Β-Lactamase inhibitor

Beta-lactamases are a family of enzymes involved in bacterial resistance to beta-lactam antibiotics. In bacterial resistance to beta-lactam antibiotics, the bacteria have beta-lactamase which degrade the beta-lactam rings, rendering the antibiotic ineffective. However, with beta-lactamase inhibitors, these enzymes on the bacteria are inhibited, thus allowing the antibiotic to take effect. Strategies for combating this form of resistance have included the development of new beta-lactam antibiotics that are more resistant to cleavage and the development of the class of enzyme inhibitors called beta-lactamase inhibitors.^[1] Although β-lactamase inhibitors have little antibiotic activity of their own,^[2] they prevent bacterial degradation of beta-lactam antibiotics and thus extend the range of bacteria the drugs are effective against.

Clavulanic acid

Sulbactam

Tazobactam

Avibactam

Durlobactam

Relebactam

Vaborbactam

Enmetazobactam

Medical uses

The most important use of beta-lactamase inhibitors is in the treatment of infections known or believed to be caused by gram-negative bacteria, as beta-lactamase production is an important contributor to beta-lactam resistance in these pathogens. In contrast, most beta-lactam resistance in gram-positive bacteria is due to variations in penicillin-binding proteins that lead to reduced binding to the beta-lactam.^[3][4] The gram-positive pathogen Staphylococcus aureus produces beta-lactamases, but beta-lactamase inhibitors play a lesser role in treatment of these infections because the most resistant strains (methicillin-resistant Staphylococcus aureus) also use variant penicillin-binding proteins.^[5][6]

Mechanism of action

homology and presumed phylogenetic relationships. Classes A, C and D cleave beta-lactams by a multi-step mechanism analogous to the mechanism of serine proteases. Upon binding, a serine hydroxyl group in the beta-lactamase active site forms a transient covalent bond to the beta-lactam ring carbonyl group, cleaving the beta-lactam ring in the process. In a second step, nucleophilic attack by a water molecule cleaves the covalent bond between the enzyme and the carbonyl group of the erstwhile beta-lactam. This allows the degraded beta-lactam to diffuse away and frees up the enzyme to process additional beta-lactam molecules.^{[citation needed]}

Currently available beta-lactamase inhibitors are effective against Ambler Class A beta-lactamases (tazobactam, clavulanate, and sulbactam) or against Ambler Class A, C and some Class D beta-lactamases (avibactam). Like beta-lactam antibiotics, they are processed by beta-lactamases to form an initial covalent intermediate. Unlike the case of beta-lactam antibiotics, the inhibitors act as suicide substrates (tazobactam and sulbactam) which ultimately leads to the degradation of the beta-lactamase.^[7] Avibactam on the other hand does not contain a beta-lactam ring (non beta-lactam beta-lactamase inhibitor), and instead binds reversibly.^[8][9]

Ambler Class B beta-lactamases cleave beta-lactams by a mechanism similar to that of metalloproteases. As no covalent intermediate is formed, the mechanism of action of marketed beta-lactamase inhibitors is not applicable. Thus the spread of bacterial strains expressing metallo beta-lactamases such as the New Delhi metallo-beta-lactamase 1 has engendered considerable concern.^[10]

Commonly used agents

Currently marketed β-lactamase inhibitors are not sold as individual drugs. Instead they are co-formulated with a β-lactam antibiotic with a similar serum half-life. This is done not only for dosing convenience, but also to minimize resistance development that might occur as a result of varying exposure to one or the other drug. The main classes of β-lactam antibiotics used to treat gram-negative bacterial infections include (in approximate order of intrinsic resistance to cleavage by β-lactamases) penicillins (especially aminopenicillins and ureidopenicillins), 3rd generation cephalosporins, and carbapenems. Individual β-lactamase variants may target one or many of these drug classes, and only a subset will be inhibited by a given β-lactamase inhibitor.^[9] β-lactamase inhibitors expand the useful spectrum of these β-lactam antibiotics by inhibiting the β-lactamase enzymes produced by bacteria to deactivate them.^[11]

