The thioenol ML302F was recently identified as an inhibitor of class B metallo-β-lactamases (MBLs). We assessed the activity of ML302F when combined with meropenem (MEM) against 31 carbapenem resistant Gram-negative clinical isolates. Minimum inhibitory concentrations of MEM:ML302F were determined at fixed ratios of 1:4 and 1 8 using strains producing variants of the clinically relevant VIM-like MBL. Toxicity and efficacy in vivo was assessed in a Galleria mellonella invertebrate model against strains producing VIM-1, VIM-2 and VIM-4 variants. At a fixed MEM:ML302F ratio of 1:8, 22/31 isolates were rendered either susceptible (MIC ≤ 2 mg L-1), or intermediate (MIC 4-8 mg L-1) to MEM. ML302F alone was not toxic at up to 80 mg kg-1 in G. mellonella and treatment with MEM 0.6 mg kg-1:ML302F 4.8 mg kg-1 significantly improved the survival of infected larvae. As ML302F was able to successfully restore susceptibility to resistant strains both in vitro and in vivo it represents a structurally interesting inhibitor in the search for new MBL inhibitors

Abdul Momin, MHF

Betts, JW

Brem, J

Phee, LM

Schofield, C

Umland, K-D

Wareham, DW

Brem, Jurgen

Schofield, Christopher

Oxford University Research Archive

MedChemCommCONCISE ARTICLECite this: Med. Chem. Commun.,2016, 7, 190Received 4th September 2015,Accepted 10th November 2015DOI: 10.1039/c5md00380fwww.rsc.org/medchemcommIn vitro and in vivo activity of ML302F: a thioenolateinhibitor of VIM-subfamily metallo β-lactamasesJonathan W. Betts,a Lynette M. Phee,ab Muhd H. F. Abdul Momin,aKlaus-Daniel Umland,c Jurgen Brem,c Christopher J. Schofieldcand David W. Wareham*abThe thioenol ML302F was recently identified as an inhibitor of class B metallo-β-lactamases (MBLs). Weassessed the activity of ML302F when combined with meropenem (MEM) against 31 carbapenem resistantGram-negative clinical isolates. Minimum inhibitory concentrations of MEM :ML302F were determined atfixed ratios of 1 : 4 and 1 : 8 using strains producing variants of the clinically relevant VIM-like MBL. Toxicityand efficacy in vivo was assessed in a Galleria mellonella invertebrate model against strains producing VIM-1, VIM-2 and VIM-4 variants. At a fixed MEM :ML302F ratio of 1 : 8, 22/31 isolates were rendered either sus-ceptible (MIC ≤ 2 mg L−1), or intermediate (MIC 4–8 mg L−1) to MEM. ML302F alone was not toxic at up to80 mg kg−1 in G. mellonella and treatment with MEM 0.6 mg kg−1 :ML302F 4.8 mg kg−1 significantlyimproved the survival of infected larvae. As ML302F was able to successfully restore susceptibility to resis-tant strains both in vitro and in vivo it represents a structurally interesting inhibitor in the search for newMBL inhibitors.IntroductionThe global dissemination of multi-drug resistant Gram-negative bacteria has seriously limited antibiotic treatmentoptions. As few novel synthetic antimicrobials are in develop-ment the challenge is to increase and protect the lifespan andspectrum of existing compounds for as long as possible. Thisis most important in the case of β-lactams (penicillins, cepha-losporins, carbapenems) especially when resistance occursdue to the acquisition and production of β-lactamases thatcatalyse β-lactam hydrolysis.1 There are two distinct mecha-nistic classes of β-lactamase – the nucleophilic serineenzymes and the metallo β-lactamases (MBLs). Inhibitors ofthe serine enzymes (clavulanic acid/tazobactam/avibactam)have been developed and already applied clinically.2 However,no such compounds have yet been developed to targetMBLs. The use