Role of p-lactamase Mutations in Antibiotic Resistance Bacterial resistance to antimicrobial agents has increased in recent years and now represents a significant threat to successful antibiotic therapy. One example of this phenomenon is the development of resistance to p-lactam antibiotics, p-lactam antibiotics, such as the penicillins and cephalosporins, are among the most frequently used antimicrobialagents. The most common mechanism of resistance to P-lactam antibiotics is the production of p-lactamases, which cleave the antibiotic, rendering it harmless to bacteria. Based on primary sequence homology, p-lactamases have been grouped into four classes. Classes A, C and D arc active-siteserinc enzymes that catalyze, via a serine-bound acyl-enzyme intermediate,the hydrolysis of the p-lactam antibiotic. Class B enzymes require zinc for activity and catalysis does not proceed via a covalent intermediate.Because of the diverse range of substrate specificities of these enzymes, virtually all p-lactam antibioticsaresusceptible to hydrolysis. Clearly, the design of new antibiotics that escape hydrolysis by the growing collectionof - lactamase activitieswill be a challenge. It will be necessary to understand the catalytic mechanism and basis for substrate specificity of each class of p-lactamase. The goal of this work is understand how the amino acid sequence determines the structure, catalysis, and substrate specificityof the IMP-1 p-lactamase of class B and the P99 class C p-lactamasc. This will be achieved by randomizingamino acid positions in theactive-site pocket of each en/yme to sample all possible aminoacid substitutions. All of the random substitutions will then be screened to identify those substitutionsthat alter the substrate specificity of the enzyme. Enzymes containing substitutions that alter substrate specificitywill be purified and characterized biochemically. The sets of random substitutionswill also be screened using phage display methodology to identify residues critical for catalysis. A further goal of this proposal is to use the detailed knowledge of the interface between p- lactamase inhibitoryprotein (BLIP) and p-lactamasc, in combinationwith random mutagenesis and phage display, to create derivatives of BLIP that bind and inhibit P-lactamases and penicillin binding proteins. The new BLIP derivatives will be characterized biochemically and structurally. The informationgained from these studies will be useful for the rational design of new antibioticsand inhibitors.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Method to Extend Research in Time (MERIT) Award (R37)
Project #
5R37AI032956-19
Application #
7874594
Study Section
Special Emphasis Panel (NSS)
Program Officer
Huntley, Clayton C
Project Start
1992-07-01
Project End
2011-04-30
Budget Start
2010-05-01
Budget End
2011-04-30
Support Year
19
Fiscal Year
2010
Total Cost
$353,636
Indirect Cost
Name
Baylor College of Medicine
Department
Microbiology/Immun/Virology
Type
Schools of Medicine
DUNS #
051113330
City
Houston
State
TX
Country
United States
Zip Code
77030
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Adamski, Carolyn J; Palzkill, Timothy (2017) BLIP-II Employs Differential Hotspot Residues To Bind Structurally Similar Staphylococcus aureus PBP2a and Class A ?-Lactamases. Biochemistry 56:1075-1084
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Adamski, Carolyn J; Cardenas, Ana Maria; Brown, Nicholas G et al. (2015) Molecular basis for the catalytic specificity of the CTX-M extended-spectrum ?-lactamases. Biochemistry 54:447-57
Mehta, Shrenik C; Rice, Kacie; Palzkill, Timothy (2015) Natural Variants of the KPC-2 Carbapenemase have Evolved Increased Catalytic Efficiency for Ceftazidime Hydrolysis at the Cost of Enzyme Stability. PLoS Pathog 11:e1004949
Long, S Wesley; Olsen, Randall J; Mehta, Shrenik C et al. (2014) PBP2a mutations causing high-level Ceftaroline resistance in clinical methicillin-resistant Staphylococcus aureus isolates. Antimicrob Agents Chemother 58:6668-74

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