(1) Background: Metallo-β-lactamases (MBLs) have raised concerns due to their ability to inactivate carbapenems and newer generation cephalosporins and the absence of clinically available MBL inhibitors. Their genes are often transferred horizontally, and the number of MBL variants has grown exponentially, with many newer variants showing enhanced enzyme activity or stability. In this study, we investigated a closely related group of variants from the IMP family that all contain the combination of mutations S115T and S119G relative to IMP-1. (2) Methods: The effects of each individual mutation and their combination in the IMP-1 sequence background in comparison to IMP-1 were investigated. Their ability to confer resistance and their in-cell expression levels were determined. All enzymes were purified, and their secondary structure and thermal stability were determined with circular dichroism. Their Zn(II) content and kinetic constants with a panel of β-lactam antibiotics were determined. (3) Results: All four enzymes were viable and conferred resistance to all antibiotics tested except aztreonam. However, the single-mutant enzymes were slightly deficient, IMP-1S115T due to decreased enzyme activity and IMP-1-S119G due to decreased thermal stability and expression, while the double mutant did not show these defects. (4) Conclusions: These observations suggest that S119G was acquired due to its increased enzyme activity and S115T to suppress the thermal stability and expression defect introduced by S119G.
(1) Background: Metallo-β-lactamases (MBLs) have raised concerns due to their ability to inactivate carbapenems and newer generation cephalosporins and the absence of clinically available MBL inhibitors. Their genes are often transferred horizontally, and the number of MBL variants has grown exponentially, with many newer variants showing enhanced enzyme activity or stability. In this study, we investigated a closely related group of variants from the IMP family that all contain the combination of mutations S115T and S119G relative to IMP-1. (2) Methods: The effects of each individual mutation and their combination in the IMP-1 sequence background in comparison to IMP-1 were investigated. Their ability to confer resistance and their in-cell expression levels were determined. All enzymes were purified, and their secondary structure and thermal stability were determined with circular dichroism. Their Zn(II) content and kinetic constants with a panel of β-lactam antibiotics were determined. (3) Results: All four enzymes were viable and conferred resistance to all antibiotics tested except aztreonam. However, the single-mutant enzymes were slightly deficient, IMP-1S115T due to decreased enzyme activity and IMP-1-S119G due to decreased thermal stability and expression, while the double mutant did not show these defects. (4) Conclusions: These observations suggest that S119G was acquired due to its increased enzyme activity and S115T to suppress the thermal stability and expression defect introduced by S119G.
Authors: Alecander E LaCuran; Kevin M Pegg; Eleanor M Liu; Christopher R Bethel; Ni Ai; William J Welsh; Robert A Bonomo; Peter Oelschlaeger Journal: Antimicrob Agents Chemother Date: 2015-09-14 Impact factor: 5.191
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
Authors: Alesha C Stewart; Christopher R Bethel; Jamie VanPelt; Alex Bergstrom; Zishuo Cheng; Callie G Miller; Cameron Williams; Robert Poth; Matthew Morris; Olivia Lahey; Jay C Nix; David L Tierney; Richard C Page; Michael W Crowder; Robert A Bonomo; Walter Fast Journal: ACS Infect Dis Date: 2017-10-11 Impact factor: 5.084
Authors: Zishuo Cheng; Christopher R Bethel; Pei W Thomas; Ben A Shurina; John-Paul Alao; Caitlyn A Thomas; Kundi Yang; Steven H Marshall; Huan Zhang; Aidan M Sturgill; Andrea N Kravats; Richard C Page; Walter Fast; Robert A Bonomo; Michael W Crowder Journal: Antimicrob Agents Chemother Date: 2021-03-18 Impact factor: 5.191