In all known cases, in normally growing cells, toxins form a stable complex with their cognate antitoxins that blocks the toxin activity. Antitoxin also functions as a repressor for individual TA operons (Gerdes et al., 2005). Under stress conditions, intrinsically unstable antitoxin is lost from the cells, releasing toxin freely and inhibiting various essential cellular functions, such as DNA replication, mRNA stability, protein synthesis, and cell division (Jiang
et al., 2002; Zhang et al., 2003; Tan et al., Venetoclax ic50 2011; Zhang & Inouye, 2011). This leads to a reversible cell growth arrest, which is implicated in the persister phenotype. The TA system is also shown to be associated with pathogenicity, programmed cell death, and biofilm formation (Pandey & Gerdes, 2005; Nariya & Inouye, 2008; Wang & Wood, 2011). Escherichia coli have two essential bacterial cytoskeletal proteins, FtsZ and MreB. FtsZ is a highly conserved GTPase and is homologous to eukaryotic cytoskeleton protein, tubulin (Mukherjee et al., 1998). It forms a ring structure at the mid-cell and functions as a scaffold for divisome, a multiprotein
complex responsible for cell division. MreB is an actin-like ATPase, essential for maintaining the typical rod shape and cell polarity in E. coli (Osborn & Rothfield, 2007). MreB is also implicated in chromosome segregation, localization of membranous organelles, and coordinating cell division with cell biosynthesis (Kruse et al., 2005; Komeili et al., 2006; Madabhushi & Marians, 2009; Domínguez-Escobar et al., 2011; selleck chemical ADP ribosylation factor Garner et al., 2011). Because both FtsZ and MreB are involved in a number of essential cellular functions, the inhibition of their functions is detrimental to the cells. For example, the inhibition of FtsZ polymerization by SulA or MinCD results in blocking the septum formation, causing the formation of filamentous cells (Mukherjee et al., 1998; Pichoff & Lutkenhaus, 2001). The inhibition of MreB by A22 [S-(3,4-dichlorobenzyl) isothiourea] leads to the loss of its rod shape and eventual cell lysis (Karczmarek et al.,
2007; Bean et al., 2009). Here, we have identified a novel TA system in E. coli genome using RASTA (Sevin & Barloy-Hubler, 2007). The putative toxin, YgfX, inhibits the cell growth and causes significant changes in the cellular morphology of E. coli. Upon induction of YgfX, the cells were first elongated and then subsequently became inflated in the middle. The YgfX toxicity was neutralized by the co-expression of YgfY, indicating that YgfY is an antitoxin of YgfX. YgfX is the first toxin of E. coli TA systems shown to be associated with membrane. We further demonstrated that YgfX physically interacts with FtsZ and MreB and inhibits their polymerization in vitro and that the C-terminal soluble domain of the YgfX is responsible for the inhibition.