The absence of PtsN, the terminal phosphoacceptor of the phosphotransferase system comprising PtsP-PtsO-PtsN, in Escherichia coli confers a potassium-sensitive ( ) of 200 to 400 mM that is thought to be required for optimal functioning of several metabolic processes (reviewed in references 1 and 2). In addition, K ϩ is a major determinant in the maintenance of cell turgor, so that an increase in osmolarity of the medium is associated with increased [K ϩ ] i (3-6). K ϩ has also been proposed to act as a second messenger (2, 7).The maintenance of cytoplasmic K ϩ pools in E. coli is achieved through the balance of activities of K ϩ uptake systems Kdp, Trk, and Kup (formerly known as TrkD) on the one hand and of an as yet unidentified K ϩ efflux system or systems on the other (1, 2). The well-studied K ϩ efflux systems KefG/B and KefF/C are known to act as K ϩ /H ϩ antiporters, with K ϩ efflux and concomitant H ϩ influx leading to cytoplasmic acidification, serving to mitigate the detrimental effects of endogenous or exogenous electrophiles (reviewed in reference 8). A residual K ϩ transport activity, TrkF, present in a kdp kup trk triple K ϩ transporter-defective mutant is thought to represent a mode of K ϩ uptake occurring through systems that do not normally transport K ϩ (9), and an as yet uncharacterized turgor-activated efflux system is also believed to exist (10).The Kdp transporter, encoded by genes of the kdpFABC operon, is a high-affinity K ϩ uptake system (11, 12) that is transcriptionally induced when the external K ϩ concentration ([K ϩ ] e ) becomes limiting for growth (13,14). More recent studies have shown that expression and/or activity of the Kdp transporter is also inhibited by [K ϩ ] e s above 5 mM (15, 16). The Trk and Kup systems, in contrast, are low-affinity K ϩ uptake systems that are constitutively expressed (1, 2). Of these systems, Kup is a standalone K ϩ transporter, whereas the Trk system is a multicomponent system, and a null mutation in trkA, coding for the regulatory subunit, disables the Trk system (2). The presence of multiple transport systems for K ϩ allow, within the limits of its osmoregulatory capacity, robust growth of E. coli in media with a wide range of [K ϩ ] e s. In E. coli, components of the phosphotransferase system (PTS) mediate uptake of carbohydrates, wherein transport of the incoming sugar is coupled to its phosphorylation (reviewed in references 17, 18, 19, and 20). In each of these systems, a phosphate moiety is transferred from phosphoenolpyruvate (PEP) to the particular sugar via a multiprotein phosphorelay mechanism. E. coli also possesses a PTS comprising PtsP-PtsO-PtsN, with a PEP-dependent phosphorelay operating in the same sequence (21-23). However, the phosphorylation substrate of PtsN is unknown. Given that ptsN and ptsO are member genes of the rpoN operon (21), PtsP, PtsO, and PtsN have also been referred to as EI Ntr , Npr, and EIIA Ntr , respectively. A recent study has shown that the phosphorylation state of PtsN can be modulated, depending u...
