Heptameric YggB is a mechanosensitive ion channel (MscS) from the inner membrane of Escherichia coli. We demonstrate, using the patch clamp technique, that cross-linking of the YggB C termini led to irreversible inhibition of the channel activities. Application of Ni 2؉ to the YggB-His 6 channels with the hexahistidine tags added to the ends of their C termini also resulted in a marked but reversible decrease of activities. Western blot revealed that YggB-His 6 oligomers are more stable in the presence of Ni 2؉ , providing evidence that Ni 2؉ is coordinated between C termini from different subunits of the channel. Intersubunit coordination of Ni 2؉ affecting channel activities occurred in the channel closed conformation and not in the open state. This may suggest that the C termini move apart upon channel opening and are involved in the channel activation. We propose that the as yet undefined C-terminal region may form a cytoplasmic gate of the channel. The results are discussed and interpreted based on the recently released quaternary structure of the channel.
Mechanosensitive (MS)1 ion channels open upon membrane tension, and therefore they represent the simplest mechanosensors. MS channels have been implicated in many physiological processes from growth and cell volume regulation to hearing, blood pressure regulation, and pain sensation (reviewed in Ref. 1). Bacterial MS channels protect these cells against hypoosmotic shock. Two types of MS channels from the cytoplasmic membrane of Escherichia coli, MscL and MscS, play an essential role in the physiology of this bacterium, allowing the efflux of solutes from the cytoplasm when osmolarity of the external medium decreases (2-4). MscL, the large conductance MS channel, has been cloned (5), and a quaternary structure of its closed conformation has been determined (6). Based on this structure and the analysis of the channel gating, the open conformation has been predicted (7, 8) and experimentally confirmed (9, 10). Functional homologues of this channel have been found in other bacteria (11) and Archea (12), and structurally related protein from Neurospora has been also reported (13). The functional channel is a pentamer, and each subunit consists of two ␣-helical membrane-spanning domains TM1 and TM2 with both the C and N termini located in the cytoplasm (6). TM1s line the pore, and their hydrophobic residues form the primary, transmembrane gate (6, 14). It is postulated that there are two gates involved in the opening of the channel: the transmembrane and the cytoplasmic gates (7, 8) acting in accordance (15). The transmembrane gate is proposed to act as a pressure sensor, and upon application of pressure, this gate permits initial expansion of the channel without its full opening (7,8,10). It is proposed that the other, cytoplasmic gate, which allows full activation of the channel, is composed of five ␣-helical S1 segments of the cytoplasmic N termini being connected with TM1s via flexible linkers. According to the model, the applied pressure is transmitted to...
