The Oxyanion Hole in Serine beta-Lactamase Catalysis: Interactions of Thiono Substrates with the Active Site

Restricted Rotational Flexibility of the C5α-Methyl-Substituted Carbapenem NA-1-157 Leads to Potent Inhibition of the GES-5 Carbapenemase

Carbapenem antibiotics are used as a last-resort treatment for infections caused by multidrug-resistant bacteria. The wide spread of carbapenemases in Gram-negative bacteria has severely compromised the utility of these drugs and represents a serious public health threat. To combat carbapenemase-mediated resistance, new antimicrobials and inhibitors of these enzymes are urgently needed. Here, we describe the interaction of the atypically C5α-methyl-substituted carbapenem, NA-1-157, with the GES-5 carbapenemase. MICs of this compound against Escherichia coli, Klebsiella pneumoniae, and Acinetobacter baumannii producing the enzyme were reduced 4-16-fold when compared to MICs of the commercial carbapenems, reaching clinically sensitive breakpoints. When NA-1-157 was combined with meropenem, a strong synergistic effect was observed. Kinetic and ESI-LC/MS studies demonstrated that NA-1-157 is a potent inhibitor of GES-5, with a high inactivation efficiency of (2.9 ± 0.9) × 105 M-1 s-1. Acylation of GES-5 by NA-1-157 was biphasic, with the fast phase completing within seconds, and the slow phase taking several hours and likely proceeding through a reversible tetrahedral intermediate. Deacylation was extremely slow (k3 = (2.4 ± 0.3) × 10-7 s-1), resulting in a residence time of 48 ± 6 days. MD simulation of the GES-5-meropenem and GES-5-NA-1-157 acyl-enzyme complexes revealed that the C5α-methyl group in NA-1-157 sterically restricts rotation of the 6α-hydroxyethyl group preventing ingress of the deacylating water into the vicinity of the scissile bond of the acyl-enzyme intermediate. These data demonstrate that NA-1-157 is a potent irreversible inhibitor of the GES-5 carbapenemase.

Unique Diacidic Fragments Inhibit the OXA-48 Carbapenemase and Enhance the Killing of Escherichia coli Producing OXA-48

Despite the advances in β-lactamase inhibitor development, limited options exist for the class D carbapenemase known as OXA-48. OXA-48 is one of the most prevalent carbapenemases in carbapenem-resistant Enterobacteriaceae infections and is not susceptible to most available β-lactamase inhibitors. Here, we screened various low-molecular-weight compounds (fragments) against OXA-48 to identify functional scaffolds for inhibitor development. Several biphenyl-, naphthalene-, fluorene-, anthraquinone-, and azobenzene-based compounds were found to inhibit OXA-48 with low micromolar potency despite their small size. Co-crystal structures of OXA-48 with several of these compounds revealed key interactions with the carboxylate-binding pocket, Arg214, and various hydrophobic residues of β-lactamase that can be exploited in future inhibitor development. A number of the low-micromolar-potency inhibitors, across different scaffolds, synergize with ampicillin to kill Escherichia coli expressing OXA-48, albeit at high concentrations of the respective inhibitors. Additionally, several compounds demonstrated micromolar potency toward the OXA-24 and OXA-58 class D carbapenemases that are prevalent in Acinetobacter baumannii. This work provides foundational information on a variety of chemical scaffolds that can guide the design of effective OXA-48 inhibitors that maintain efficacy as well as potency toward other major class D carbapenemases.