• β-lactamase inhibitors with a β-lactam core:
  • Tebipenem is the first carbapenem to be administered orally in the form of tebipenem-pivoxil. Structural and kinetic studies of tebipenem is available with M. tuberculosis beta-lactamase (BlaC).^[12]
  • Clavulanic acid or clavulanate, usually combined with amoxicillin (Augmentin) or ticarcillin (Timentin)
  • Sulbactam, usually combined with ampicillin (Unasyn) or cefoperazone (Sulperazon)
  • Tazobactam, usually combined with piperacillin (Zosyn, Tazocin)
  • Enmetazobactam, usually combined with cefepime (Exblifep)
• β-lactamase inhibitors with a diazabicyclooctane core:
  • Avibactam, approved in combination with ceftazidime (Avycaz, Zavicefta), currently undergoing clinical trials for combination with ceftaroline
  • Durlobactam, approved in combination with sulbactam (Xacduro) to treat hospital‑acquired bacterial pneumonia and ventilator-associated bacterial pneumonia (HABP/VABP) pneumonia caused by Acinetobacter baumannii-calcoaceticus complex
  • Relebactam, used in combination with imipenem/cilastatin (Recarbrio).^[13][14]
• β-lactamase inhibitors with other types of non β-lactam cores:
  • Vaborbactam, used in combination with meropenem (Vabomere). Has a boronic acid core.^[15]

Beta-lactamase producing bacteria

Bacteria that can produce beta-lactamases include, but are not limited to:^{[citation needed]}

• Staphylococcus
  • MRSA(Methicillin-resistant Staphylococcus aureus)
• Enterobacteriaceae:
  • Klebsiella pneumoniae
  • Citrobacter
  • Proteus vulgaris
  • Morganella
  • Salmonella
  • Shigella
  • Escherichia coli
• Haemophilus influenzae
• Moraxella catarrhalis
• Neisseria gonorrhoeae
• Pseudomonas aeruginosa
• Mycobacterium tuberculosis

Research

Some bacteria can produce extended spectrum β-lactamases (ESBLs) making the infection more difficult to treat and conferring additional resistance to penicillins, cephalosporins, and monobactams.^[16] Boronic acid derivatives are currently under vast and extensive research as novel active site inhibitors for beta-lactamases because they contain a site that mimics the transition state that beta-lactams go through when undergoing hydrolysis via beta-lactamases. They have been found generally to fit well into the active site of many beta-lactamases and have the convenient property of being unable to be hydrolysed, and therefore rendered useless. This is a favorable drug design over many clinically used competing agents, because most of them, such as clavulanic acid, become hydrolysed, and are therefore only useful for a finite period of time. This generally causes the need for a higher concentration of competitive inhibitor than would be necessary in an unhydrolyzable inhibitor. Different boronic acid derivatives have the potential to be tailored to the many different isoforms of beta-lactamases, and therefore have the potential to reestablish potency of beta-lactam antibiotics.^[17]

