Yoshimura; N Kato
Journal:  Antimicrob Agents Chemother       Date:  1994-01       Impact factor: 5.191

8.  Antibiotic recognition by binuclear metallo-beta-lactamases revealed by X-ray crystallography.

Authors:  James Spencer; Jonathan Read; Richard B Sessions; Steven Howell; G Michael Blackburn; Steven J Gamblin
Journal:  J Am Chem Soc       Date:  2005-10-19       Impact factor: 15.419

9.  Chromophore-linked substrate (CLS405): probing metallo-β-lactamase activity and inhibition.

Authors:  Anne Makena; Sander S van Berkel; Clarisse Lejeune; Raymond J Owens; Anil Verma; Ramya Salimraj; James Spencer; Jürgen Brem; Christopher J Schofield
Journal:  ChemMedChem       Date:  2013-10-25       Impact factor: 3.466

10.  Biochemical, mechanistic, and spectroscopic characterization of metallo-β-lactamase VIM-2.

Authors:  Mahesh Aitha; Amy R Marts; Alex Bergstrom; Abraham Jon Møller; Lindsay Moritz; Lucien Turner; Jay C Nix; Robert A Bonomo; Richard C Page; David L Tierney; Michael W Crowder
Journal:  Biochemistry       Date:  2014-11-13       Impact factor: 3.162
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  62 in total

1.  Activity of Cefiderocol, Ceftazidime-Avibactam, and Eravacycline against Carbapenem-Resistant Escherichia coli Isolates from the United States and International Sites in Relation to Clonal Background, Resistance Genes, Coresistance, and Region.

Authors:  Brian D Johnston; Paul Thuras; Stephen B Porter; Melissa Anacker; Brittany VonBank; Paula Snippes Vagnone; Medora Witwer; Mariana Castanheira; James R Johnson
Journal:  Antimicrob Agents Chemother       Date:  2020-09-21       Impact factor: 5.191

Review 2.  The Growing Threat of Antibiotic Resistance in Children.

Authors:  Rachel L Medernach; Latania K Logan
Journal:  Infect Dis Clin North Am       Date:  2018-03       Impact factor: 5.982

3.  Dipicolinic Acid Derivatives as Inhibitors of New Delhi Metallo-β-lactamase-1.

Authors:  Allie Y Chen; Pei W Thomas; Alesha C Stewart; Alexander Bergstrom; Zishuo Cheng; Callie Miller; Christopher R Bethel; Steven H Marshall; Cy V Credille; Christopher L Riley; Richard C Page; Robert A Bonomo; Michael W Crowder; David L Tierney; Walter Fast; Seth M Cohen
Journal:  J Med Chem       Date:  2017-08-30       Impact factor: 7.446

4.  NDM-5 and OXA-181 Beta-Lactamases, a Significant Threat Continues To Spread in the Americas.

Authors:  Laura J Rojas; Andrea M Hujer; Susan D Rudin; Meredith S Wright; T Nicholas Domitrovic; Steven H Marshall; Kristine M Hujer; Sandra S Richter; Eric Cober; Federico Perez; Mark D Adams; David van Duin; Robert A Bonomo
Journal:  Antimicrob Agents Chemother       Date:  2017-06-27       Impact factor: 5.191

Review 5.  A close look onto structural models and primary ligands of metallo-β-lactamases.

Authors:  Joanna E Raczynska; Ivan G Shabalin; Wladek Minor; Alexander Wlodawer; Mariusz Jaskolski
Journal:  Drug Resist Updat       Date:  2018-08-25       Impact factor: 18.500

6.  Investigation of Dipicolinic Acid Isosteres for the Inhibition of Metallo-β-Lactamases.

Authors:  Allie Y Chen; Pei W Thomas; Zishuo Cheng; Nasa Y Xu; David L Tierney; Michael W Crowder; Walter Fast; Seth M Cohen
Journal:  ChemMedChem       Date:  2019-05-24       Impact factor: 3.466

Review 7.  Metallo-β-Lactamases: Structure, Function, Epidemiology, Treatment Options, and the Development Pipeline.

Authors:  Sara E Boyd; David M Livermore; David C Hooper; William W Hope
Journal:  Antimicrob Agents Chemother       Date:  2020-09-21       Impact factor: 5.191

8.  Aztreonam plus Clavulanate, Tazobactam, or Avibactam for Treatment of Infections Caused by Metallo-β-Lactamase-Producing Gram-Negative Bacteria.

Authors:  Cécile Emeraud; Lelia Escaut; Athénaïs Boucly; Nicolas Fortineau; Rémy A Bonnin; Thierry Naas; Laurent Dortet
Journal:  Antimicrob Agents Chemother       Date:  2019-04-25       Impact factor: 5.191

9.  An integrated biophysical approach to discovering mechanisms of NDM-1 inhibition for several thiol-containing drugs.

Authors:  Sarah Fullington; Zishuo Cheng; Caitlyn Thomas; Callie Miller; Kundi Yang; Lin-Cheng Ju; Alexander Bergstrom; Ben A Shurina; Stacey Lowery Bretz; Richard C Page; David L Tierney; Michael W Crowder
Journal:  J Biol Inorg Chem       Date:  2020-06-04       Impact factor: 3.358

Review 10.  NDM Metallo-β-Lactamases and Their Bacterial Producers in Health Care Settings.

Authors:  Wenjing Wu; Yu Feng; Guangmin Tang; Fu Qiao; Alan McNally; Zhiyong Zong
Journal:  Clin Microbiol Rev       Date:  2019-01-30       Impact factor: 26.132
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