In Crystallo Time-Resolved Interaction of the Clostridioides difficile CDD-1 enzyme with Avibactam Provides New Insights into the Catalytic Mechanism of Class D β-lactamases

Class D β-lactamases have risen to notoriety due to their wide spread in bacterial pathogens, propensity to inactivate clinically important β-lactam antibiotics, and ability to withstand inhibition by the majority of classical β-lactamase inhibitors. Understanding the catalytic mechanism of these enzymes is thus vitally important for the development of novel antibiotics and inhibitors active against infections caused by antibiotic-resistant bacteria. Here we report an in crystallo time-resolved study of the interaction of the class D β-lactamase CDD-1 from Clostridioides difficile with the diazobicyclooctane inhibitor, avibactam. We show that the catalytic carboxylated lysine, a residue that is essential for both acylation and deacylation of β-lactams, is sequestered within an internal sealed pocket of the enzyme. Time-resolved snapshots generated in this study allowed us to observe decarboxylation of the lysine and movement of CO2 and water molecules through a transient channel formed between the lysine pocket and the substrate binding site facilitated by rotation of the side chain of a conserved leucine residue. These studies provide novel insights on avibactam binding to CDD-1 and into the catalytic mechanism of class D β-lactamases in general.

Inhibition of the Clostridioides difficile Class D β-Lactamase CDD-1 by Avibactam

Avibactam is a potent diazobicyclooctane inhibitor of class A and C β-lactamases. The inhibitor also exhibits variable activity against some class D enzymes from Gram-negative bacteria; however, its interaction with recently discovered class D β-lactamases from Gram-positive bacteria has not been studied. Here, we describe microbiological, kinetic, and mass spectrometry studies of the interaction of avibactam with CDD-1, a class D β-lactamase from the clinically important pathogen Clostridioides difficile, and show that avibactam is a potent irreversible mechanism-based inhibitor of the enzyme. X-ray crystallographic studies at three time-points demonstrate the rapid formation of a stable CDD-1-avibactam acyl-enzyme complex and highlight differences in the anchoring of the inhibitor by class D enzymes from Gram-positive and Gram-negative bacteria.

Structural Basis and Binding Kinetics of Vaborbactam in Class A β-Lactamase Inhibition

Class A β-lactamases are a major cause of β-lactam resistance in Gram-negative bacteria. The recently FDA-approved cyclic boronate vaborbactam is a reversible covalent inhibitor of class A β-lactamases, including CTX-M extended-spectrum β-lactamase and KPC carbapenemase, both frequently observed in the clinic. Intriguingly, vaborbactam displayed different binding kinetics and cell-based activity for these two enzymes, despite their similarity. A 1.0-Å crystal structure of CTX-M-14 demonstrated that two catalytic residues, K73 and E166, are positively charged and neutral, respectively. Meanwhile, a 1.25-Å crystal structure of KPC-2 revealed a more compact binding mode of vaborbactam versus CTX-M-14, as well as alternative conformations of W105. Together with kinetic analysis of W105 mutants, the structures demonstrate the influence of this residue and the unusual conformation of the β3 strand on the inactivation rate, as well as the stability of the reversible covalent bond with S70. Furthermore, studies of KPC-2 S130G mutant shed light on the different impacts of S130 in the binding of vaborbactam versus avibactam, another recently approved β-lactamase inhibitor. Taken together, these new data provide valuable insights into the inhibition mechanism of vaborbactam and future development of cyclic boronate inhibitors.

A surface loop modulates activity of the Bacillus class D β-lactamases

The expression of β-lactamases is a major mechanism of bacterial resistance to the β-lactam antibiotics. Four molecular classes of β-lactamases have been described (A, B, C and D), however until recently the class D enzymes were thought to exist only in Gram-negative bacteria. In the last few years, class D enzymes have been discovered in several species of Gram-positive microorganisms, such as Bacillus and Clostridia, and an investigation of their kinetic and structural properties has begun in earnest. Interestingly, it was observed that some species of Bacillus produce two distinct class D β-lactamases, one highly active and the other with only basal catalytic activity. Analysis of amino acid sequences of active (BPU-1 from Bacillus pumilus) and inactive (BSU-2 from Bacillus subtilis and BAT-2 from Bacillus atrophaeus) enzymes suggests that presence of three additional amino acid residues in one of the surface loops of inefficient β-lactamases may be responsible for their severely diminished activity. Our structural and docking studies show that the elongated loop of these enzymes severely restricts binding of substrates. Deletion of the three residues from the loops of BSU-2 and BAT-2 β-lactamases relieves the steric hindrance and results in a significant increase in the catalytic activity of the enzymes. These data show that this surface loop plays an important role in modulation of the catalytic activity of Bacillus class D β-lactamases.

