Covalently Dimerized SecA Is Functional in Protein Translocation

The ATPase SecA provides the driving force for the transport of secretory proteins across the cytoplasmic membrane of Escherichia coli. SecA exists as a dimer in solution, but the exact oligomeric state of SecA during membrane binding and preprotein translocation is a topic of debate. To study the requirements of oligomeric changes in SecA during protein translocation, a non-dissociable SecA dimer was formed by oxidation of the carboxyl-terminal cysteines. The cross-linked SecA dimer interacts with the SecYEG complex with a similar stoichiometry as non-cross-linked SecA. Cross-linking reversibly disrupts the SecB binding site on SecA. However, in the absence of SecB, the activity of the disulfide-bonded SecA dimer is indistinguishable from wild-type SecA. Moreover, SecYEG binding stabilizes a cold sodium dodecylsulfate-resistant dimeric state of SecA. The results demonstrate that dissociation of the SecA dimer is not an essential feature of the protein translocation reaction.

2,2,2-Trifluoroethanol Changes the Transition Kinetics and Subunit Interactions in the Small Bacterial Mechanosensitive Channel MscS

2,2,2-Trifluoroethanol (TFE), a low-dielectric solvent, has recently been used as a promising tool to probe the strength of intersubunit interactions in membrane proteins. An analysis of inner membrane proteins of Escherichia coli has identified several SDS-resistant protein complexes that separate into subunits upon exposure to TFE. One of these was the homo-heptameric stretch-activated mechanosensitive channel of small conductance (MscS), a ubiquitous component of the bacterial turgor-regulation system. Here we show that a substantial fraction of MscS retains its oligomeric state in cold lithium-dodecyl-sulfate gel electrophoresis. Exposure of MscS complexes to 10–15 vol % TFE in native membranes or nonionic detergent micelles before lithium-dodecyl-sulfate electrophoresis results in a complete dissociation into monomers, suggesting that at these concentrations TFE by itself disrupts or critically compromises intersubunit interactions. Patch-clamp analysis of giant E. coli spheroplasts expressing MscS shows that exposure to TFE in lower concentrations (0.5–5.0 vol %) causes leftward shifts of the dose-response curves when applied extracellularly, and rightward shifts when added from the cytoplasmic side. In the latter case, TFE increases the rate of tension-dependent inactivation and lengthens the process of recovery to the resting state. MscS responses to pressure ramps of different speeds indicate that in the presence of TFE most channels reside in the resting state and only at tensions near the activation threshold does TFE dramatically speed up inactivation. The effect of TFE is reversible as normal channel activity returns 15–30 min after a TFE washout. We interpret the observed midpoint shifts in terms of asymmetric partitioning of TFE into the membrane and distortion of the bilayer lateral pressure profile. We also relate the increased rate of inactivation and subunit separation with the capacity of TFE to perturb buried interhelical contacts in proteins and discuss these effects in the framework of the proposed gating mechanism of MscS

Phosphatidic acid plays a special role in stabilizing and folding of the tetrameric potassium channel KcsA

In this study, we investigated how the presence of anionic lipids influenced the stability and folding properties of the potassium channel KcsA. By using a combination of gel electrophoresis, tryptophan fluorescence and acrylamide quenching experiments, we found that the presence of the anionic lipid phosphatidylglycerol (PG) in a phosphatidylcholine (PC) bilayer slightly stabilized the tetramer and protected it from trifluoroethanol- induced dissociation. Surprisingly, the presence of phosphatidic acid (PA) had a much larger effect on the stability of KcsA and this lipid, in addition, significantly influenced the folding properties of the protein. The data indicate that PA creates some specificity over PG, and that it most likely stabilizes the tetramer via both electrostatic and hydrogen bond interactions