The KdpF subunit is part of the K(+)-translocating Kdp complex of Escherichia coli and is responsible for stabilization of the complex in vitro

The kdpABC operon codes for the high affinity K(+)-translocating Kdp complex (P-type ATPase) of Escherichia coli. Upon expression of this operon in minicells, a so far unrecognized small hydrophobic polypeptide, KdpF, could be identified on high resolution SDS-polyacrylamide gels in addition to the subunits KdpA, KdpB, and KdpC. Furthermore, it could be demonstrated that KdpF remains associated with the purified complex. As determined by mass spectrometry, this peptide is present in its formylated form and has a molecular mass of 3100 Da. KdpF is not essential for growth on low K(+) (0.1 mM) medium, as shown by deletion analysis of kdpF, but proved to be indispensable for a functional enzyme complex in vitro. In the absence of KdpF, the ATPase activity of the membrane-bound Kdp complex was almost indistinguishable from that of the wild type. In contrast, the purified detergent-solubilized enzyme complex showed a dramatic decrease in enzymatic activity. However, addition of purified KdpF to the KdpABC complex restored the activity up to wild type level. It is interesting to note that the addition of high amounts of E. coli lipids had a similar effect. Although KdpF is not essential for the function of the Kdp complex in vivo, it is part of the complex and functions as a stabilizing element in vitro. The corresponding operon should now be referred to as kdpFABC.     

Clarification of the structural and functional features of the osmoregulated kdp operon of Escherichia coli

Expression of the Escherichia coli kdpABC operon, which is responsible for a high-affinity potassium-uptake system, is regulated in response to a change in the medium osmolarity. In this study, we clarified the structure and function of the kdpABC promoter including its regulatory sequence at the molecular level. The canonical -35 and -10 regions determined for the promoter were not fully functional, i.e. in addition to them, a cis-acting sequence located upstream of the -35 region was essential for full activation of the promoter. This upstream sequence was demonstrated to be the target site for the trans-acting activator, KdpE.     

Wide distribution of homologs of Escherichia coli Kdp K+-ATPase among gram-negative bacteria.

We used Southern blotting to screen a variety of bacterial genes for homology to the kdp genes of Escherichia coli, genes that encode an ATP-driven K+ transport system. We found that most enterobacteria have sequences homologous to those of the three kdp structural genes and the kdpD regulatory gene. A number of distantly related species, including some cyanobacteria, have sequences homologous to those of the structural genes but not the regulatory gene. In all cases only a single region of homology was found. These results suggest that ATP-driven transport systems similar to the Kdp system in structure and regulation are found in many enteric organisms. In other gram-negative organisms, the ATPase is more divergent, retaining good homology at the DNA level only to the highly conserved phosphorylated subunit of the ATPase.     

Expression of the Kdp ATPase Is Consistent with Regulation by Turgor Pressure

The kdpFABC operon of Escherichia coli encodes the four protein subunits of the Kdp K⁺ transport system. Kdp is expressed when growth is limited by the availability of K⁺. Expression of Kdp is dependent on the products of the adjacent kdpDE operon, which encodes a pair of two-component regulators. Studies with kdp-lac fusions led to the suggestion that change in turgor pressure acts as the signal to express Kdp (L. A. Laimins, D. B. Rhoads, and W. Epstein, Proc. Natl. Acad. Sci. USA 78:464–468, 1981). More recently, effects of compatible solutes, among others, have been interpreted as inconsistent with the turgor model (H. Asha and J. Gowrishankar, J. Bacteriol. 175:4528–4537, 1993). We re-examined the effects of compatible solutes and of medium pH on expression of Kdp in studies in which growth rate was also measured. In all cases, Kdp expression correlated with the K⁺ concentration when growth began to slow. Making the reasonable but currently untestable assumptions that the reduction in growth rate by K⁺ limitation is due to a reduction in turgor and that addition of betaine does not increase turgor, we concluded that all of the data on Kdp expression are consistent with control by turgor pressure.