Vancomycin-arginine (STM-001) abrogates ESBL carrier and carbapenem-resistant Escherichia coli burden in a murine complicated urinary tract infection model.

OBJECTIVES: STM-001, a retargeted glycopeptide, is active against MDR E. coli expressing ESBLs including carbapenemases. Herein, we assessed its capability to combat E. coli complicated urinary tract infections (cUTI) in mice driven by clinically important serine (CTX-M-15) and metallo-ß-lactamases (NDM-1). METHODS: Plasma and urine pharmacokinetics following IV administration of STM-001 (1-50 mg/kg) were determined in mice via LC-MS/MS. The effects on bacterial burden (kidney, bladder and urine) were determined in a 7 day mouse cUTI model whereby STM-001 was administered q12h or q24h at 2-100 mg/kg/day from Day 4. Efficacy was assessed by the change in log10 cfu/g or log10 cfu/mL from vehicle-treated infected mice. RESULTS: MICs of STM-001 for CTX-M-15 and NDM-1 E. coli were 8 and 16 mg/L, respectively. Blood pharmacokinetic profile was linear and dose-dependent with low clearance of 9.49 ±â€Š0.31 mL/min/kg, V = 0.63 ±â€Š0.02 L/kg and t½â€Š= 1.16 ±â€Š0.03 h. High STM-001 concentrations were recovered in urine 0-8 h post-administration, reaching up to 120-fold above its MIC. In cUTI efficacy studies, STM-001 (1-50 mg/kg, q12h) reduced CTX-M-15 burden by log10 4.31 (kidney), 3.95 (bladder) and 4.82 (urine) compared with vehicle-treated animals (P < 0.0001). STM-001 also reduced NDM-1 burden by log10 3.89 (kidney), 3.76 (bladder) and 3.08 (urine) (P < 0.0001), with similar inhibitory effects following q24h dosing. CONCLUSIONS: STM-001 was highly effective in reducing E. coli burden in kidney, bladder and urine in mouse cUTI models. The observed efficacy with either dosing regimen indicates potential low humanized doses of 1-5 mg/kg. These data support further development of STM-001 as an innovative, carbapenem-sparing antibiotic to combat human cUTIs.

In Vivo Targeting of Escherichia coli with Vancomycin-Arginine.

The ability of vancomycin-arginine (V-r) to extend the spectrum of activity of glycopeptides to Gram-negative bacteria was investigated. Its MIC towards Escherichia coli, including ß-lactamase expressing Ambler classes A, B, and D, was 8 to 16 µg/ml. Addition of 8 times the MIC of V-r to E. coli was acutely bactericidal and associated with a low frequency of resistance (<2.32 × 10-10). In vivo, V-r markedly reduced E. coli burden by >7 log10 CFU/g in a thigh muscle model. These data warrant further development of V-r in combatting E. coli, including resistant forms.

Detection of intact vancomycin-arginine as the active antibacterial conjugate in E. coli by whole-cell solid-state NMR.

The introduction of new and improved antibacterial agents based on facile synthetic modifications of existing antibiotics represents a promising strategy to deliver urgently needed antibacterial candidates to treat multi-drug resistant bacterial infections. Using this strategy, vancomycin was transformed into a highly active agent against antibiotic-resistant Gram-negative organisms in vitro and in vivo through the addition of a single arginine to yield vancomycin-arginine (V-R). Here, we report detection of the accumulation of V-R in E. coli by whole-cell solid-state NMR using 15N-labeled V-R. 15N CPMAS NMR revealed that the conjugate remained fully amidated without loss of arginine, demonstrating that intact V-R represents the active antibacterial agent. Furthermore, C{N}REDOR NMR in whole cells with all carbons at natural abundance 13C levels exhibited the sensitivity and selectivity to detect the directly bonded 13C-15N pairs of V-R within E. coli cells. Thus, we also present an effective methodology to directly detect and evaluate active drug agents and their accumulation within bacteria without the need for potentially perturbative cell lysis and analysis protocols.

The quest for secondary structure in chiral dendrimers.

This review highlights important developments in the pursuit of chiral conformational order in dendritic structures. To be able to create and control chiral secondary structure necessitates a thorough understanding of how chiral subunits influence the macroscopic structure. Recent studies involve highly sophisticated manipulation of macroscopic chirality through a creative combination of a wide range of synthetic, computational and analytical techniques.

Interplay between core and peripheral chirality in polyethers.

A chiral-base mediated reaction has been used to synthesise the polyethers illustrated and their enantiomers; CD spectroscopy revealed that the homochiral isomers A may be viewed as a C3-symmetric arrangement of fixed paddles while the heterochiral isomers B form a C3-symmetric arrangement of rotating paddles.