In electrophysiological measurements, the presence of a diffusion potential disturbs the precise measurement of the reverse potential by altering the electrode potential. Using a micro-agar salt bridge, the impact of the diffusion potential is minimized, which allows a more precise measurement of substrate turnover numbers of reconstituted recombinant membrane proteins.
To date, more than 50% of all pharmacological drugs target the transport kinetics of membrane proteins. The electrophysiological characterization of membrane carrier proteins reconstituted in lipid bilayer membranes is a powerful but delicate method for the assessment of their physicochemical and pharmacological properties. The substrate turnover number is a unique parameter that allows the comparison of the activity of different membrane proteins. In an electrogenic transport, the gradient of the translocated substrate creates a membrane potential that directly correlates to the substrate turnover rate of the protein. By using silver chloride electrodes, a diffusion potential, also called liquid junction potential, is induced, which alters electrode potential and significantly disturbs precise membrane potential measurements. Diffusion potential can be minimized by a salt bridge, which balances electrode potential. In this article, a micro-agar salt bridge is designed to improve the electrophysiological set-up, which uses micropipettes for the membrane formation. The salt solution is filled into a microcapillary pipette tip, stabilized by the addition of agarose, and can be easily mounted to a standard electrode. The electrode potential of a micro-salt bridge electrode is more stable compared to a standard electrode. The implementation of this system stabilizes electrode potential and allows more precise measurements of membrane potential generated by a pH gradient. Using this system, the proton turnover rates of the mitochondrial carriers UCP1 and UCP3 are reinvestigated and compared to earlier measurements.
Membrane proteins are targeted by up to 60% of all known pharmaceutical drugs1. Electrophysiological measurements of membrane proteins are a powerful but delicate tool to analyze the electrogenic transport of substrates mediated by membrane carrier proteins. The modulation of the transmembrane current by the application of constant voltages or voltage ramps allows assessing the pharmacological and physical properties of the carriers, for instance, the activation and inhibition by substrates or the transport kinetics. Of special interest is the substrate turnover number, which displays the amount of substrate that is translocated by a membrane protein per time unit. It is a major parameter when comparing the kinetics of various membrane proteins. Establishing a concentration gradient of the charged substrate across the membrane generates an electromotive force from which the turnover number of the substrate is deduced.
Using an AgCl electrode, the presence of a chloride-free buffer creates a diffusion potential that alters electrode potential and leads to a shift in current-voltage measurements2. Although always present, it is negligible for standard conductance and capacity measurements since these parameters are either dependent on the slope of the current-voltage recording (conductance) or are the difference of a single recording (capacity), which cancels the potential. However, the recording of the reverse potential, which is created by the transport of substrate, can be significantly disturbed by the diffusion potential. Thus, for exact measurements of the reverse potential, the electrode potentials have to be kept constant.
The diffusion potential can be minimized by two methods: (i) in the presence of a bilayer membrane, a substrate concentration has to be increased on one side of the membrane3,4, or (ii) a salt bridge balances the electrode potential5. The first method is highly dependent on the stability of the measurements. The membrane has to survive for several minutes, from the addition of substrate under stirring until the substrate is almost equally distributed in the solution. If the membrane ruptures in between, the substrate gradient is altered by the free exchange of charged molecules, and measurements turn inaccurate. The latter method balances the diffusion potential but is limited by the size of the set-up. Implementing a small but functioning salt bridge in a micro range to an electrophysiological set-up is challenging6. For the latter method, the salt solution is filled into a microcapillary tip and stabilized by the addition of agarose to prevent diffusion of the salt solution to the buffer solution.
In this protocol, a straightforward production of a micro-agar salt bridge and implementation into an electrophysiological set-up based on the pipette set-up7 is described. A microcapillary tip is adjusted both to contain a 3 M KCl solution with 1 mol% (w/v) agarose and to bridge an AgCl electrode and buffer solution. The advantage of the micro-salt bridge is displayed by time recordings of the electrode potential shift and the more precise measurements of membrane potential at various pH gradients. In the model system of recombinant proteins reconstituted into liposomes, the turnover rates of mitochondrial carriers UCP1 and UCP3 produced under similar conditions are reinvestigated and compared to previous results3,8.
