Abstract
Two Gram-positive Tet proteins, TetA(L) from Bacillus subtilis and TetK from a Staphylococcus aureus plasmid, have previously been suggested to have multiple catalytic modes and roles. These include: tetracycline (Tc)-metal/H+ antiport for both proteins (Yamaguchi, A., Shiina, Y., Fujihira, E., Sawai, T., Noguchi, N., and Sasatsu, M. (1995) FEBS Lett. 365, 193-197; Cheng, J. Guffanti, A. A., Wang, W., Krulwich, T. A., and Bechhofer, D. H. (1996) J. Bacteriol. 178, 2853-2860); Na+(K+)/H+ antiport for both proteins (Cheng et al. (1996)); and an electrical potential-dependent K+ leak mode for TetK and highly truncated segments thereof that can facilitate net K+ uptake (Guay, G. G., Tuckman, M., McNicholas, P., and Rothstein, D. M. (1993) J. Bacteriol. 175, 4927-4929). Studies of membrane vesicles from Escherichia coli expressing low levels of complete and 3'-truncated versions of tetA(L) or tetK, now show that the full-length versions of both transporters catalyze electrogenic antiport and that demonstration of electrogenicity depends upon use of a low chloride buffer for the assay. The K+ uptake mode, assayed via 86Rb+ uptake, was also catalyzed by both full-length TetA(L) and TetK. This mode does not represent a potential-dependent leak. Such a leak was not demonstrable in energized membrane vesicles. Rather, Rb+ uptake occurred in right-side-out vesicles when the intravesicular space contained either Na+ or K+ but not choline. If an outwardly directed gradient of Na+ or K+ was present, Rb+ uptake occurred without energization in vesicles from cells transformed with a plasmid containing tetA(L) or tetK but not a control plasmid. Experiments in which a comparable exchange was carried out in low chloride buffers to which oxonol was added confirmed that the exchange was electrogenic. Thus, the K+ uptake mode is proposed to be a mode of the electrogenic monovalent cation/H+ antiport activity of TetA(L) and TetK in which K+ takes the place of the external protons. Truncated TetK and TetA(L) failed to catalyze either Tc-metal/H+ or Na+/H+ antiport in energized everted vesicles. Truncated TetK, but not TetA(L), did, however, exhibit modest, electrogenic Na+(K+)/Rb+ exchange as well as a small, potential-dependent leak of Rb+. The C-terminal halves of the TetA(L) and TetK proteins are thus required both for proton-coupled active transport activities of the multifunctional transporter and, perhaps, for minimizing cation leakiness.
Highlights
Tc1 enters bacterial cells in a non-carrier dependent fashion that is promoted by a transmembrane pH gradient, acid out [1]
Tet proteins might be a potential-dependent, electrogenic leak made possible by the presence of those particular proteins or it might be a catalytic mode of the electrogenic monovalent cation/Hϩ antiport in which Kϩ replaces the Hϩ
E. coli TK2420 (Kϩ uptake-deficient) cells transformed with full-length and truncated tetA(L) or tetK genes were examined for complementation, i.e. a reduction in the Bacterial strains or plasmids
Summary
Tetracycline; ⌬pH, transmembrane pH gradient, acid out for right-side-out vesicles or cells; ⌬⌿, transmembrane electrical potential, positive out for right-side-out vesicles or cells; MIC, minimal inhibitory concentration; MOPS, 4-morpholinepropanesulfonic acid. The new hypothesis arises from the discovery that these Tet proteins are electrogenic monovalent cation/Hϩ antiporters, i.e. have a catalytic mode in which cytoplasmic Naϩ or Kϩ is exchanged for a greater number of external Hϩ. A capacity to catalyze net Kϩ uptake might be restricted to those Tet proteins with both monovalent cation/Hϩ exchange activity and a high affinity for Kϩ. Both cloned TetA(L) and TetK were shown to restore Naϩ exclusion capacity and resistance to a ⌬tetA(L) strain of B. subtilis. The current studies support the hypothesis that net Kϩ uptake catalyzed by full-length forms of TetA(L) and TetK is a mode of the Naϩ(Kϩ)/Hϩ exchange of both proteins
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