Detection of transmembrane potentials by optical methods

Chemistry: molecular biology and microbiology – Treatment of micro-organisms or enzymes with electrical or... – Cell membrane or cell surface is target

Reexamination Certificate

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C435S029000, C436S063000, C436S172000, C436S519000, C436S546000, C436S805000

Reexamination Certificate

active

06342379

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates generally to compositions and optical methods for determining transmembrane potentials across biological membranes of living cells.
BACKGROUND OF THE INVENTION
Fluorescence detection and imaging of cellular electrical activity is a technique of great importance and potential (Grinvald, A., Frostig, R. D., Lieke, E., and Hildesheim, R. 1988. Optical imaging of neuronal activity.
Physiol. Rev.
68:1285-1366; Salzberg, B. M. 1983. Optical recording of electrical activity in neurons using molecular probes. In Current Methods in Cellular Neurobiology. J. L. Barker, editor. Wiley, N.Y. 139-187; Cohen, L. B. and S. Lesher. 1985. Optical monitoring of membrane potential: methods of multisite optical measurement. In Optical Methods in Cell Physiology. P. de Weer and B. M. Salzberg, editors. Wiley, N.Y. 71-99).
Mechanisms for optical sensing of membrane potential have traditionally been divided into two classes:
(1) sensitive but slow redistribution of permeant ions from the extracellular medium into the cell, and
(2) fast but small perturbations of relatively impermeable dyes attached to one face of the plasma membrane. see, Loew, L. M., “How to choose a potentiometric membrane probe”, In Spectroscopic Membrane Probes. L. M. Loew, ed., 139-151 (1988) (CRC Press, Boca Raton); Loew, L. M., “Potentiometric membrane dyes”, In Fluorescent and Luminescent Probes for Biological Activity. W. T. Mason, ed., 150-160 (1993) (Academic Press, San Diego).
The permeant ions are sensitive because the ratio of their concentrations between the inside and outside of the cell can change by up to the Nernstian limit of 10-fold for a 60 mV change in transmembrane potential. However, their responses are slow because to establish new equilibria, ions must diffuse through unstirred layers in each aqueous phase and the low-dielectric-constant interior of the plasma membrane. Moreover, such dyes distribute into all available hydrophobic binding sites indiscriminately. Therefore, selectivity between cell types is difficult. Also, any additions of hydrophobic proteins or reagents to the external solution, or changes in exposure to hydrophobic surfaces, are prone to cause artifacts. These indicators also fail to give any shift in fluorescence wavelengths or ratiometric output. Such dual-wavelength readouts are useful in avoiding artifacts due to variations in dye concentration, path length, cell number, source brightness, and detection efficiency.
By contrast, the impermeable dyes can respond very quickly because they need little or no translocation. However, they are insensitive because they sense the electric field with only a part of a unit charge moving less than the length of the molecule, which in turn is only a small fraction of the distance across the membrane. Furthermore, a significant fraction of the total dye signal comes from molecules that sit on irrelevant membranes or cells and that dilute the signal from the few correctly placed molecules.
In view of the above drawbacks, methods and compositions are needed which are sensitive to small variations in transmembrane potentials and can respond both to rapid, preferably on a millisecond timescale, and sustained membrane potential changes. Also needed are methods and compositions that are less susceptible to the effects of changes in external solution composition, more capable of selectively monitoring membranes of specific cell types, and within intracellular organelles and providing a ratiometric fluorescence signal.
Such methods require effective methods of discriminating measurements from within defined cell populations, or subcellular structures. This invention fulfils this and related needs.
SUMMARY OF THE INVENTION
Methods and compositions are provided for detecting changes in membrane potential in biological systems. One aspect of the detection method comprises;
a) providing a living cell with a first reagent comprising a charged hydrophobic molecule. Typically the molecule is a fluorescence resonance energy transfer (FRET) acceptor or donor, or is a quencher and is capable of redistributing within the membrane of a biological membrane in response to changes in the potential across the membrane;
b) providing the cell with a second reagent that can label the first face or the second face of a biological membrane within the cell. In one aspect, the second reagent can redistribute from the membrane to other sites in response to changes in the potential of the membrane. Typically the second reagent comprises a luminescent or fluorescent component capable of undergoing energy transfer with the first reagent or quenching light emission of the first reagent;
c) detecting light emission from the first reagent or the second reagent.
In one aspect of this method, the cell is exposed to excitation light at appropriate wavelengths and the degree of energy transfer between the first and second reagents determined. In one contemplated version of this method the excitation light is used to confocally illuminate the cell, thereby providing enhanced spatial resolution. In another aspect this is achieved via the use of two photon excitation.
In another aspect of this method, the cell is exposed to a luminescent or bioluminescent substrate for the luminescent component resulting in light emission from the luminescent component. The degree of energy transfer between the first and second reagent may then be determined by measuring the emission ratios of the first and second reagents, without the need to provide external illumination.
In one aspect of this method, light emission of the first reagent or the second reagent is dependent on the membrane potential across the membrane.
In another aspect of this method, the efficiency of energy transfer from the first reagent to the second reagent is dependent on the voltage potential across the membrane.
In another aspect, the cell additionally comprises an ion channel, receptor, transporter or membrane pore-forming agent that acts to set the membrane potential to a specific value.
Another aspect of the invention involves a method of monitoring subcellular organelle membrane potentials in a living cell comprising;
1) providing a living cell with a first reagent, comprising a hydrophobic, charged fluorescent molecule, and
2) providing the living cell with a second reagent comprising a luminescent or fluorescent component, wherein the luminescent or fluorescent component is targetable to the subcellular membrane, and wherein the second reagent undergoes energy transfer with said first reagent or quenches light emission of the first reagent.
In one aspect of this method the second reagent is targetable to the subcellular membrane through fusion to a protein or peptide that contains a targeting or localization sequence(s). Preferred localization sequences provide for specific localization of the protein to the defined location, with minimal accumulation of the reagent in other biological membranes.
Another aspect of the present invention is a transgenic organism comprising a first reagent that comprises a charged hydrophobic fluorescent molecule, and a second reagent comprising a bioluminescent or naturally fluorescent protein. The bioluminescent or naturally fluorescent protein is typically expressed within the transgenic organism and targetable to a cellular membrane. A second reagent provided to the transgenic organism undergoes energy transfer with the first reagent or quenches light emission of said first reagent. Such transgenic organisms may be used in whole animal studies to monitor drug effects on neuronal activity in vivo or to understand disease states in appropriate model systems.
Another aspect of the invention is a method of screening test chemicals for activity to modulate a target ion channel, involving, providing a living cell comprising a target ion channel, and a membrane potential modulator wherein the membrane potential modulator sets the resting membrane potential to a predefined value between about −150 mV and +100 mV. After contact of the l

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