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Pseudomonas aeruginosa easily adapts to newer environments and acquires several genome flexibilities to overcome the effect of antibiotics during therapeutics, especially in cystic fibrosis patients. During adaptation to the host system, the bacteria employ various tactics including virulence factor production and biofilm formation to escape from the host immune system and resist antibiotics. Hence, identifying alternative strategies to combat recalcitrant pathogens is imperative for the successful elimination of drug-resistant microbes. In this context, this study portrays the anti-virulence efficacy of umbelliferone (UMB) against P. aeruginosa . UMB (7-hydroxy coumarin) is pervasively found among the plant family of Umbelliferae and Asteraceae . The UMB impeded biofilm formation in the P. aeruginosa reference strain and clinical isolates on polystyrene and glass surfaces at the concentration of 125 µg/ml. Global proteomic analysis of UMB-treated cells revealed the downregulation of major virulence-associated proteins such as RhlR, LasA, AlgL, FliD, Tpx, HtpG, KatA, FusA1, Tsf, PhzM, PhzB2, CarB, DctP, MtnA, and MscL. A functional interaction study, gene ontology, and KEGG pathway analysis revealed that UMB could modulate the global regulators, enzymes, co-factors, and transcription factors related to quorum sensing (QS), stress tolerance, siderophore production, motility, and microcolony formation. In vitro biochemical assays further affirmed the anti-virulence efficacy of UMB by reducing pyocyanin, protease, elastase, and catalase production in various strains of P. aeruginosa . Besides the antibiofilm activity, UMB-treated cells exhibited enhanced antibiotic susceptibility to various antibiotics including amikacin, kanamycin, tobramycin, ciprofloxacin, and cefotaxime. Furthermore, in vitro cytotoxicity analysis revealed the biocompatibility of UMB, and the IC 50 value was determined to be 249.85 µg/ml on the HepG2 cell line. Altogether, the study substantiates the anti-virulence efficacy of UMB against P. aeruginosa , and the proteomic analysis reveals the differential expression of the regulators related to QS, stress response, and motility factors.

Background Bacteriophages are the most genetically diverse biological entities in nature. Our current understanding of phage biology primarily stems from studies on a limited number of model bacteriophages. Jumbo phages, characterized by their exceptionally large genomes, are less frequently isolated and studied. Some jumbo phages exhibit remarkable genetic diversity, unique infection mechanisms, and therapeutic potential. Methods In this study, we describe the isolation of Sharanji, a novel Escherichia coli jumbo phage, isolated from chicken feces. The phage genome was sequenced and analyzed extensively through gene annotation and phylogenetic analysis. The jumbo phage was phenotypically characterized through electron microscopy, host range analysis, and survival at different pH and temperatures, and one-step growth curve assay. Finally, Sharanji mediated infection of E. coli is studied through fluorescence microscopy, to analyze its mechanism of infection compared to well-studied nucleus-forming jumbo phages. Results Whole genome sequencing reveals that Sharanji has a genome size of 350,079 bp and is a phage encompassing 593 ORFs. Genomic analysis indicates that the phage belongs to the Asteriusvirus genus and is related to E. coli jumbo phages PBECO4 and 121Q. Phenotypic analysis of isolated phage Sharanji, indicates that the phage size is 245.3 nm, and it is a narrow-spectrum phage infecting E. coli K12 strains, but not other bacteria including avian pathogenic E. coli . Infection analysis using microscopy shows that Sharanji infection causes cell filamentation. Furthermore, intracellular phage nucleus-like structures were not observed in Sharanji-infected cells, in contrast to infection by ΦKZ-like jumbo phages. Conclusions Our study reports the isolation and characterization of Sharanji, one of the large E. coli jumbo phages. Both genotypic and phenotypic analyses suggest that Sharanji serves as a unique model system for studying phage-bacteria interactions, particularly within the context of non-nucleus-forming jumbo phages. Further exploration of jumbo phages holds promise for uncovering new paradigms in the study of microbial viruses.