Anthony Shillings

Type IIA topoisomerase inhibition by a new class of antibacterial agents

Despite the success of genomics in identifying new essential bacterial genes, there is a lack of sustainable leads in antibacterial drug discovery to address increasing multidrug resistance. Type IIA topoisomerases cleave and religate DNA to regulate DNA topology and are a major class of antibacterial and anticancer drug targets, yet there is no well developed structural basis for understanding drug action. Here we report the 2.1 Å crystal structure of a potent, new class, broad-spectrum antibacterial agent in complex with Staphylococcus aureus DNA gyrase and DNA, showing a new mode of inhibition that circumvents fluoroquinolone resistance in this clinically important drug target. The inhibitor ‘bridges’ the DNA and a transient non-catalytic pocket on the two-fold axis at the GyrA dimer interface, and is close to the active sites and fluoroquinolone binding sites. In the inhibitor complex the active site seems poised to cleave the DNA, with a single metal ion observed between the TOPRIM (topoisomerase/primase) domain and the scissile phosphate. This work provides new insights into the mechanism of topoisomerase action and a platform for structure-based drug design of a new class of antibacterial agents against a clinically proven, but conformationally flexible, enzyme class.

Structural basis of quinolone inhibition of type IIA topoisomerases and target-mediated resistance.

Quinolone antibacterials have been used to treat bacterial infections for over 40 years. A crystal structure of moxifloxacin in complex with Acinetobacter baumannii topoisomerase IV now shows the wedge-shaped quinolone stacking between base pairs at the DNA cleavage site and binding conserved residues in the DNA cleavage domain through chelation of a noncatalytic magnesium ion. This provides a molecular basis for the quinolone inhibition mechanism, resistance mutations and invariant quinolone antibacterial structural features.

Enabling Lead Discovery for Histone Lysine Demethylases by High-Throughput RapidFire Mass Spectrometry

A high-throughput RapidFire mass spectrometry assay is described for the JMJD2 family of Fe2+, O2, and α-ketoglutarate-dependent histone lysine demethylases. The assay employs a short amino acid peptide substrate, corresponding to the first 15 amino acid residues of histone H3, but mutated at two positions to increase assay sensitivity. The assay monitors the direct formation of the dimethylated-Lys9 product from the trimethylated-Lys9 peptide substrate. Monitoring the formation of the monomethylated and des-methylated peptide products is also possible. The assay was validated using known inhibitors of the histone lysine demethylases, including 2,4-pyridinedicarboxylic acid and an α-ketoglutarate analogue. With a sampling rate of 7 s per well, the RapidFire technology permitted the single-concentration screening of 101 226 compounds against JMJD2C in 10 days using two instruments, typically giving Z′ values of 0.75 to 0.85. Several compounds were identified of the 8-hydroxyquinoline chemotype, a known series of inhibitors of the Lys9-specific histone demethylases. The peptide also functions as a substrate for JMJD2A, JMJD2D, and JMJD2E, thus enabling the development of assays for all 3 enzymes to monitor progress in compound selectivity. The assay represents the first report of a RapidFire mass spectrometry assay for an epigenetics target.

Identification of KasA as the cellular target of an anti-tubercular scaffold

Phenotypic screens for bactericidal compounds are starting to yield promising hits against tuberculosis. In this regard, whole-genome sequencing of spontaneous resistant mutants generated against an indazole sulfonamide (GSK3011724A) identifies several specific single-nucleotide polymorphisms in the essential Mycobacterium tuberculosis β-ketoacyl synthase (kas) A gene. Here, this genomic-based target assignment is confirmed by biochemical assays, chemical proteomics and structural resolution of a KasA-GSK3011724A complex by X-ray crystallography. Finally, M. tuberculosis GSK3011724A-resistant mutants increase the in vitro minimum inhibitory concentration and the in vivo 99% effective dose in mice, establishing in vitro and in vivo target engagement. Surprisingly, the lack of target engagement of the related β-ketoacyl synthases (FabH and KasB) suggests a different mode of inhibition when compared with other Kas inhibitors of fatty acid biosynthesis in bacteria. These results clearly identify KasA as the biological target of GSK3011724A and validate this enzyme for further drug discovery efforts against tuberculosis.

Lead Discovery for Microsomal Prostaglandin E Synthase Using a Combination of High-Throughput Fluorescent-Based Assays and RapidFire Mass Spectrometry

Microsomal prostaglandin E synthase-1 (mPGES-1) represents an attractive target for the treatment of rheumatoid arthritis and pain, being upregulated in response to inflammatory stimuli. Biochemical assays for prostaglandin E synthase activity are complicated by the instability of the substrate (PGH2) and the challenge of detection of the product (PGE2). A coupled fluorescent assay is described for mPGES-1where PGH2 is generated in situ using the action of cyclooxygenase 2 (Cox-2) on arachidonic acid. PGE2 is detected by coupling through 15-prostaglandin dehydrogenase (15-PGDH) and diaphorase. The overall coupled reaction was miniaturized to 1536-well plates and validated for high-throughput screening. For compound progression, a novel high-throughput mass spectrometry assay was developed using the RapidFire platform. The assay employs the same in situ substrate generation step as the fluorescent assay, after which both PGE2 and a reduced form of the unreacted substrate were detected by mass spectrometry. Pharmacology and assay quality were comparable between both assays, but the mass spectrometry assay was shown to be less susceptible to interference and false positives. Exploiting the throughput of the fluorescent assay and the label-free, direct detection of the RapidFire has proved to be a powerful lead discovery strategy for this challenging target.

