Antibacterial activity of alkyl gallates is a combination of direct targeting of FtsZ and permeabilization of bacterial membranes.

Ewa Król,Henrique Ferreira,Anabela De Sousa Borges,Isabel Da Silva,Dirk-Jan Scheffers,Carlos R Polaquini,Luis O Regasini

doi:10.3389/fmicb.2015.00390

Ewa Król, Henrique Ferreira + Show 5 more

Open Access

https://doi.org/10.3389/fmicb.2015.00390

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Abstract

Alkyl gallates are compounds with reported antibacterial activity. One of the modes of action is binding of the alkyl gallates to the bacterial membrane and interference with membrane integrity. However, alkyl gallates also cause cell elongation and disruption of cell division in the important plant pathogen Xanthomonas citri subsp. citri, suggesting that cell division proteins may be targeted by alkyl gallates. Here, we use Bacillus subtilis and purified B. subtilis FtsZ to demonstrate that FtsZ is a direct target of alkyl gallates. Alkyl gallates disrupt the FtsZ-ring in vivo, and cause cell elongation. In vitro, alkyl gallates bind with high affinity to FtsZ, causing it to cluster and lose its capacity to polymerize. The activities of a homologous series of alkyl gallates with alkyl side chain lengths ranging from five to eight carbons (C5–C8) were compared and heptyl gallate was found to be the most potent FtsZ inhibitor. Next to the direct effect on FtsZ, alkyl gallates also target B. subtilis membrane integrity—however the observed anti-FtsZ activity is not a secondary effect of the disruption of membrane integrity. We propose that both modes of action, membrane disruption and anti-FtsZ activity, contribute to the antibacterial activity of the alkyl gallates. We propose that heptyl gallate is a promising hit for the further development of antibacterials that specifically target FtsZ.

Highlights

The use of plants as sources of antimicrobial agents has a long history (Abreu et al, 2012)
Alkyl Gallates with Carbon Side Chain Length C5–C8 Inhibit B. subtilis Growth Recently, we showed that pentyl, hexyl, heptyl, and octyl gallates disrupt cell division in Xac
Our initial studies indicated that the alkyl gallates disrupt cell division in Xac, possibly by targeting the FtsZ-ring, which is different from the observed mechanism of membrane binding that is described for these compounds (Takai et al, 2011)

Summary

Introduction

The use of plants as sources of antimicrobial agents has a long history (Abreu et al, 2012). Octyl gallate has been reported to exhibit bactericidal activity only against dividing and exponentially growing cells of B. subtilis but did not affect the viability of cells in the stationary phase (Kubo et al, 2004). Taken together, these results indicate that alkyl gallates may affect functions associated with cell division in Gram-positive and Gram-negative bacteria (Kubo et al, 2004; Silva et al, 2013)

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