of carbapenems such as ertapenem, imipenemor meropenem (MEM) in combination with an effectivemetallo-β-lactamase inhibitor, could prolong their lifespan aswell as increase their spectrum of use to carbapenemase pro-ducing bacteria. Thus, there are ongoing efforts to developMBL inhibitors of suitable potency and breadth of selectivityfor clinical use.3 In the latter regard the ability to inhibit thedifferent subtypes of clinically relevant MBLs and apparentlyrapidly emerging variants will likely be important.The rhodanine ML302 was initially identified as a MBLinhibitor in a high throughput screen and subsequentlycharacterised as a non-competitive inhibitor of class B (IMP,VIM, NDM) metallo-β-lactamases in vitro.4 Recently the mech-anism behind the apparent inhibition by ML302 was investi-gated in crystallographic, NMR, and kinetic studies. These,unexpectedly revealed that ML302 undergoes hydrolysis, togenerate the thioenol ML302F (Fig. 1). The thiol of ML302Fchelates the two zinc ions present in the active site of mostMBLs in a manner mimicking an intermediate in β-lactamhydrolysis.5 In some cases the observed inhibition of MBLsby ML302/ML302F combinations may involve ternary com-plexes. In some instances ML302F is able to inhibit thecarbapenemase activity of MBLs at low μM concentrations(IC50 VIM-2 0.30 μM) sufficient to restore the activity ofmeropenem against MBL-producing strains.5Neither ML302 nor ML302F have significant cytotoxicitytowards eukaryotic cells in tissue culture (>100 μM) but havenot yet been assessed in any animal model of antimicrobialtherapeutics. The wax moth caterpillar Galleria mellonella isincreasingly being used as a simple invertebrate model forpre-clinical assessment of the efficacy, toxicity and pharmaco-kinetics of antimicrobials.6–9 Here we report studies on theactivity of ML302F in combination with MEM against a col-lection of carbapenem resistant clinical isolates (Pseudomo-nas, Klebsiella, Enterobacter, Escherichia coli, Providencia)190 | Med. Chem. Commun., 2016, 7, 190–193 This journal is © The Royal Society of Chemistry 2016a Antimicrobial Research Group, Barts & The London School of Medicine andDentistry, Queen Mary University of London, London, E1 2AT, UK.E-mail: d.w.wareham@qmul.ac.ukbDivision of Infection, Barts Health NHS Trust, London, E1 1BB, UKcDepartment of Chemistry, University of Oxford, Oxford, OX1 3TA, UKPublished on 16 November 2015. Downloaded on 07/03/2017 14:47:38. View Article OnlineView Journal  | View IssueMed. Chem. Commun., 2016, 7, 190–193 | 191This journal is © The Royal Society of Chemistry 2016producing clinically relevant variants of the VIM (VIM-1/2/4)MBL. Preferred ratios of MEM to ML302F required for syn-ergy in vitro were determined and then used at a simulatedhumanized pharmacokinetic dose in the treatment of G.mellonella infected with carbapenem resistant P. aeruginosa,K. pneumoniae and E. coli.Results and discussionThe antimicrobial activities of MEM and ML302F alone andin combination were assessed in vitro against 31 VIM-producing clinical isolates. Synergy between MEM andML302F was first confirmed in checkerboard assays against7/8 isolates tested (FICI ≤ 0.5). An MEM :ML302F ratio of 1 : 4and 1 : 8 was found to be optimal resulting in a ≥4 foldreduction in the MIC of MEM.Thirty strains were either resistant (MIC > 8 mg L−1) orhad reduced susceptibility (MIC ≥ 4 mg L−1) to MEM aloneas judged by the European Committee on Antimicrobial Sus-ceptibility (EUCAST) breakpoint criteria. One K. pneumoniaeisolate harbouring