Spectroscopic studies of substrate interactions with clavaminate synthase 2, a multifunctional alpha-KG-dependent non-heme iron enzyme: correlation with mechanisms and reactivities

Using a single ferrous active site, clavaminate synthase 2 (CS2) activates O(2) and catalyzes the hydroxylation of deoxyguanidinoproclavaminic acid (DGPC), the oxidative ring closure of proclavaminic acid (PC), and the desaturation of dihydroclavaminic acid (and a substrate analogue, deoxyproclavaminic acid (DPC)), each coupled to the oxidative decarboxylation of cosubstrate, alpha-ketoglutarate (alpha-KG). CS2 can also catalyze an uncoupled decarboxylation of alpha-KG both in the absence and in the presence of substrate, which results in enzyme deactivation. Resting CS2/Fe(II) has a six-coordinate Fe(II) site, and alpha-KG binds to the iron in a bidentate mode. The active site becomes five-coordinate only when both substrate and alpha-KG are bound, the latter still in a bidentate mode. Absorption, CD, MCD, and VTVH MCD studies of the interaction of CS2 with DGPC, PC, and DPC provide significant molecular level insight into the structure/function correlations of this multifunctional enzyme. There are varying amounts of six-coordinate ferrous species in the substrate complexes, which correlate to the uncoupled reaction. Five-coordinate ferrous species with similar geometric and electronic structures are present for all three substrate/alpha-KG complexes. Coordinative unsaturation of the Fe(II) in the presence of both cosubstrate and substrate appears to be critical for the coupling of the oxidative decarboxylation of alpha-KG to the different substrate oxidation reactions. In addition to the substrate orientation relative to the open coordination position on the iron site, it is hypothesized that the enzyme can affect the nature of the reactivity by further regulating the binding energy of the water to the ferrous species in the enzyme/succinate/product complex.

Structure of beta-lactam synthetase reveals how to synthesize antibiotics instead of asparagine

The enzyme beta-lactam synthetase (beta-LS) catalyzes the formation of the beta-lactam ring in clavulanic acid, a clinically important beta-lactamase inhibitor. Whereas the penicillin beta-lactam ring is generated by isopenicillin N synthase (IPNS) in the presence of ferrous ion and dioxygen, beta-LS uses ATP and Mg2+ as cofactors. According to sequence alignments, beta-LS is homologous to class B asparagine synthetases (AS-Bs), ATP/Mg2+-dependent enzymes that convert aspartic acid to asparagine. Here we report the first crystal structure of a beta-LS. The 1.95 A resolution structure of Streptomyces clavuligerus beta-LS provides a fully resolved view of the active site in which substrate, closely related ATP analog alpha,beta-methyleneadenosine 5'-triphosphate (AMP-CPP) and a single Mg2+ ion are present. A high degree of substrate preorganization is observed. Comparison to Escherichia coli AS-B reveals the evolutionary changes that have taken place in beta-LS that impede interdomain reaction, which is essential in AS-B, and that accommodate beta-lactam formation. The structural data provide the opportunity to alter the synthetic potential of beta-LS, perhaps leading to the creation of new beta-lactamase inhibitors and beta-lactam antibiotics.

Haemophilus ducreyi associates with phagocytes, collagen, and fibrin and remains extracellular throughout infection of human volunteers

In a previous study, Haemophilus ducreyi was found in the pustule and dermis of samples obtained at the clinical end point in the human model of infection. To understand the kinetics of localization, we examined infected sites at 0, 24, and 48 h after inoculation and at the clinical end point. Immediately after inoculation, bacteria were found predominantly in the dermis but also in the epidermis. Few bacteria were detectable at 24 h; however, by 48 h, bacteria were readily seen in the pustule and dermis. H. ducreyi was associated with polymorphonuclear leukocytes and macrophages in the pustule and at its base, but was not associated with T cells, Langerhans' cells, or fibroblasts. H. ducreyi colocalized with collagen and fibrin but not laminin or fibronectin. Association with phagocytes, collagen, and fibrin was seen as early as 48 h and persisted at the pustular stage of disease. Optical sectioning by confocal microscopy and transmission electron microscopy both failed to demonstrate intracellular H. ducreyi. These data identify collagen and fibrin as potentially important targets of adherence in vivo and strongly suggest that H. ducreyi remains extracellular throughout infection and survives by resisting phagocytic killing in vivo.