The crystal structures of CDD-1, the intrinsic class D β-lactamase from the pathogenic Gram-positive bacterium Clostridioides difficile, and its complex with cefotaxime

Class D β-lactamases, enzymes that degrade β-lactam antibiotics and are widely spread in Gram-negative bacteria, were for a long time not known in Gram-positive organisms. Recently, these enzymes were identified in various non-pathogenic Bacillus species and subsequently in Clostridioides difficile, a major clinical pathogen associated with high morbidity and mortality rates. Comparison of the BPU-1 enzyme from Bacillus pumilus with the CDD-1 and CDD-2 enzymes from C. difficile demonstrated that the latter enzymes have broadened their substrate profile to efficiently hydrolyze the expanded-spectrum methoxyimino cephalosporins, cefotaxime and ceftriaxone. These two antibiotics are major contributors to the development of C. difficile infection, as they suppress sensitive bacterial microflora in the gut but fail to kill the pathogen which is highly resistant to these drugs. To gain insight into the structural features that contribute to the expansion of the substrate profile of CDD enzymes compared to BPU-1, we solved the crystal structures of CDD-1 and its complex with cefotaxime. Comparison of CDD-1 structures with those of class D enzymes from Gram-negative bacteria showed that in the cefotaxime-CDD-1 complex, the antibiotic is bound in a substantially different mode due to structural differences in the enzymes' active sites. We also found that CDD-1 has a uniquely long Ω-loop when compared to all other class D β-lactamases. This Ω-loop extension allows it to engage in hydrogen bonding with the acylated cefotaxime, thus providing additional stabilizing interactions with the substrate which could be responsible for the high catalytic activity of the enzyme for expanded-spectrum cephalosporins.

Class D β-lactamases do exist in Gram-positive bacteria

Production of β-lactamases of the four molecular classes (A, B, C, and D) is the major mechanism of bacterial resistance to β-lactams, the largest class of antibiotics that have saved countless lives since their inception 70 years ago. Although several hundred efficient class D enzymes have been identified in Gram-negative pathogens over the last four decades, they have not been reported in Gram-positive bacteria. Here we demonstrate that efficient class D β-lactamases capable of hydrolyzing a wide array of β-lactam substrates are widely disseminated in various species of environmental Gram-positive organisms. Class D enzymes of Gram-positive bacteria have a distinct structural architecture and employ a unique substrate binding mode quite different from that of all currently known class A, C, and D β-lactamases. They constitute a novel reservoir of antibiotic resistance enzymes.

OXA-198, an acquired carbapenem-hydrolyzing class D beta-lactamase from Pseudomonas aeruginosa

A carbapenem-resistant Pseudomonas aeruginosa strain (PA41437) susceptible to expanded-spectrum cephalosporins was recovered from several consecutive lower-respiratory-tract specimens of a patient who developed a ventilator-associated pneumonia while hospitalized in an intensive care unit. Cloning experiments identified OXA-198, a new class D β-lactamase which was weakly related (less than 45% amino acid identity) to other class D β-lactamases. Expression in Escherichia coli TOP10 and in P. aeruginosa PAO1 led to transformants that were resistant to ticarcillin and showed reduced susceptibility to carbapenems and cefepime. The bla(OXA-198) gene was harbored by a class 1 integron carried by a ca. 46-kb nontypeable plasmid. This study describes a novel class D β-lactamase involved in carbapenem resistance in P. aeruginosa.

