Antiadhesive hydroalcoholic extract from Apium graveolens fruits prevents bladder and kidney infection against uropathogenic E. coli.

Fruits from Apium graveolens (Celery) are used traditionally in Persian and European medicine for the treatment of uncomplicated urinary tract infections. No data are available on A. graveolens extract on the interplay between uropathogenic E. coli and the eukaryotic host cells and on quorum sensing of the bacteria. The present study aimed to characterize an antiadhesive and anti quorum sensing effect of a characterized A. graveolens extract by specific in vitro assays and to correlate these effects with in vivo data obtained by an animal infection model. Hydroalcoholic extract CSE (EtOH-water, 1:1) from A. graveolens fruits was characterized by UHPLC/+ESI-QTOF-MS and investigated on antiproliferative activity against UPEC (strain NU14) and human T24 bladder cells. Antiadhesive properties of CSE were investigated within two different in vitro adhesion assays. For in vivo studies BALB/c mice were used in an UPEC infection model. The effect of CSE on bacterial load in bladder tissue was monitored within a 4- and 7 days pretreatment (200, 500 mg/kg) of the animals. CSE was dominated by the presence of luteolin-glycosides and related flavons besides furocoumarins. CSE had no cytotoxic effects against UPEC and bladder cells. CSE exerts a dose dependent antiadhesive activity against UPEC strains NU14 and UTI89. CSE inhibited in a concentration-dependent manner bacterial quorum sensing. 4- and 7-day pretreatment of animals with CSE transurethrally infected with UPEC NU14, significantly reduced the bacterial load in bladder tissue. CSE is assessed as an antiadhesive extract for which the traditional use in phytotherapy for UTI is justified.

Aqueous extract from Orthosiphon stamineus leaves prevents bladder and kidney infection in mice.

BACKGROUND: Extracts from the leaves of Orthosiphon stamineus are used in phytotherapy for treatment of uncomplicated urinary tract infections. PURPOSES: Evaluation of an aqueous extract against infection with uropathogenic Escherichia coli in vivo; investigation of underlying microbiological mechanisms. STUDY DESIGN: In vivo studies in mice and in vitro investigations on cytotoxicity, antiadhesive potential, influence on bacterial gene expression and quorum sensing. METHODS: Extract OWE was prepared by hot water extraction. For in vivo studies BALB/c mice were used in an UPEC infection model. The effect of OWE on bacterial load in bladder/kidney tissue was monitored in pre- and posttreatment. Cytotoxicity of OWE against different UPEC strains, T24 bladder/A498 kidney cells, gene expression analysis, monitoring of phenotypic motility and quorum sensing was investigated by standard methods of microbiology. RESULTS: OWE was quantified (UHPLC) according to the content of rosmarinic acid, cichoric acid, caffeic acid. Three- and 5-day treatment of animals with OWE (750mg/kg) after transurethral infection with UPEC CFT073 reduced the bacterial load in bladder and kidney, similar to norfloxacin. Four- and 7-day pretreatment of mice prior to the infection with UPEC NU14 reduced bacterial bladder colonization. In vitro investigations indicated that OWE (≤2mg/ml) has no cytotoxic or proliferation-inhibiting activity against different UPEC strains as well as against T24 bladder and A498 kidney cells. OWE exerts a dose dependent antiadhesive activity against UPEC strains NU14 and UTI89. OWE reduced gene expression of fimH, but evoked increase of the expression of motility/fitness gene fliC. Increase of bacterial motility on gene level was confirmed by a changed bacterial phenotype by an increased bacterial motility in soft agar assay. OWE inhibited in a concentration-dependent manner bacterial quorum sensing. CONCLUSION: OWE is assessed as a strong antiadhesive plant extract for which the traditional use in phytotherapy for UTI might be justified.

2,4,5-Trisubstituted imidazoles: novel nontoxic modulators of P-glycoprotein mediated multidrug resistance. Part 1.

N-4,5-Di-(4-dialkylamino)phenyl imidazoles (A) are potent modulators of P-glycoprotein mediated multidrug resistance. This manuscript describes the discovery and lead optimization of this novel class of inhibitors.

2,4,5-Trisubstituted imidazoles: novel nontoxic modulators of P-glycoprotein mediated multidrug resistance. Part 2.

Solution-phase combinatorial chemistry was applied to the optimization and development of clinical candidate OC144-093 (22), a novel and nontoxic modulator of P-glycoprotein mediated multidrug resistance.