Structure-function Relationships In Ion Channels Research Articles

Variation of Two S3b Residues in KV4.1-4.3 Channels Underlies Their Different Modulations by Spider Toxin κ-LhTx-1.

The naturally occurred peptide toxins from animal venoms are valuable pharmacological tools in exploring the structure-function relationships of ion channels. Herein we have identified the peptide toxin κ-LhTx-1 from the venom of spider Pandercetes sp (the Lichen huntsman spider) as a novel selective antagonist of the KV4 family potassium channels. κ-LhTx-1 is a gating-modifier toxin impeded KV4 channels’ voltage sensor activation, and mutation analysis has confirmed its binding site on channels’ S3b region. Interestingly, κ-LhTx-1 differently modulated the gating of KV4 channels, as revealed by toxin inhibiting KV4.2/4.3 with much more stronger voltage-dependence than that for KV4.1. We proposed that κ-LhTx-1 trapped the voltage sensor of KV4.1 in a much more stable resting state than that for KV4.2/4.3 and further explored the underlying mechanism. Swapping the non-conserved S3b segments between KV4.1(280FVPK283) and KV4.3(275VMTN278) fully reversed their voltage-dependence phenotypes in inhibition by κ-LhTx-1, and intensive mutation analysis has identified P282 in KV4.1, D281 in KV4.2 and N278 in KV4.3 being the key residues. Furthermore, the last two residues in this segment of each KV4 channel (P282/K283 in KV4.1, T280/D281 in KV4.2 and T277/N278 in KV4.3) likely worked synergistically as revealed by our combinatorial mutations analysis. The present study has clarified the molecular basis in KV4 channels for their different modulations by κ-LhTx-1, which have advanced our understanding on KV4 channels’ structure features. Moreover, κ-LhTx-1 might be useful in developing anti-arrhythmic drugs given its high affinity, high selectivity and unique action mode in interacting with the KV4.2/4.3 channels.

Cysteine Modification: Probing Channel Structure, Function and Conformational Change.

Cysteine substitution has been a powerful tool to investigate the structure and function of proteins. It has been particularly useful for studies of membrane proteins in their native environment, embedded in phospholipid membranes. Among the 20 amino acids, cysteine is uniquely reactive. This reactivity has motivated the synthesis of a wide array of sulfhydryl reactive chemicals. The commercially available array of sulfhydryl reactive reagents has allowed investigators to probe the local steric and electrostatic environment around engineered cysteines and to position fluorescent, paramagnetic and mass probes at specific sites within proteins and for distance measurements between pairs of sites. Probing the reactivity and accessibility of engineered cysteines has been extensively used in Substituted Cysteine Accessibility Method (SCAM) investigations of ion channels, membrane transporters and receptors. These studies have successfully identified the residues lining ion channels, agonist/antagonist and allosteric modulator binding sites, and regions whose conformation changes as proteins transition between different functional states. The thousands of cysteine-substitution mutants reported in the literature demonstrate that, in general, mutation to cysteine is well tolerated. This has allowed systematic studies of residues in transmembrane segments and in other parts of membrane proteins. Finally, by inserting pairs of cysteines and assaying their ability to form disulfide bonds, changes in proximity and mobility relationships between specific positions within a protein can be inferred. Thus, cysteine mutagenesis has provided a wealth of data on the structure of membrane proteins in their functional environment. This data can complement the structural insights obtained from the burgeoning number of crystal structures of detergent solubilized membrane proteins whose functional state is often uncertain. This article will review the use of cysteine mutagenesis to probe structure-function relationships in ion channels focusing mainly on Cys-loop receptors.

