David Kuo scite author profile

Small-molecule antivirulence agents represent a promising alternative or adjuvant to antibiotics. These compounds disarm pathogens of disease-causing toxins without killing them, thereby diminishing survival pressure to develop resistance. Here we show that the small-molecule antivirulence agents F12 and F19 block staphylococcal transcription factor AgrA from binding to its promoter. Consequently, toxin expression is inhibited, thus preventing host cell damage by Gram-positive pathogens. Broad spectrum efficacy against Gram-positive pathogens is due to the existence of AgrA homologs in many Gram-positive bacteria. F12 is more efficacious in vitro and F19 works better in vivo. In a murine MRSA bacteremia/sepsis model, F19 treatment alone resulted in 100% survival while untreated animals had 70% mortality. Furthermore, F19 enhances antibiotic efficacy in vivo. Notably, in a murine MRSA wound infection model, combination of F19 with antibiotics resulted in bacterial load reduction. Thus, F19 could be used alone or in combination with antibiotics to prevent and treat infections of Gram-positive pathogens.

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Determination of the Kinetic Parameters of Escherichia coli Leader Peptidase Activity Using a Continuous Assay: The pH Dependence and Time-Dependent Inhibition by .beta.-Lactams Are Consistent with a Novel Serine Protease Mechanism

Kuo¹,

Weidner²,

Griffin³

et al. 1994

Biochemistry

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Bacterial leader peptidase (LPase) is a potential target for the development of novel anti-infective agents, but to data only peptides based upon natural macromolecular substrates have been reported as inhibitors. In this work is described a continuous assay for Escherichia coli LPase activity, based upon Ac-WSASALAKI-AMC (I) as the substrate, that can be monitored either spectrophotometrically or spectrofluorometrically. The LPase reaction is coupled to the liberation of AMC (aminomethylcoumarin) via a nonspecific leucine aminopeptidase. LPase and a short form of the enzyme (LPase-sf) lacking the membrane spanning domains displayed saturable kinetics toward I. The second-order rate constants were approximately 2 x 10(5) M-1 h-1 at pH 7.5 and were comparable to those reported in the literature for peptide substrates based upon natural cleavage sites in preproteins. LPase was inhibited by beta-lactams. [S-(R*,S*)]-4-[(1-(((1-(5-toluoyl)butyl)amino)carbonyl)-3,3-dimethyl-4- oxo-2-azetidinyl)oxyl]benzoic acid (L-684,-248, 588 microM) inhibited the LPase-catalyzed hydrolysis of 50 microM I and 125 microM Ac-WLVP-Nleu-LSFAAEGDDPA-NH2 by 30% and 88% over 1 and 4 h, respectively. The inhibition of LPase by L-684,248 and its C-4 diasteromer was time dependent and yielded second-order rate constants (kinact/Ki) of 12 and 7.7 M-1 min-1, respectively. The process was structurally specific as the C-3 diethyl substituted beta-lactam (C-4 S-isomer) was inactive. The latter data correlate with the LPase preference for alanine at the P1 position of peptide substrates [Kuo et al. (1993) Arch. Biochem. Biophys. 303, 274-280].(ABSTRACT TRUNCATED AT 250 WORDS)

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Novel Quorum-Quenching Agents Promote Methicillin-Resistant Staphylococcus aureus (MRSA) Wound Healing and Sensitize MRSA to β-Lactam Antibiotics

Kuo

Hoch

et al. 2015

Antimicrob Agents Chemother

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The dwindling repertoire of antibiotics to treat methicillin-resistant Staphylococcus aureus (MRSA) calls for novel treatment options. Quorum-quenching agents offer an alternative or an adjuvant to antibiotic therapy. Three biaryl hydroxyketone compounds discovered previously (F1, F12, and F19; G. Yu, D. Kuo, M. Shoham, and R. Viswanathan, ACS Comb Sci 16:85-91, 2014) were tested for efficacy in MRSA-infected animal models. Topical therapy of compounds F1 and F12 in a MRSA murine wound infection model promotes wound healing compared to the untreated control. Compounds F1, F12, and F19 afford significant survival benefits in a MRSA insect larva model. Combination therapy of these quorum-quenching agents with cephalothin or nafcillin, antibiotics to which MRSA is resistant in monotherapy, revealed additional survival benefits. The quorum-quenching agents sensitize MRSA to the antibiotic by a synergistic mode of action that also is observed in vitro. An adjuvant of 1 g/ml F1, F12, or F19 reduces the MIC of nafcillin and cephalothin about 50-fold to values comparable to those for vancomycin, the antibiotic often prescribed for MRSA infections. These findings suggest that it is possible to resurrect obsolete antibiotic therapies in combination with these novel quorum-quenching agents. Methicillin-resistant Staphylococcus aureus (MRSA) is a widespread bacterial pathogen, causing various infections, ranging from skin and soft tissue infections to serious invasive infections, such as pneumonia, endocarditis, bacteremia, and sepsis (1, 2). Rising antibiotic resistance and diminishing investment by the pharmaceutical industry in the development of new antibiotics have created an urgent need for novel anti-MRSA agents (3). Quorum-quenching agents provide an alternative and an adjuvant to conventional antibiotic therapy (4, 5). The mechanism of action of quorum-quenching agents is fundamentally different from that for antibiotics. Quorum-quenching agents are neither bactericidal nor bacteriostatic. They inhibit the production of disease-causing toxins by the pathogen, thereby disarming the pathogen of its capacity to inactivate host defense factors. An intact host immune system has a better chance to clear a bacterial infection. A quorum-quenching agent tips the balance of bacterial virulence factors and host defense factors in favor of the host.Virulence factor production in Staphylococcus aureus is regulated by a quorum-sensing mechanism predominantly under the control of the agr operon (6, 7). In previous work, we have identified small-molecule biaryl hydroxyketone compounds that target the response regulator AgrA and inhibit its interaction with promoter P3, curtailing the production of toxins and virulence factors (8). In a follow-up study, a combinatorial library of 148 compounds was synthesized based on the most efficacious hit compound (9). A member of this biaryl hydroxyketone library, named F12, was the most efficacious of the synthesized compounds, demonstrating 98% in vitro MRSA rabbit erythrocyte hemolysis inhi...

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David Kuo

Escherichia coli Leader Peptidase: Production of an Active Form Lacking a Requirement for Detergent and Development of Peptide Substrates

Small-molecule AgrA inhibitors F12 and F19 act as antivirulence agents against Gram-positive pathogens

Determination of the Kinetic Parameters of Escherichia coli Leader Peptidase Activity Using a Continuous Assay: The pH Dependence and Time-Dependent Inhibition by .beta.-Lactams Are Consistent with a Novel Serine Protease Mechanism

Novel Quorum-Quenching Agents Promote Methicillin-Resistant Staphylococcus aureus (MRSA) Wound Healing and Sensitize MRSA to β-Lactam Antibiotics

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