Kinetic mechanism of the beta-lactam synthetase of Streptomyces clavuligerus

Streptomyces clavuligerus beta-lactam synthetase (beta-LS) was recently demonstrated to catalyze an early step in clavulanic acid biosynthesis, the ATP/Mg(2+)-dependent intramolecular closure of the beta-amino acid N(2)-(carboxyethyl)-L-arginine (CEA) to the monocyclic beta-lactam deoxyguanidinoproclavaminic acid (DGPC). Here we investigate the steady-state kinetic mechanism of the beta-LS-catalyzed reaction to better understand this unprecedented secondary metabolic enzyme. Initial velocity patterns were consistent with a sequential ordered bi-ter kinetic mechanism. Product inhibition studies with PP(i) and DGPC demonstrated competitive inhibition versus their cognate substrates ATP and CEA, respectively, and noncompetitive inhibition against their noncognate substrates. To clarify the order of substrate binding, the truncated substrate analogue N(2)-(carboxymethyl)-L-arginine was synthesized and demonstrated uncompetitive inhibition versus ATP and competitive patterns versus CEA. These data are consistent with ordered substrate binding, with ATP binding first, an abortive enzyme-DGPC complex, and PP(i) released as the last product. The pH dependence of V and V/K was determined and suggests that residues with a pK of 6.5 and 9.3 must be ionized for optimal activity. These observations were considered in the context of investigations of the homologous primary metabolic enzyme asparagine synthetase B, and a chemical mechanism is proposed that is consistent with the kinetic mechanism.

A new class of antituberculosis agents

Long-chain lipid envelopes are characteristic of mycobacteria such as those that cause tuberculosis and leprosy. Inhibition of fatty acid synthesis or elongation is a strategy demonstrated to be clinically effective against M. tuberculosis. A new class of compounds designed to inhibit the beta-ketoacyl synthase reaction of fatty acid synthesis has been developed. Of >30 compounds described, the most active were acetamides containing alkylsulfonyl substituents. Inhibitory activities were acutely sensitive to net charge, chain length, and degree of unsaturation. The most active compound 5 (alkyl = C(10)) contained a single methylene spacer between the sulfone and carboxamide and exhibited an MIC of 0.75-1.5 microg/mL, comparable to first-line antituberculosis drugs. These compounds are species-specific, exhibiting no significant activity against bacterial species other than M. tuberculosis and closely related strains. The synthesis, biological activity, and specificity of these compounds are described.

Site-directed mutagenesis and biochemical analysis of the endogenous ligands in the ferrous active site of clavaminate synthase. The His-3 variant of the 2-His-1-carboxylate model

The facial 2-His-1-carboxylate (Asp/Glu) motif has emerged as the structural paradigm for metal binding in the alpha-ketoglutarate (alpha-KG)-dependent nonheme iron oxygenases. Clavaminate synthase (CS2) is an unusual member of this enzyme family that mediates three different, nonsequential reactions during the biosynthesis of the beta-lactamase inhibitor clavulanic acid. In this study, covalent modification of CS2 by the affinity label N-bromoacetyl-L-arginine near His297, which is within the HRV signature of a His-2 motif, suggested this histidine could play a role in metal coordination. However, site-specific mutagenesis of eight His residues to Gln identified His145 and His280, but not His297, as involved in iron binding. Weak homology of His145 and its flanking sequence and the presence of Glu147 fitting the canonical acidic residue of the His-Xaa-Asp/Glu signature are consistent with His145 being a coordinating ligand (His-1). His280 and its flanking sequence, which give poor alignments to most other members of this enzyme family, are similar among a subset of these enzymes and notably to CarC, an apparent oxygenase involved in carbapenem biosynthesis. The separation of His145 and His280 is more than twice that seen in the current 2-His-1-carboxylate model and may define an alternative iron binding motif, which we propose as His-3. These ligand assignments, based on kinetic measurements of both oxidative cyclization/desaturation and hydroxylation assays, establish that no histidine ligand switching occurs during the catalytic cycle. These results are confirmed in a recent X-ray crystal structure of CS1, a highly similar isozyme of CS2 (81% identical). Tyr299, Tyr300 in CS2 modified by N-bromoacetyl-L-arginine, is hydrogen bonded to Glu146 (Glu147 in CS2) in this structure and well-positioned for reaction with the affinity label.

Expansion of the clavulanic acid gene cluster: identification and in vivo functional analysis of three new genes required for biosynthesis of clavulanic acid by Streptomyces clavuligerus

Clavulanic acid is a potent inhibitor of beta-lactamase enzymes and is of demonstrated value in the treatment of infections by beta-lactam-resistant bacteria. Previously, it was thought that eight contiguous genes within the genome of the producing strain Streptomyces clavuligerus were sufficient for clavulanic acid biosynthesis, because they allowed production of the antibiotic in a heterologous host (K. A. Aidoo, A. S. Paradkar, D. C. Alexander, and S. E. Jensen, p. 219-236, In V. P. Gullo et al., ed., Development in industrial microbiology series, 1993). In contrast, we report the identification of three new genes, orf10 (cyp), orf11 (fd), and orf12, that are required for clavulanic acid biosynthesis as indicated by gene replacement and trans-complementation analysis in S. clavuligerus. These genes are contained within a 3.4-kb DNA fragment located directly downstream of orf9 (cad) in the clavulanic acid cluster. While the orf10 (cyp) and orf11 (fd) proteins show homologies to other known CYP-150 cytochrome P-450 and [3Fe-4S] ferredoxin enzymes and may be responsible for an oxidative reaction late in the pathway, the protein encoded by orf12 shows no significant similarity to any known protein. The results of this study extend the biosynthetic gene cluster for clavulanic acid and attest to the importance of analyzing biosynthetic genes in the context of their natural host. Potential functional roles for these proteins are proposed.