Apparent charge of binding site in ion-translocating enzymes: kinetic impact
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Abstract
Recently, we presented a general scope for the nonlinear electrical properties of enzymes E which catalyze translocation of a substrate S with charge number zS through lipid membranes (Boyd et al. J. Membr. Biol. 195:1–12, 2003). In this study, the voltage sensitivity of the enzymatic reaction cycle has been assigned to one predominant reversible reaction step, i.e. the reorientation of either E or ES in the electric field, leaving the reorientation of the alternate state (ES or E) electroneutral, respectively. With this simplification, the steady-state current–voltage relationships (IV) assumed saturation kinetics like in Michaelis–Menten systems. Here, we introduce an apparent charge number zE of the unoccupied binding site of the enzyme, which accounts for the impact of all charged residues in the vicinity of the physical binding site. With this more realistic concept, the occupied binding site assumes an apparent charge of \( z_{{{\text{ES}}}} = z_{{\text{E}}} + z_{{\text{S}}} \), and IV does not saturate any more in general, but exponentially approaches infinite or zero current for large voltage displacements from equilibrium. These nonlinear characteristics are presented here explicitly. They are qualtitatively explained in a mechanistic way, and are illustrated by simple examples. We also demonstrate that the correct determination of the model parameters from experimental data is still possible after incorporating zE and its corollaries into the previous model of enzyme-mediated ion translocation.
Keywords
Current–voltage relationship Enzyme kinetics Electro-enzymes Voltage clamp Voltage sensitivityNotes
Acknowledgements
This work has been supported by grants from the Natural Sciences and Engineering Research Council of Canada to C.M.B.
References
- Allen GJ, Sanders D, Gradmann D (1998) Calcium-potassium selectivity: kinetic analysis of current-voltage relationships of the open, slowly activating channel in the vacuolar membrane of guard-cells of Vicia faba. Planta 204:528–541Google Scholar
- Bernèche S, Roux B (2001) Energetics of ion conduction through the K+ channel. Nature 414:73–76Google Scholar
- Boyd J, Gradmann D, Boyd CM (2003) Transinhibition and voltage-gating in a fungal nitrate transporter. J Membr Biol 195:1–12 Google Scholar
- Eisenberg RS (1990) Channels as enzymes. J Membr Biol 115:1–12Google Scholar
- Gradmann D, Boyd CM (1999) Electrophysiology of the marine diatom Coscinodiscus wailesii IV: types of non-linear current–voltage–time relationships recorded with single saw-tooth voltage-clamp. Eur Biophys J 28:591–599Google Scholar
- Gradmann D, Boyd CM (2000) Three types of membrane excitations in the marine diatom Coscinodiscus wailesii. J Membr Biol 175:149–160Google Scholar
- Gradmann D, Boyd CM (2004) Current–voltage–time records of ion translocating enzymes. Eur Biophys J 33:396–411Google Scholar
- Hansen U-P, Gradmann D, Sanders D, Slayman CL (1981) Interpretation of current–voltage relationships for active ion transport systems. I. Steady-state reaction-kinetic analysis of Class-I mechanisms. J Membr Biol 63:165–190Google Scholar
- Jiang Y, Ruta V, Chen J, Lee A, MacKinnon R (2003) The principle of gating charge movement in a voltage-dependent K+ channel. Nature 423:42–48Google Scholar
- Läuger P (1980) Kinetic properties of ion carriers and channels. J Membr Biol 57:163–178Google Scholar
- Läuger P (1995) Conformational transitions of ionic channels. In: Sakmann B, Neher E (eds) Single-channel recording, 2nd edn. Plenum, New York, pp 651–662Google Scholar
- Morais-Cabral J, Zhou Y, MacKinnon R (2001) Energetic optimization of ion conduction rate by the K+ selectivity filter. Nature 414:37–42Google Scholar