blaVIM-1 was deemed susceptible (MIC 1mg L−1). ML302F had no antimicrobial activity alone at con-centrations up to 512 mg L−1.Using a fixed 1 : 8 ratio of MEM :ML302F in vitro suscepti-bility to carbapenems was increased in 22/31 (70%) of the iso-lates with 11 rendered susceptible (MIC ≤ 2 mg L−1) or inter-mediate (MIC 4–8 mg L−1). For 9 isolates, the MIC of MEMremained >8 mg L−1 (Table 1).ML302F was non-toxic when administered to G. mellonellaby injection at doses up to 80 mg kg−1 (100% survival of alllarvae at 96 h). The inoculum required for staggered killingof >50% of larvae by carbapenem resistant strains over 96 hvaried by species. The LD50 was <101, 105 and 104 CFU perlarvae for P. aeruginosa GR57, E. coli 98 and K. pneumoniaerespectively.In treatment assays, survival of ML302F (4.8 mg kg−1)treated larvae was similar to those given PBS for the treat-ment of PA GR57, EC 98 and KP 120 infections. Monotherapywith MEM (0.6 mg kg−1) was superior to either PBS andML302F (P < 0.0001), but the % survival was only 44%, 23%and 69% versus strains EC 98, PA GR57 and KP 120, respectively.The addition of ML302F to MEM significantly improved thesurvival of infected larva (P < 0.0001) compared to MEMalone, with survival rates of 69% (EC 98), 81% (PA GR57) and98% (KP 120) at 96 (Fig. 2) and a relative risk for MEM-ML302F versus MEM of 0.64, 0.28 and 0.70 for these isolates.ExperimentalMaterialsBacterial strains were from the collection of clinical isolatesheld at Queen Mary University London. Species identificationwas by analysis of MADLI-TOF mass spectrometry profiles(Bruker) and MBL detection by PCR and sequencing of theblaVIM gene Meropenem trihydrate was purchased fromRanbaxy (UK) Limited (London, UK). ML302F was producedwithin the Chemical Research Laboratories, Oxford UniversityTable 1 Minimum inhibitory concentrations (MICs) of meropenem(MEM) with and without ML302F (1 : 8) versus multidrug-resistant Gram-negative bacteria producing VIM carbapenemasesMBL IsolateMIC (mg L−1)FICIMEM MEM + ML302FVIM-1 K. pneumoniae GR54 128 4 0.09VIM-1 K. pneumoniae 177 1 1 1.02VIM-1 P. stuartii 67 8 1 0.14VIM-1 P. stuartii 70 8 1 0.14VIM-2 P. aeruginosa 30 64 8 0.25VIM-2 P. aeruginosa 47 32 1 0.05VIM-2 P. aeruginosa 50 32 8 0.38VIM-2 P. aeruginosa GR57 32 4 0.19VIM-2 P. aeruginosa GR58 32 8 0.38VIM-2 P. aeruginosa GR62 32 8 0.38VIM-2 P. aeruginosa GR64 32 4 0.19VIM-2 P. aeruginosa 3 (13) 64 8 0.25VIM-2 P. aeruginosa 8 (13) 128 16 0.38VIM-2 P. aeruginosa 9 (13) 128 16 0.38VIM-2 P. aeruginosa 11 (13) 32 2 0.09VIM-2 P. aeruginosa 6 (14) 128 16 0.38VIM-2 P. aeruginosa 11 (14) 128 32 0.75VIM-2 P. aeruginosa 12 (14) 128 32 0.75VIM-2 P. aeruginosa 13 (14) 32 16 0.75VIM-2 P. aeruginosa 14 (14) 64 2 0.06VIM-2 P. aeruginosa 15 (14) 64 16 0.5VIM-2 P. aeruginosa 16 (14) 64 16 0.5VIM-2 P. aeruginosa 27 (14) 64 16 0.5VIM-4 E. cloacae 102 32 4 0.19VIM-4 E. coli 98 16 2 0.16VIM-4 K. oxytoca 95 32 8 0.38VIM-4 K. oxytoca 126 32 4 0.19VIM-4 K. pneumoniae 101 32 2 0.09VIM-4 K. pneumoniae 120 16 2 0.25VIM-4 K. pneumoniae 128 4 1 0.27VIM-4 K. pneumoniae 196 16 1 0.08Fig. 1 Structures of (a) the thioenol ML302F, (b) the ‘parent’rhodanine ML302, (c) outline mechanism for MBL catalysed β-lactamhydrolysis as exemplified with meropenem (PDB ID: 4EYL), and (d) car-toons based on a crystal structure of ML302F (PDB ID: 4PVO)complexed with MBLs showing how the inhibitor mimics an enzyme-intermediate/product complex.MedChemComm Concise ArticlePublished on 16 November 2015. Downloaded on 07/03/2017 14:47:38. View Article Online192 | Med. Chem. Commun., 2016, 7, 190–193 This journal is © The Royal Society of Chemistry 2016(Oxford, UK). All media were purchased from SigmaAldrich(Dorset, UK).Minimum inhibitory concentrationsMinimum inhibitory concentrations (MICs) of MEM (0–64mg L−1) and ML302F (0–32 mg L−1) were determined by brothmicrotiter dilution (BMD) in Mueller-Hinton 2 cation-adjusted broth with a bacterial inocula of 105 colony formingunits (CFU) per well in accordance with Clinical LaboratoryStandards Institute (CLSI) guidance. Initial screening assayswere performed using eight Gram-negative isolates includingP. aeruginosa (VIM-2), Escherichia coli (VIM-4), Klebsiellapneumoniae (VIM-4) and Providencia stuartii (VIM-1). K.pneumoniae NCTC 9633 and P. aeruginosa ATCC 27853 wereused as MEM susceptible type strains to control BMD MICdeterminations.The activity of ML302F in combination with MEM wasassessed in checkerboard assays with fractional inhibitoryconcentration index (FICI) and MEM :ML302F ratio used toquantify interactions.10 A FICI (MIC of MEM/ML302F + MICML302F/MEM) of ≤0.5 was defined as synergy, a FICI of 0.5to 4.0 as indifferent or additive, and values of >4.0 asantagonistic. MICs for the MEM/ML302F combination strainsstudied were determined at fixed MEM :ML302F ratios of 1 : 4and 1 : 8 by BMD.Toxicity assaysThe in vivo toxicity of ML302F was assessed in the Galleriamellonella wax moth larvae model using a simple live deadranking.11 Increasing doubling concentrations of ML302F (0to 80 mg kg−1) were administered in 10 μl injections directlyinto the hemocoel of ten larvae before incubation at 37 °Cfor 96 h. Larvae were scored for mellonisation and movementevery 24 h, as live or dead. Larvae for all G. mellonella assayswere purchased from Livefood UK Ltd (Somerset, UK).G. mellonella virulence assayThe bacterial inocula required for staggered killing (50%lethal dose [LD50]) of G. mellonella by VIM producing isolatesover 96 h was determined using 10 larvae inoculated withovernight cultures of E. coli EC98, K. pneumoniae KP120 andP. aeruginosa PA GR57. Tenfold serial dilutions were madefrom washed cultures, diluted in PBS and administered in 10μl injections at final concentrations of 101–106 CFU per larvaeand incubated at 37 °C for 96 h. Larvae were scored as live ordead every 24 h.MEM/ML302F treatment assaysThe activity of MEM and ML302F alone and in combinationwere assessed using 16 G. mellonella larva as previouslydescribed.12 Larvae were inoculated with P. aeruginosa GR57,E. coli EC98 and K. pneumoniae KP120. In combination thera-pies, a fixed ratio (1 : 8) of MEM :ML302F containing 0.6 mgkg−1 of MEM8 and 4.8 mg kg−1 of ML302F was administeredin 10 μL injections to infected larvae. PBS injections (10 μL)were used as both controls for no antimicrobial therapy andinoculation injury.Larvae were scored for survival over 96 h and kill curvesanalysed by the log-rank test for trend. Relative risk (RR) ofsurvival between the different treatment arms was calculatedusing Fisher's exact test with, two-tailed P-values of <0.05considered statistically significant.ConclusionsIn combination with MEM at a 1 : 8 ratio ML302F was able torestore susceptibility to MEM amongst VIM-producingcarbapenem resistant Enterobacteriaceae (CRE) and wasactive in vivo in the G. mellonella larva invertebrate model ofCRE infection. ML302F was active against several clinicallyrelevant VIM variants. The combined results reveal thatML302F is a structurally interesting MBL inhibitor active inboth cellular and animal models and should stimulate