aeruginosa PAO1 mutant strain unable to produce the type III secretion system effector gene pcrV Compound C purchase (strain PW4017). Our results suggest that AZM-pretreated P. aeruginosa could indirectly exacerbate pro-inflammation by inducing IL-8 production in HBEs. “
“PyrH is a member of the UMP kinase family that catalyses the conversion of UMP to UDP, an essential step in the pyrimidine metabolic pathway in a variety of bacteria including those causing community-acquired respiratory tract
infections (RTIs). In this study, we have developed a luminescence-based kinase assay of PyrH and evaluated the inhibitory activity of PYRH-1 (sodium 3-[4-tert-butyl-3-(9H-xanthen-9-ylacetylamino)phenyl]-1-cyclohexylmethylpropoxycarbonyloxyacetate).
PYRH-1 inhibits PyrH derived from both Streptococcus pneumoniae and Haemophilus influenzae with IC50 (concentration of inhibitor giving a 50% decrease in enzyme activity) values of 48 and 75 μM, respectively, whose inhibitory activity against S. pneumoniae PyrH was far higher compared with that of UTP (IC50 = 710 μM), an allosteric PyrH inhibitor. The molecular interaction Depsipeptide mouse analysis by surface plasmon resonance suggested that PYRH-1 directly interacts with S. pneumoniae PyrH at one-to-one molar ratio. Finally, PYRH-1 was shown to have antimicrobial activity against several different bacteria causing RTIs, such as S. pneumoniae,Staphylococcus aureus,H. influenzae (acrA knockout strain), suggesting that PYRH-1 is a prototype chemical compound that can be harnessed as an antimicrobial drug with a novel mode of action by targeting bacterial PyrH. Although numerous antibiotics for community-acquired bacterial respiratory tract infection (RTIs) have been
discovered, thus far, most of them target the same or functionally similar molecules that are essential for bacterial growth. Because emerging antibiotic-resistant bacteria, such as multidrug-resistant Streptococcus pneumoniae and β-lactamase-negative and ampicillin-resistant Haemophilus influenzae (BLNAR), are posing threats, especially to immunocompromised patients, there is an unmet medical need to provide antibiotics with OSBPL9 novel modes of action for reducing infections associated with such bacteria. Recent progress in the genome projects (Fleischmann et al., 1995; Hoskins et al., 2001; Kuroda et al., 2001) has decoded the genome structure of a variety of organisms such as S. pneumoniae, Staphylococcus aureus and H. influenzae, thereby creating opportunities to design molecular targeting strategies for discovering agents that specifically attack pathogens. In fact, a number of studies in pharmaceutical companies and academia have developed screening platforms based on enzymatic assay and structure-based drug design.