The implementation of the micro-agar salt bridge with the electrode minimizes its diffusion potential and allows more precise measurements of membrane potential generated by a pH gradient. In the presence of various transmembrane pH gradients, the potential shift of both electrodes was acceptable at ΔpH = 0.35 when comparing to the theoretical value of the Nernst equilibrium potential (ΦNernst =23.8 mV for ΔpH = 0.4). However, at more physiological pH gradients, as for instance in mitochondria between the matrix and intermembrane space, the standard AgCl electrode failed to precisely measure the potential shift at ΔpH = 1 (Figure 3A). The electrode bridged with micro-agar salt delivered the values which were much more comparable to the theory.
Diffusion potential may also occur at the AgCl reference electrode if the buffer solution is changed during the experiment. Chloride-free buffer solution was used in the experiments since uncoupling proteins were suggested to transport chloride ions, and the pH was adjusted using Tris or MES. The electrode potential, in the absence of a substantial concentration of chloride, primarily depends on chloride impurities in the buffer solution. As its composition is unchanged during the experiments, it will simply result in a constant offset potential. However, for the measurement of an absolute potential difference between the two electrodes, a simple agar salt-bridge system (Ag/AgCl 3 M KCl) could also be used for the reference electrode.
A micro-agar salt bridge balances the diffusion potential by an equilibration of the electrode potential. In order to stabilize the salt solution, 1% (w/v) agarose was added to prevent the mixing of the salt solution with the buffer solution. The salt ions K+ and Cl– have similar mobilities in liquid and balance the electrode potential. To properly install the salt bridge, the agar salt solution has to be sufficiently heated up to fill the microcapillary tip without any air bubbles and to cover the AgCl electrode. Before further usage, electrical contact between the salt bridge electrode and the reference electrode has to be checked. Depending on the time the salt bridge is used, the salt solution has to be sufficiently gelled to prevent any mixing of the salt solution with the buffer. This is especially critical if K+ or Cl– transporters are investigated. The salt bridge was used for a very short time and the elution of agarose is negligible in this time range. A higher concentration of agarose of up to 5%, or of agar (3% – 5%), allows using the salt bridge for a longer period of time6,12.
This method allows determining the transport kinetics of a membrane transporter (i) with low turnover rates and (ii) of mitochondrial proteins of the inner membrane, which can hardly be investigated in standard patch clamp set-ups13. Its precision is mainly dependent on the reverse potential measurement, which accuracy is decreased at a low total membrane conductance and small concentration gradients which induce a membrane potential below the noise of recording.
Using this set-up, the turnover rates of UCP1 and UCP3 as produced under the same conditions were measured. Due to the higher pH gradient, the obtained rates seem to be more precise and unperturbed by artefacts resulting from the minor electrode potential shift. It can be used to further analyze and compare mitochondrial membrane transporters produced under similar conditions.
The authors have nothing to disclose.
This work was supported by the Austrian Research Fund (P31559-B20 to E.E.P.). The authors thank Sarah Bardakji for the excellent technical assistance in the production and reconstitution of mouse UCP1 and UCP3 into proteoliposomes.
Microloader tips | Eppendorf | 5242956.003 | Microcapillary pipette tip |
Ethanol 99% | AustrAlco Österr. Agrar-Alkohol Handelsges.m.b.H | AAAH-5020-07025-230317 | |
Kaliumchlorid | Carl Roth GmbH + Co. Kg | 6781.3 | |
DC supply | Voltcraft | V10/CPG 1940 -01 | |
Agarose Standard | Carl Roth GmbH + Co. Kg | 3810.2 | |
Patch Clamp Amplifier | Heka | ||
Sample tube | Carl Roth GmbH + Co. Kg | 5863.1 | |
Na2SO4 | Carl Roth GmbH + Co. Kg | 8560.3 | |
MES | Carl Roth GmbH + Co. Kg | 4256.2 | |
TRIS | Carl Roth GmbH + Co. Kg | AE15.2 | |
EGTA | Carl Roth GmbH + Co. Kg | 3054.1 | |
Hexane | Sigma-Aldrich | 296090-100ML | |
Hexadecane | Sigma-Aldrich | 296317-100ML | |
Heating wire | Voltcraft | USPS-2250 |