Biochemical and structural characterization of alanine racemase from Bacillus anthracis (Ames)

<p>Abstract</p> <p>Background</p> <p><it>Bacillus anthracis </it>is the causative agent of anthrax and a potential bioterrorism threat. Here we report the biochemical and structural characterization of <it>B. anthracis </it>(Ames) alanine racemase (Alr_<it>Bax</it>), an essential enzyme in prokaryotes and a target for antimicrobial drug development. We also compare the native Alr_{<it>Bax </it>}structure to a recently reported structure of the same enzyme obtained through reductive lysine methylation.</p> <p>Results</p> <p><it>B. anthracis </it>has two open reading frames encoding for putative alanine racemases. We show that only one, <it>dal1</it>, is able to complement a D-alanine auxotrophic strain of <it>E. coli</it>. Purified Dal1, which we term Alr_<it>Bax</it>, is shown to be a dimer in solution by dynamic light scattering and has a V_maxfor racemization (L- to D-alanine) of 101 U/mg. The crystal structure of unmodified Alr_{<it>Bax </it>}is reported here to 1.95 Å resolution. Despite the overall similarity of the fold to other alanine racemases, Alr_{<it>Bax </it>}makes use of a chloride ion to position key active site residues for catalysis, a feature not yet observed for this enzyme in other species. Crystal contacts are more extensive in the methylated structure compared to the unmethylated structure.</p> <p>Conclusion</p> <p>The chloride ion in Alr_{<it>Bax </it>}is functioning effectively as a carbamylated lysine making it an integral and unique part of this structure. Despite differences in space group and crystal form, the two Alr_{<it>Bax </it>}structures are very similar, supporting the case that reductive methylation is a valid rescue strategy for proteins recalcitrant to crystallization, and does not, in this case, result in artifacts in the tertiary structure.</p

The crystal structure of alanine racemase from Streptococcus pneumoniae, a target for structure-based drug design

<p>Abstract</p> <p>Background</p> <p><it>Streptococcus pneumoniae </it>is a globally important pathogen. The Gram-positive diplococcus is a leading cause of pneumonia, otitis media, bacteremia, and meningitis, and antibiotic resistant strains have become increasingly common over recent years.Alanine racemase is a ubiquitous enzyme among bacteria and provides the essential cell wall precursor, D-alanine. Since it is absent in humans, this enzyme is an attractive target for the development of drugs against <it>S. pneumoniae </it>and other bacterial pathogens.</p> <p>Results</p> <p>Here we report the crystal structure of alanine racemase from <it>S. pneumoniae </it>(Alr_SP). Crystals diffracted to a resolution of 2.0 Å and belong to the space group P3₁21 with the unit cell parameters a = b = 119.97 Å, c = 118.10 Å, α = β = 90° and γ = 120°. Structural comparisons show that Alr_SPshares both an overall fold and key active site residues with other bacterial alanine racemases. The active site cavity is similar to other Gram positive alanine racemases, featuring a restricted but conserved entryway.</p> <p>Conclusions</p> <p>We have solved the structure of Alr_SP, an essential step towards the development of an accurate pharmacophore model of the enzyme, and an important contribution towards our on-going alanine racemase structure-based drug design project. We have identified three regions on the enzyme that could be targeted for inhibitor design, the active site, the dimer interface, and the active site entryway.</p

An Adaptive Mutation in Enterococcus faecium LiaR Associated with Antimicrobial Peptide Resistance Mimics Phosphorylation and Stabilizes LiaR in an Activated State

The cyclic antimicrobial lipopeptide daptomycin (DAP) triggers the LiaFSR membrane stress response pathway in enterococci and many other Gram-positive organisms. LiaR is the response regulator that, upon phosphorylation, binds in a sequence-specific manner to DNA to regulate transcription in response to membrane stress. In clinical settings, non-susceptibility to DAP by Enterococcus faecium is correlated frequently with a mutation in LiaR of Trp73 to Cys (LiaRW73C). We have determined the structure of the activated E. faecium LiaR protein at 3.2 Å resolution and, in combination with solution studies, show that the activation of LiaR induces the formation of a LiaR dimer that increases LiaR affinity at least 40-fold for the extended regulatory regions upstream of the liaFSR and liaXYZ operons. In vitro, LiaRW73C induces phosphorylation-independent dimerization of LiaR and provides a biochemical basis for non-susceptibility to DAP by the upregulation of the LiaFSR regulon. A comparison of the E. faecalis LiaR, E. faecium LiaR, and the LiaR homolog from Staphylococcus aureus (VraR) and the mutations associated with DAP resistance suggests that physicochemical properties such as oligomerization state and DNA specificity, although tuned to the biology of each organism, share some features that could be targeted for new antimicrobials