Crystal Structures of Ask1-Inhibtor Complexes Provide a Platform for Structure Based Drug Design.

ASK1, a member of the MAPK Kinase Kinase family of proteins has been shown to play a key role in cancer, neurodegeneration and cardiovascular diseases and is emerging as a possible drug target. Here we describe a ‘replacement‐soaking’ method that has enabled the high‐throughput X‐ray structure determination of ASK1/ligand complexes. Comparison of the X‐ray structures of five ASK1/ligand complexes from 3 different chemotypes illustrates that the ASK1 ATP binding site is able to accommodate a range of chemical diversity and different binding modes. The replacement‐soaking system is also able to tolerate some protein flexibility. This crystal system provides a robust platform for ASK1/ligand structure determination and future structure based drug design.

Crystallization and initial crystallographic analysis of covalent DNA‐cleavage complexes of Staphyloccocus aureus DNA gyrase with QPT‐1, moxifloxacin and etoposide

Fluoroquinolone drugs such as moxifloxacin kill bacteria by stabilizing the normally transient double-stranded DNA breaks created by bacterial type IIA topoisomerases. Previous crystal structures of Staphylococcus aureus DNA gyrase with asymmetric DNAs have had static disorder (with the DNA duplex observed in two orientations related by the pseudo-twofold axis of the complex). Here, 20-base-pair DNA homoduplexes were used to obtain crystals of covalent DNA-cleavage complexes of S. aureus DNA gyrase. Crystals with QPT-1, moxifloxacin or etoposide diffracted to between 2.45 and 3.15 Å resolution. A G/T mismatch introduced at the ends of the DNA duplexes facilitated the crystallization of slightly asymmetric complexes of the inherently flexible DNA-cleavage complexes.

Inhibitors of the DNA-cleavage gate of bacterial type IIA topoisomerases

Type IIA topoisomerases resolve topological problems in DNA by making a double-stranded break in one DNA segment, passing another DNA duplex through this break, and then resealing the break. Drugs (such as the widely used fluoroquinolone antibacterials and anti-cancer compounds such as etoposide) that stabilize double-strandedly cleaved DNA complexes with type IIA topoisomerases are cytotoxic. In GlaxoSmithKline a new class of novel bacterial topoisomerase inhibitors (NBTIs) have been developed. A 2.1Å crystal structure of a complex of GSK299423 with DNA and S. aureus DNA gyrase showed how the NBTI inhibits the enzyme by interacting with both the DNA and the protein. A pocket occupied by the compound in the protein (at the dimer interface) is absent in the apo structure, while the pocket occupied by the compound in the DNA has been formed by the enzyme stretching and untwisting the DNA between the two active sites. The NBTI structure has trapped a pre-cleavage complex of the enzyme, before the four base-pair double stranded break has occurred, and the structure gives insights into the role of metal ions in the cleavage mechanism of type IIA topoisomerases. Stuctures suggest how relatively small movements at the active sites (for example an ~3Å movement of a magnesium ion) can cause the cleavage of phosphate ester bonds and are coupled to the large domain movements involved in the catalytic cycle of these conformationally flexible enzymes. The binding site for the NBTI is close to but distinct from those for fluoroquinolones. Structures shows how the fluoroquinolone interacts with both the protein and the DNA by binding a non-catalytic magnesium ion and four associated waters. This provides a structural explanation for both fluoroquinolone resistance mutations and SAR (structure-activity relationships). Mechanistic implications of recent structural studies will be discussed.

Structural studies on bacterial type IIA topoisomerases - targets for quinolone and coumarin antibiotics

25th European Crystallographic Meeting, ECM 25, İstanbul, 2009 Acta Cryst. (2009). A65, s 25 Page s 25 FA1-MS07-O1 Structural Studies on Bacterial Type IIA Topoisomerases-Targets for Quinolone and Coumarin Antibiotics. Ben Baxa, Martin Hibbsa, Emma Jonesa, Andrew Theobalda, Andrew Fosberrya, Claus Spitzfadena, Anthony Shillingsa, Alexandre Wohlkoniga, Kristin K. Koretkeb, Jianzhong Huangb, Neil Pearsonb, Michael N. Gwynnb . aGlaxoSmithKline, Harlow, Essex, UK. b GlaxoSmithKline, Pennsylvania, USA. E-mail: benjamin.d.bax@gsk.com