References

1. Essack SY (October 2001). "The development of beta-lactam antibiotics in response to the evolution of beta-lactamases". Pharmaceutical Research. 18 (10): 1391–9. doi:10.1023/a:1012272403776. PMID 11697463. S2CID 34318096.
2. "Beta-Lactamase Inhibitors". Department of Nursing of the Fort Hays State University College of Health and Life Sciences. October 2000. Archived from the original on 2007-09-27. Retrieved 2007-08-17.
3. Georgopapadakou NH (October 1993). "Penicillin-binding proteins and bacterial resistance to beta-lactams". Antimicrobial Agents and Chemotherapy. 37 (10): 2045–53. doi:10.1128/aac.37.10.2045. PMC 192226. PMID 8257121.
4. Zapun A, Contreras-Martel C, Vernet T (March 2008). "Penicillin-binding proteins and beta-lactam resistance". FEMS Microbiology Reviews. 32 (2): 361–85. doi:10.1111/j.1574-6976.2007.00095.x. PMID 18248419.
5. Curello J, MacDougall C (July 2014). "Beyond Susceptible and Resistant, Part II: Treatment of Infections Due to Gram-Negative Organisms Producing Extended-Spectrum β-Lactamases". The Journal of Pediatric Pharmacology and Therapeutics. 19 (3): 156–64. doi:10.5863/1551-6776-19.3.156. PMC 4187532. PMID 25309145.
6. Wolter DJ, Lister PD (2013). "Mechanisms of β-lactam resistance among Pseudomonas aeruginosa". Current Pharmaceutical Design. 19 (2): 209–22. doi:10.2174/13816128130203. PMID 22894618.
7. Patrick, Graham L. (2017). An introduction to medicinal chemistry (6th ed.). Oxford, United Kingdom. ISBN 9780198749691. OCLC 987051883.{{cite book}}: CS1 maint: location missing publisher (link)
8. Lahiri SD, Mangani S, Durand-Reville T, Benvenuti M, De Luca F, Sanyal G, Docquier JD (June 2013). "Structural insight into potent broad-spectrum inhibition with reversible recyclization mechanism: avibactam in complex with CTX-M-15 and Pseudomonas aeruginosa AmpC β-lactamases". Antimicrobial Agents and Chemotherapy. 57 (6): 2496–505. doi:10.1128/AAC.02247-12. PMC 3716117. PMID 23439634.
9. Drawz SM, Bonomo RA (January 2010). "Three decades of beta-lactamase inhibitors". Clinical Microbiology Reviews. 23 (1): 160–201. doi:10.1128/CMR.00037-09. PMC 2806661. PMID 20065329.
10. Biedenbach D, Bouchillon S, Hackel M, Hoban D, Kazmierczak K, Hawser S, Badal R (February 2015). "Dissemination of NDM metallo-β-lactamase genes among clinical isolates of Enterobacteriaceae collected during the SMART global surveillance study from 2008 to 2012". Antimicrobial Agents and Chemotherapy. 59 (2): 826–30. doi:10.1128/AAC.03938-14. PMC 4335866. PMID 25403666.
11. Watson ID, Stewart MJ, Platt DJ (September 1988). "Clinical pharmacokinetics of enzyme inhibitors in antimicrobial chemotherapy". Clinical Pharmacokinetics. 15 (3): 133–64. doi:10.2165/00003088-198815030-00001. PMID 3052984. S2CID 2388750.
12. Hazra S, Xu H, Blanchard JS (June 2014). "Tebipenem, a new carbapenem antibiotic, is a slow substrate that inhibits the β-lactamase from Mycobacterium tuberculosis". Biochemistry. 53 (22): 3671–8. doi:10.1021/bi500339j. PMC 4053071. PMID 24846409.
13. "FDA approves new treatment for complicated urinary tract and complicated intra-abdominal infections". Food and Drug Administration. July 17, 2019. Archived from the original on November 20, 2019. Retrieved July 18, 2019.
14. "Cilastatin/imipenem/relebactam — AdisInsight". Springer International Publishing AG. Archived from the original on 31 May 2016. Retrieved 29 April 2016.
15. "FDA approves new antibacterial drug" (Press release). Food and Drug Administration. August 29, 2017. Archived from the original on April 23, 2019. Retrieved July 18, 2019.
16. Livermore DM (October 1995). "beta-Lactamases in laboratory and clinical resistance". Clinical Microbiology Reviews. 8 (4): 557–84. doi:10.1128/cmr.8.4.557. PMC 172876. PMID 8665470.
17. Leonard DA, Bonomo RA, Powers RA (November 2013). "Class D β-lactamases: a reappraisal after five decades". Accounts of Chemical Research. 46 (11): 2407–15. doi:10.1021/ar300327a. PMC 4018812. PMID 23902256.

External links

• Xu H, Hazra S, Blanchard JS (June 2012). "NXL104 irreversibly inhibits the β-lactamase from Mycobacterium tuberculosis". Biochemistry. 51 (22): 4551–7. doi:10.1021/bi300508r. PMC 3448018. PMID 22587688.
• Kurz SG, Wolff KA, Hazra S, Bethel CR, Hujer AM, Smith KM, Xu Y, Tremblay LW, Blanchard JS, Nguyen L, Bonomo RA (December 2013). "Can inhibitor-resistant substitutions in the Mycobacterium tuberculosis β-Lactamase BlaC lead to clavulanate resistance?: a biochemical rationale for the use of β-lactam-β-lactamase inhibitor combinations". Antimicrobial Agents and Chemotherapy. 57 (12): 6085–96. doi:10.1128/AAC.01253-13. PMC 3837893. PMID 24060876.