Purification and preliminary crystallization of alanine racemase from Streptococcus pneumoniae

<p>Abstract</p> <p>Background</p> <p>Over the past fifteen years, antibiotic resistance in the Gram-positive opportunistic human pathogen <it>Streptococcus pneumoniae </it>has significantly increased. Clinical isolates from patients with community-acquired pneumonia or otitis media often display resistance to two or more antibiotics. Given the need for new therapeutics, we intend to investigate enzymes of cell wall biosynthesis as novel drug targets. Alanine racemase, a ubiquitous enzyme among bacteria and absent in humans, provides the essential cell wall precursor, D-alanine, which forms part of the tetrapeptide crosslinking the peptidoglycan layer.</p> <p>Results</p> <p>The alanine racemases gene from <it>S. pneumoniae </it>(<it>alr</it>_<it>SP</it>) was amplified by PCR and cloned and expressed in <it>Escherichia coli</it>. The 367 amino acid, 39854 Da dimeric enzyme was purified to electrophoretic homogeneity and preliminary crystals were obtained. Racemic activity was demonstrated through complementation of an <it>alr </it>auxotroph of <it>E. coli </it>growing on L-alanine. In an alanine racemases photometric assay, specific activities of 87.0 and 84.8 U mg^-1were determined for the conversion of D- to L-alanine and L- to D-alanine, respectively.</p> <p>Conclusion</p> <p>We have isolated and characterized the alanine racemase gene from the opportunistic human pathogen <it>S. pneumoniae</it>. The enzyme shows sufficient homology with other alanine racemases to allow its integration into our ongoing structure-based drug design project.</p

Evolutionary fates within a microbial population highlight an essential role for protein folding during natural selection

Physicochemical properties of molecules can be linked directly to evolutionary fates of a population in a quantitative and predictive manner.Reversible- and irreversible-folding pathways must be accounted for to accurately determine in vitro kinetic parameters (KM and kcat) at temperatures or conditions in which a significant fraction of free enzyme is unfolded.In vivo population dynamics can be reproduced using in vitro physicochemical measurements within a model that imposes an activity threshold above which there is no added fitness benefit

Antimicrobial sensing coupled with cell membrane remodeling mediates antibiotic resistance and virulence in Enterococcus faecalis.

Bacteria have developed several evolutionary strategies to protect their cell membranes (CMs) from the attack of antibiotics and antimicrobial peptides (AMPs) produced by the innate immune system, including remodeling of phospholipid content and localization. Multidrug-resistant Enterococcus faecalis, an opportunistic human pathogen, evolves resistance to the lipopeptide daptomycin and AMPs by diverting the antibiotic away from critical septal targets using CM anionic phospholipid redistribution. The LiaFSR stress response system regulates this CM remodeling via the LiaR response regulator by a previously unknown mechanism. Here, we characterize a LiaR-regulated protein, LiaX, that senses daptomycin or AMPs and triggers protective CM remodeling. LiaX is surface exposed, and in daptomycin-resistant clinical strains, both LiaX and the N-terminal domain alone are released into the extracellular milieu. The N-terminal domain of LiaX binds daptomycin and AMPs (such as human LL-37) and functions as an extracellular sentinel that activates the cell envelope stress response. The C-terminal domain of LiaX plays a role in inhibiting the LiaFSR system, and when this domain is absent, it leads to activation of anionic phospholipid redistribution. Strains that exhibit LiaX-mediated CM remodeling and AMP resistance show enhanced virulence in the Caenorhabditis elegans model, an effect that is abolished in animals lacking an innate immune pathway crucial for producing AMPs. In conclusion, we report a mechanism of antibiotic and AMP resistance that couples bacterial stress sensing to major changes in CM architecture, ultimately also affecting host-pathogen interactions

Biochemical characterization of cardiolipin synthase mutations associated with daptomycin resistance in enterococci