fur-ther work on the synthesis and testing of ML302F analogues.ML302F was derived from a rhodanine by hydrolysis. We arewell aware that as a class the rhodanines have a somewhatchequered history with respect to their use as (potential)Fig. 2 Treatment assays using meropenem (MEM), ML302F and a1 : 8 (mg kg−1) combination of MEM + ML302F versus VIM-2 producingPseudomonas aeruginosa isolate GR57 (a) VIM-4 producing Escherichiacoli 98 (b) and Klebsiella pneumoniae 120 (c) over 96 h in Galleriamellonella.MedChemCommConcise ArticlePublished on 16 November 2015. Downloaded on 07/03/2017 14:47:38. View Article OnlineMed. Chem. Commun., 2016, 7, 190–193 | 193This journal is © The Royal Society of Chemistry 2016pharmaceuticals.13,14 Furthermore, one may anticipate that thedevelopment of thioenols as pharmaceuticals might be diffi-cult due to their reactivity (e.g. due to oxidation). However, asis well known the structures of many antibiotics do not fol-low recent ‘normal’ paradigms for drug structures.15 This isbeautifully exemplified by the Class A serine β-lactamaseinhibitors (clavulanic acid, tazobactam, sulbactam) that arewidely used to extend penicillin and cephalosporin use.These are themselves β-lactams which act as ‘mechanismbased’ inhibitors that undergo fragmentation on their targetβ-lactamases to produce ester linked species that are stablewith respect to hydrolysis.15 The fact that rhodanines canundergo hydrolysis (whether enzyme mediated or not in thecase of ML302/ML302F) to produce potent thioenol inhibitorsraises the question as to whether mechanism based MBLinhibitors that are β-lactams which produce thioenol inhibi-tors can be generated. In this regard the development ofmodified carbapenems (one carbapenem, faropenem is inclinical use)16 (Fig. 3) which have the potential to undergohydrolysis to produce thioenols that are MBL inhibitors maybe of interest.AcknowledgementsWe would like to gratefully acknowledge Public HealthEngland (Colindale, UK) and the General Hospital of ChestDiseases “Sotiria” (Athens, Greece) for supplying a number ofantimicrobial-resistant isolates. We thank the Medical ResearchCouncil MR/L007665/1 grant for support of J. B. and C. J. S.Notes and references1 K. Bush, Ann. N.Y. Acad. Sci., 2013, 1277, 84–90.2 A. M. Drawz, K. M. Papp-Wallace and R. A. Bonomo,Antimicrob. Agents Chemother., 2014, 58(4), 1835–1846.3 W. Fast and L. D. Sutton, Biochim. Biophys. Acta,2013, 1834(8), 1648–1659.4 T. Spicer, D. Minond, I. Enogieru, S. A. Saldanha, C. Allais,Q. Liu, B. A. Mercer, W. R. Roush and P. 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AgentsChemother., 2011, 55, 3534–3537.13 T. Mendgen, C. Steuer and C. D. Klein, J. Med. Chem.,2012, 55, 743–753.14 M. A. T. Blaskovich, J. Zuegg, A. G. Elliot and M. A. Cooper,ACS Infect. Dis., 2015, 1, 285–287.15 C. Bebrone, P. Lassaux, L. Vercheval, J. S. Sohier, A. Jehaes,E. Sauvage and M. Galleni, Drugs, 2010, 70, 651–679.16 S. Hazra, S. G. Kurz, K. Wolff, L. Nguyen, R. A. Bonomo andJ. S. Blanchard, Biochemistry, 2015, 54, 5657–5664.Fig. 3 Proposed mechanism for thioenol formation from faropenem.MedChemComm Concise ArticlePublished on 16 November 2015. Downloaded on 07/03/2017 14:47:38. View Article Online

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In vitro and in vivo activity of ML302F: a thioenolate inhibitor of VIM-subfamily metallo β-lactamases

In vitro and in vivo activity of ML302F: a thioenolate inhibitor of VIM-subfamily metallo β-lactamases

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