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Voltage gated ion channels (VGICs) shape the electrical character of cells by undergoing structural changes in response to membrane depolarization. High-resolution techniques have provided a wealth of data on individual VGIC structures, but the conformational changes of endogenous channels in live cell membranes have remained unexplored. Here, we describe methods for imaging structural changes of voltage-gated K+ channels in living cells, using peptidyl toxins labeled with fluorophores that report specific protein conformations. These Endogenous Voltage-sensor Activity Probes (EVAPs) enable study of both VGIC allostery and function in the context of endogenous live-cell membranes under different physiological states. In this chapter, we describe methods for the synthesis, imaging, and analysis of dynamic EVAPs, which can report K+ channel activity in complex tissue preparations via 2-photon excitation microscopy, and environment-sensitive EVAPs, which report voltage-dependent conformational changes at the VGIC-toxin interface. The methods here present the utility of current EVAPs and lay the groundwork for the development of other probes that act by similar mechanisms. EVAPs can be correlated with electrophysiology, offering insight into the molecular details of endogenous channel function and allostery in live cells. This enables investigation of conformational changes of channels in their native, functional states, putting structures and models into a context of live-cell membranes. The expansive array of state-dependent ligands and optical probes should enable probes more generally for investigating the molecular motions of endogenous proteins.Membrane potential is a fundamental biophysical parameter common to all of cellular life. Traditional methods to measure membrane potential rely on electrodes, which are invasive and low-throughput. Optical methods to measure membrane potential are attractive because they have the potential to be less invasive and higher throughput than classic electrode based techniques. However, most optical measurements rely on changes in fluorescence intensity to detect changes in membrane potential. In this chapter, we discuss the use of fluorescence lifetime imaging microscopy (FLIM) and voltage-sensitive fluorophores (VoltageFluors, or VF dyes) to estimate the millivolt value of membrane potentials in living cells. We discuss theory, application, protocols, and shortcomings of this approach.Monitoring the conformational changes of proteins is critical to understand their function. Ion channels are membrane-bound minute machines controlling the passage of ions across biological membranes. The precise labeling of ion channels with fluorescent probes allows studying their dynamics and facilitates their characterization by high-resolution optical techniques. Here we describe a protocol for the use of a small fluorescent reporter, incorporated by expansion of the genetic code in the host cell. An important advantage of using small probes is that they are less likely to perturb protein structure, function, and trafficking. In our hands, Tyr-coumarin proved to be useful to measure the conformational changes occurring in the narrow space of the permeation pathway in single capsaicin receptors. The method described here could be directly translated to the study of membrane receptors, non-electrogenic transporters, or membrane-bound enzymes.Transient Receptor Potential (TRP) channels play numerous important physiological roles in humans. Notably, they are involved in temperature sensing and regulation, in the proper functioning of immune and cardiac systems, in skin, hair, and bone physiology and in many types of cancer. Because of their physiological significance there has been much interest in elucidating their molecular mechanisms of action. Recent improvements in eukaryotic protein expression and purification techniques and in cryo-electron microscopy (cryo-EM) have greatly facilitated TRP channel studies. https://www.selleckchem.com/products/2-aminoethyl-diphenylborinate.html The TRP Vanilloid 2 (TRPV2) channel has emerged as particularly amenable to structural studies and its structure has been solved by both X-ray crystallography and by cryo-EM. Here, we provide an overview of demands posed by X-ray crystallography and cryo-EM on protein sample preparation and outline a step-by-step protocol for preparing the TRPV2 protein for structure determination by both of these techniques.The SARS-CoV-2 3a protein is a putative ion channel implicated in virus life cycle and pathogenesis. We recently expressed, purified, and reconstituted 3a into lipid nanodiscs to solve its structure by cryo-EM to 2.1Å resolution. In this chapter, we describe methods we developed in order to facilitate the study of this protein in other laboratories. We emphasize factors that enabled rapid progression from gene sequence to reconstituted protein (3 weeks in the case of 3a) and provide general observations and tips for adapting these protocols to other membrane proteins of interest.Nicotinic acetylcholine receptors are members of the Cys-loop superfamily of pentameric ligand-gated ion channels. The electric organ of the Torpedo ray is extraordinarily rich in an acetylcholine receptor that is homologous to the human nicotinic receptor found at the neuromuscular junction. Due to this abundant natural source in the fish and the relatively accessible preparation of the neuromuscular junction (compared to a central synapse), this muscle-type receptor and specifically the fish receptors have long been used as the prototype for study of nicotinic receptors. However, an absence of structural detail at high resolution has limited the chemical interpretation of this archetypal nicotinic receptor. One of the main concerns in preparing receptor for high resolution structural analysis was its documented sensitivity to particular detergents and requirements for specific lipids in order to maintain function after reconstitution in a membrane. Here, we present methods for purifying native nicotinic receptor from Torpedo electric tissue that maintains functionality after reconstitution and that is amenable to high resolution structural analysis. The specific developments we describe include detergent exchange during purification, inclusion of specific lipids during purification and for nanodisc reconstitution, and synthesis of a new affinity reagent for rapid isolation of receptors.
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