Daptomycin (DAP) resistance in enterococci has been linked to mutations in genes that alter the cell envelope stress response (CESR) (liaFSR) and changes in enzymes that directly affect phospholipid homeostasis, and these changes may alter membrane composition, such as that of cardiolipin synthase (Cls). While Cls substitutions are observed in response to DAP therapy, the effect of these mutations on Cls activity remains obscure. We have expressed, purified, and characterized Cls enzymes from both Enterococcus faecium S447 (residues 52 to 482; Cls447a) and Enterococcus faecalis S613 (residues 53 to 483; Cls613a) as well as Cls variants harboring a single-amino-acid change derived from DAP-resistant isolates of E. faecium. E. faecium Cls447a and E. faecalis Cls613a are tightly associated with the membrane and copurify with their substrate, phosphatidylglycerol (PG), and product, cardiolipin (CL). The amount of PG that copurifies with Cls is in molar excess to protein, suggesting that the enzyme localizes to PG-rich membrane regions. Both Cls447aH215R and Cls447aR218Q showed an increase in Vmax (μM CL/min/μM protein) from 0.16 ± 0.01 to 0.26 ± 0.02 and 0.26 ± 0.04, respectively, indicating that mutations associated with adaptation to DAP increase Cls activity. Modeling of Cls447a to Streptomyces sp. phospholipase D indicates that the adaptive mutations Cls447aH215R and Cls447aR218Q are proximal to the phospholipase domain 1 (PLD1) active site and near the putative nucleophile H217. As mutations to Cls are part of a larger genomic adaptation process, increased Cls activity is likely to be highly epistatic with other changes to facilitate DAP resistance

Two mutations commonly associated with daptomycin resistance in enterococcus faecium liaST120A and liaRW73C appear to function epistatically in liaFSR signaling

The cyclic antimicrobial lipopeptide daptomycin is now frequently used as a first-line therapy in serious infections caused by multidrug-resistant Enterococcus faecium. Resistance to daptomycin in E. faecium is mediated by activation of the LiaFSR membrane stress response pathway. Deletion of liaR, encoding the response regulator of the system, restores susceptibility to daptomycin, suggesting that the LiaFSR pathway is a potential target for the development of drugs that would induce hypersusceptibility to daptomycin and make it more difficult for enterococci to become daptomycin-resistant. In clinical isolates of E. faecium, substitutions in the membrane-bound histidine kinase LiaS (T120A) and its response regulator LiaR (W73C) are found together, suggesting a potential epistatic relationship in daptomycin resistance. Using in vitro phosphorylation studies, we show that while the phosphotransfer rate of wild-type LiaS and LiaST120A to either wild-type LiaR or LiaRW73C remains rapid and comparable, the LiaS-dependent dephosphorylation rate of phosphorylated LiaRW73C is markedly higher. When the two adaptive mutants LiaRW73C and LiaST210A are paired, however, LiaS-mediated LiaR dephosphorylation is restored back to wild-type levels. Taken together with earlier work showing that LiaRW73C leads to an increased level of oligomerization and subsequently favors an increased level of transcription of the LiaFSR regulon, the net effect of the two commonly found LiaST120A and LiaRW73C alleles would be to coordinately increase the strength and persistence of LiaFSR signaling and decrease daptomycin susceptibility. The in vitro approaches developed in this work also provide the basis for screens for identifying drug candidates that inhibit the LiaFSR pathway

Structure analysis of free and bound states of an RNA aptamer against ribosomal protein S8 from Bacillus anthracis

Several protein-targeted RNA aptamers have been identified for a variety of applications and although the affinities of numerous protein-aptamer complexes have been determined, the structural details of these complexes have not been widely explored. We examined the structural accommodation of an RNA aptamer that binds bacterial r-protein S8. The core of the primary binding site for S8 on helix 21 of 16S rRNA contains a pair of conserved base triples that mold the sugar-phosphate backbone to S8. The aptamer, which does not contain the conserved sequence motif, is specific for the rRNA binding site of S8. The protein-free RNA aptamer adopts a helical structure with multiple non-canonical base pairs. Surprisingly, binding of S8 leads to a dramatic change in the RNA conformation that restores the signature S8 recognition fold through a novel combination of nucleobase interactions. Nucleotides within the non-canonical core rearrange to create a G-(G-C) triple and a U-(A-U)-U quartet. Although native-like S8-RNA interactions are present in the aptamer-S8 complex, the topology of the aptamer RNA differs from that of the helix 21-S8 complex. This is the first example of an RNA aptamer that adopts substantially different secondary structures in the free and protein-bound states and highlights the remarkable plasticity of RNA secondary structure