Anti-infective potential of plant-derived quorum sensing inhibitors against multi-drug resistant human and aquatic bacterial pathogens.

The present study intended to decipher the anti-infective potential of bioactive phytocompounds, such as rosmarinic acid, morin, naringin, chlorogenic acid, and mangiferin, against aquatic and human bacterial pathogens using Artemia spp. nauplii and Caenorhabditis elegans as animal models, respectively. Initially, the test compounds were screened against the QS traits in Vibrio spp., such as bioluminescence production and biofilm formation. The test compounds effectively inhibited the bioluminescence in V. harveyi. Further, the confocal laser scanning microscopic analysis revealed that these natural compounds could efficiently reduce the clumping morphology, a characteristic biofilm formation in Vibrio spp., without inhibiting bacterial growth. The results of in vivo analysis showed a significant increase in the survival of Artemia spp. nauplii infected with Vibrio spp. upon exposure to these compounds. Moreover, the compounds used in this study were already proven and reported for their quorum sensing inhibitory efficacy against Pseudomonas aeruginosa. Hence, the anti-infective efficacy of these compounds against P. aeruginosa (PAO1) and its clinical isolates (AS1 and AS2) was studied using C. elegans as a live animal model system. The results of time-killing assay deciphered that rosmarinic acid and naringin are being the most effective ones in rescuing the animals from P. aeruginosa infection followed by morin, mangiferin, and chlorogenic acid. Further, the toxicity results revealed that these compounds did not show any lethal effect on C. elegans and Artemia spp. nauplii at the tested concentrations. In conclusion, the phytochemicals used in this study were effective in controlling the QS-regulated virulence traits in Vibrio spp. and P. aeruginosa infections in Artemia spp. nauplii and C. elegans animal model systems, respectively.

Proteome analysis reveals translational inhibition of Caenorhabditis elegans enhances susceptibility to Pseudomonas aeruginosa PAO1 pathogenesis.

UNLABELLED: Caenorhabditis elegans-Pseudomonas aeruginosa infection model is commonly used for pathogenesis studies over the decades. In the present study, upon exposure to the Pseudomonas aeruginosa PAO1, the 2D-PAGE was performed to examine the total proteins differences of C. elegans during the PAO1 infection at different time durations (12-48h). Also, the 2D-DIGE using the cyanine dyes were performed (48h) to identify the differentially regulated proteins against the PAO1 infection. Among the 19 short-listed proteins, 5 proteins were down-regulated and 14 proteins were up-regulated. Eukaryotic elongation factor-2 (EEF-2), a GTP binding protein involves in protein elongation process was down regulated during the pathogen infection. The 2D-PAGE analysis and MS data for the 12 and 24h infections identified the NDK-1 and other essential protein includes, ACS-18, ACT-1, GPD-3, GDH-1 and LBP-6 which are involved in important cellular homeostasis were down regulated. Validation studies using qPCR analysis for eef-2 and other selected genes, western blot analysis for EEF-2 and effect of host translational inhibition studies using Cycloheximide during PAO1 infection suggests that P. aeruginosa systematically restrains the function of host by arresting the expression of EEF-2 and thereby inhibiting protein translational events. Further, in silico analysis revealed the Exotoxin A could directly bind with the host EEF-2 and NDK-1 during the C. elegans- PAO1 interactions. BIOLOGICAL SIGNIFICANCE: Model system, C. elegans facilitates the identification of virulence mechanisms during bacterial pathogenesis. Upon infection by the fungal and bacterial pathogens, the C. elegans system induces an array of transcriptional responses, including differential expression of effector/modulator genes that provide safeguard and fight against infection. However, the in-depth knowledge of host response by the pathogen at protein level remains unclear. Much of the studies were carried out only at the transcripts level and scarce reports are available at the protein level for the host-pathogen interaction studies. In order to provide few interesting clues at the protein level, the nematode, C. elegans was infected with the human pathogen P. aeruginosa and the response(s) of host was investigated at the protein level by 2D-DIGE analysis and further validation studies using qPCR and western blotting techniques. Our differential proteomics data suggest that translational inhibition as one of the patterns of pathogenesis in C. elegans during P. aeruginosa infection. Since many of the effectors identified through C. elegans are conserved in other systems including human, our data pave the way for understanding important regulatory pathways involved during bacterial pathogenesis that can be translated into higher eukaryotic organisms.