Antibacterial and antibiofilm activities of diphyllin against fish pathogens.

Annihilation of biofilm forming bacterial pathogens is a challenging aspect in seafood and aquaculture industries. Microbes growing as biofilms cause deleterious effects on food products leading to food spoilage or loss of shelf life. As a measure to fight biofilms, agents that prevent/disrupt biofilms are recurrently screened. The study exemplifies the bactericidal and biofilm disruption potentials of a plant derived compound, diphyllin, against fish pathogens that colonizes Oreochromis mossambicus and Oreochromis niloticus. Precisely, diphyllin disrupted Salmonella typhi biofilms by triggering reactive oxidative species (ROS). Diphyllin-induced ROS had satisfactory correlation with S. typhi cell membrane damage and intracellular DNA degradation profiles providing a putative mechanistic model. In conclusion, the study identifies diphyllin as a therapeutic and dispersal agent aimed at biofilms formed by food-borne pathogens that persistently plague food processing and aquaculture settings.

Molecular docking and biological evaluation of novel urea-tailed mannich base against Pseudomonas aeruginosa.

Emergence of multi-drug resistant bacterial pathogens is escalating and it is essential to develop novel strategies to combat these super bugs. LasR is a regulator switch that plays a vital role in quorum sensing (QS) and pathogenesis of Pseudomonas aeruginosa. The present study reports two novel Mannich base (1-(phenyl (o-tolylamino) methyl) urea and 3-((1H-Imidazole-1-yl) methylnaphthalene-2-ol with enhanced anti-QS and antibiofilm activities. Synthetic compound revealed prolific interaction patterns with LasR quorum sensing receptor and showed to exhibit LasR antagonistic activities in P. aeruginosa. In-vitro LasR-inhibitory activities were further confirmed by biofilm and pyocyanin inhibition assays which showed a dose-dependent activity. The Mannich base also repressed the mRNA transcripts levels of lasA and lasB genes, confirming its active role in LasR inhibitory activity. Importantly, C1 and C2 played a crucial role in antagonizing LasR receptor by forming H-bonds with Tyr47 in the LasR active site and the presence of urea moiety on one of the Mannich base was a discrete advantage. Taken together, the insilico and invitro assays revealed similar evidences, thus confirming the mode of action of the Mannich bases. Overall the findings will assist in drug designing and for developing newer drugs with Mannich bases and its derivatives for treatment of P. aeruginosa.

Mannich base limits Candida albicans virulence by inactivating Ras-cAMP-PKA pathway.

Mannich bases and its derivatives are regarded as supreme pharmacophores in therapeutics. The study investigates the antimycotic potential of Mannich bases, 1-((1H-benzimidazol-1-yl) methyl) urea (C1) and 1-((3-hydroxynapthalen-2-yl) methyl) thiourea (C2), against Candida albicans. Biofilm and hyphal inhibitory activities of the Mannich bases were tested by crystal violet quantification, fluorescence imaging cAMP rescue, qRT PCR, and by molecular docking analysis. The compounds inhibited the biofilms of C. albicans and restrained the filamentation abilities of the pathogen. Structure-activity relationship studies revealed that the presence of urea or thiourea moiety in the tail section is essential for interacting with adenylate cyclase (AC). The Mannich bases seemed to block Ras-cAMP-PKA pathway by inhibiting second messenger activity required for hyphal induction and biofilm formation. In conclusion, the study warrants point-of-care testing of C1/C2 and provides a starting point for deriving several structurally modified Mannich bases which might plausibly replace the prevailing antimycotic drugs in future.

Burdock root extracts limit quorum-sensing-controlled phenotypes and biofilm architecture in major urinary tract pathogens.

Bacterial biofilms are serious concern in patients infected with urinary tract infections, complicated urinary tract infections and other device-associated infections. Microbes within the biofilms are effectively shielded from antibiotics and host immune cells, hence can be treated only with agents which has the potential to disassemble the biofilms. The study is focused on the root extracts of Arctium lappa Linn. as a source for complementary medicine against three major biofilm forming clinical isolates of Escherichia coli, Proteus mirabilis, and Serratia marcescens. Methanol extracts of burdock roots (BR) showed no bactericidal activity (p > 0.05) against the uropathogens, whereas restrained the biofilms (p < 0.05) on polystyrene and glass surfaces at a biofilm inhibitory concentration of 100 µg/mL. The 3D confocal laser scanning microscopy was used to analyze the biofilm architecture which showed significant reduction in the surface area. Z-stack analysis has also revealed substantial reduction in the biofilm thickness (E. coli-50.79%, P. mirabilis-69.49%, and S. marcescens-75.84%). Further, BR extracts also inhibited quorum-sensing (QS)-controlled cellular phenotypes such as violacein, prodigiosin, swarming motility, and cell surface hydrophobicity. LC-MS/MS analysis of BR extracts identified the presence of two major quercetin derivatives (miquelianin and peltatoside) along with few other constituent components. Exploring such phytocompounds will provide potential agents to treat infections caused by biofilm forming uropathogens. The antibiofilm and anti-QS agents will ultimately serve as armor, facilitating the host immune system to fight infections.