Kinetics and mechanism of inhibition of a serine beta-lactamase by O-aryloxycarbonyl hydroxamates

The class C serine beta-lactamase of Enterobacter cloacae P99 is irreversibly inhibited by O-aryloxycarbonyl hydroxamates. A series of these new inhibitors has been prepared to investigate the kinetics and mechanism of the inactivation reaction. A pH-rate profile for the reaction indicated that the reactive form of the inhibitor is neutral rather than anionic. The reaction rate is enhanced by electron-withdrawing aryloxy substituents and by hydrophobic substitution on both aryloxy and hydroxamate groups. Kinetics studies show that the rates of loss of the two possible leaving groups, aryloxide and hydroxamate, are essentially the same as the rate of enzyme inactivation. Nucleophilic trapping experiments prove, however, that the aryl oxide is the first to leave. It is likely, therefore, that the rate-determining step of inactivation is the initial acylation reaction, most likely of the active site serine, yielding a hydroxamoyl-enzyme intermediate. This then partitions between hydrolysis and aminolysis by Lys 315, the latter to form an inactive, cross-linked active site. A previously described crystal structure of the inactivated enzyme shows a carbamate cross-link of Ser 64 and Lys 315. Structure-activity studies of the reported compounds suggest that they do not react at the enzyme active site in the same way as normal substrates. In particular, it appears that the initial acylation by these compounds does not involve the oxyanion hole, an unprecedented departure from known and presumed reactivity. Molecular modeling suggests that an alternative oxyanion hole may have been recruited, consisting of the side chain functional groups of Tyr 150 and Lys 315. Such an alternative mode of reaction may lead to the design of novel inhibitors.

Atomic resolution structures of CTX-M beta-lactamases: extended spectrum activities from increased mobility and decreased stability

Extended spectrum beta-lactamases (ESBLs) confer bacterial resistance to third-generation cephalosporins, such as cefotaxime and ceftazidime, increasing hospital mortality rates. Whereas these antibiotics are almost impervious to classic beta-lactamases, such as TEM-1, ESBLs have one to four orders greater activity against them. The origins of this activity have been widely studied for the TEM and SHV-type ESBLs, but have received less attention for the CTX-M beta-lactamases, an emerging family that is now the dominant ESBL in several regions. To understand how CTX-M beta-lactamases achieve their remarkable activity, biophysical and structural studies were undertaken. Using reversible, two-state thermal denaturation, it was found that as these enzymes evolve a broader substrate range, they sacrifice stability. Thus, the mutant enzyme CTX-M-16 is eightfold more active against ceftazidime than the pseudo-wild-type CTX-M-14 but is 1.9 kcal/mol less stable. This is consistent with a "stability-activity tradeoff," similar to that observed in the evolution of other resistance enzymes. To investigate the structural basis of enzyme activity and stability, the structures of four CTX-M enzymes were determined by X-ray crystallography. The structures of CTX-M-14, CTX-M-27, CTX-M-9 and CTX-M-16 were determined to 1.10 Angstroms, 1.20 Angstroms, 0.98 Angstroms and 1.74 Angstroms resolution, respectively. The enzyme active sites resemble those of the narrow-spectrum TEM-1 and SHV-1, and not the enlarged sites typical of ESBL mutants such as TEM-52 and TEM-64. Instead, point substitutions leading to specific interactions may be responsible for the improved activity against ceftazidime and cefotaxime, consistent with observations first made for the related Toho-1 enzyme. The broadened substrate range of CTX-M-16 may result from coupled defects in the enzyme's B3 strand, which lines the active site. Substitutions Val231-->Ala and Asp240-->Gly, which convert CTX-M-14 into CTX-M-16, occur at either end of this strand. These defects appear to increase the mobility of B3 based on anisotropic B-factor analyses at ultrahigh resolution, consistent with stability loss and activity gain. The unusually high resolution of these structures that makes such analyses possible also makes them good templates for inhibitor discovery.