This is a normal tendency of biofilm-forming bacteria such as myc

This is a normal tendency of biofilm-forming bacteria such as mycobacteria. On treatment with alcohol, most of the bacteria lose their cell shape and morphology and as a consequence remain unattached and occur mostly as single cells. Thus, the growth inhibitory activity of decanol can be attributed partly, if not exclusively, to its ability to damage the cellular envelope. Perhaps INCB024360 research buy this damage is a result of the well-known event of accumulation of alkanols in the membrane thus affecting the general membrane functions. Biofilm formation in many cases is important for bacterial virulence and survival (Parsek & Singh, 2003). So a successful attenuation of biofilm formation can be of wide interest for

the management of disease progression and elimination of the pathogen. An intact cellular envelope and its hydrophobicity helps in cell to cell adhesion and thus promotes biofilm formation in microorganisms such as mycobacteria. Thus, any damage to the cell envelope may hinder its ability to adhere to each other and subsequently inhibits biofilm formation. In this context we have assessed the TSA HDAC datasheet ability of long-chain fatty alcohols in biofilm formation

by performing CV assay and acridine orange staining of the biofilm. Interestingly, our result showed that decanol concentrations of 0.1 and 0.2 mM, far lower than its MIC (0.4 mM), were able to attenuate biofilm formation (Fig. 3a). Furthermore, the quantitative CV assay also revealed that 9-decene-1-ol concentrations of 0.05 and 0.1 mM, again lower than its MIC (0.2 mM), were able to attenuate biofilm formation considerably (Fig. 3b). The same concentration of the alcohols tested had

no effect on planktonic growth as measured by OD600 nm. These results clearly suggest that a sublethal dose of both 1-decanol and 9-decene-1-ol is able to attenuate biofilm formation in vitro. This inhibition may result from the ability of these agents to damage the cellular envelope and thus in turn perturb the cell to cell adhesion, which from is a key factor in biofilm formation. Exploring new agents that can attenuate biofilm formation and insight into the mechanism involved may shed light into therapeutic strategies for infections with microbes such as mycobacteria whose pathogenic potential strongly depends on successful biofilm formation within the host. Surface active agents such as surfactants and other membrane-damaging compounds are drawing significant attention in the field of antimicrobial chemotherapy. Drugs such as daptomycin clofazimine derivatives that are known to disrupt membrane integrity are already being used either clinically or are at the final stage of drug development (Adams et al., 1999; Pogliano et al., 2012). Membrane active agents generally have multiple target sites and diverse modes of action against the organism, reducing the chance of mutation at the target site (Andries et al., 2005; Koul et al., 2008).

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