Distant Cytosolic Residues Mediate a Two-way Molecular Switch That Controls the Modulation of Inwardly Rectifying Potassium (Kir) Channels by Cholesterol and Phosphatidylinositol 4,5-Bisphosphate (PI(4,5)P2)

Cholesterol modulates inwardly rectifying potassium (Kir) channels. A two-way molecular cytosolic switch controls channel modulation by cholesterol and PI(4,5)P(2). Cholesterol and PI(4,5)P(2) induce a common gating pathway of Kir2.1 despite their opposite impact on channel function. These findings provide insights into structure-function relationship of ion channels and contribute to understanding of the mechanisms underlying their regulation by lipids. Inwardly rectifying potassium (Kir) channels play an important role in setting the resting membrane potential and modulating membrane excitability. An emerging feature of several Kir channels is that they are regulated by cholesterol. However, the mechanism by which cholesterol affects channel function is unclear. Here we show that mutations of two distant Kir2.1 cytosolic residues, Leu-222 and Asn-251, form a two-way molecular switch that controls channel modulation by cholesterol and affects critical hydrogen bonding. Notably, these two residues are linked by a residue chain that continues from Asn-251 to connect adjacent subunits. Furthermore, our data indicate that the same switch also regulates the sensitivity of the channels to phosphatidylinositol 4,5-bisphosphate, a phosphoinositide that is required for activation of Kir channels. Thus, although cholesterol and phosphatidylinositol 4,5-bisphosphate do not interact with the same region of Kir2.1, these different modulators induce a common gating pathway of the channel.

The patch clamp technique in ion channel research.

To understand the pathogenesis of a given ion channel disorder, knowledge of the mutation alone is insufficient, instead, the description of the associated functional defect is decisive. The patch clamp technique enables to achieve this both in native tissue as well as heterologous expression systems. By this technique, structure-function relationships of ion channels were elucidated that not only support the homology already suggested by amino acid alignments of different channel types, but that also pointed to regions important for gating, ion selectivity, or subunit interaction. Currently, effort is being made to develop automation of the technique which will result in a cost-effective, fast, and highly accurate method to test for drug actions on high throughput scales. This review contains an overview of channel structures, channel diseases, and methods to study channel function by the patch clamp technique.

Structure-function relationships of ion channels: Electrophysiology in the crystal age

Structure-function relationships of ion channels: Electrophysiology in the crystal age

Permeation models and structure-function relationships in ion channels.

Recent determination of the molecular structures of potassium andmechanosensitive channels from x-ray crystallography has led to arenewed interest in ion channels. The challenge for permeation modelsis to understand the functional properties of channels from the availablestructural information. Here we give a critical review of the three maincontenders, namely, continuum theories, Brownian dynamics and moleculardynamics. Continuum theories are shown to be invalid in a narrow channel environment because they ignore the self-energy of ions arising from theinduced charges on the dielectric boundary. Brownian and moleculardynamics are thus the only physically valid methods for studying thestructure-function relations in ion channels. Applications of thesemethods to potassium and calcium channels are presented, which illustratethe multi-ion nature of the permeation mechanism in selective biologicalchannels.

Random mutagenesis reveals a region important for gating of the yeast K+ channel Ykc1.

YKC1 (TOK1, DUK1, YORK) encodes the outwardly rectifying K+ channel of the yeast plasma membrane. Non-targeted mutations of YKC1 were isolated by their ability to completely block proliferation when expressed in yeast. All such mutations examined occurred near the cytoplasmic ends of the transmembrane segments following either of the duplicated P loops, which we termed the 'post-P loop' (PP) regions. These PP mutations specifically caused marked defects in the 'C1' states, a set of interrelated closed states that Ykc1 enters and exits at rates of tens to hundreds of milliseconds. These results indicate that the Ykc1 PP region plays a role in determining closed state conformations and that non-targeted mutagenesis and microbial selection can be a valuable tool for probing structure-function relationships of ion channels.

Ion Channels and Human Genetic Diseases

Ion channels have lately received much attention by geneticists and molecular biologists owing to the discovery of several inherited human "ion channels disorders". Important contributions to the understanding not only of pathogenesis, but also of the structure-function relationship of ion channels, have come from the functional analysis of these natually occurring mutant channels.

Cell-free expression of functional Shaker potassium channels.

The functional activity of ion channels and other membrane proteins requires that the proteins be correctly assembled in a transmembrane configuration. Thus, the functional expression of ion channels, neurotransmitter receptors and complex membrane-limited signalling mechanisms from complementary DNA has required the injection of messenger RNA or transfection of DNA into Xenopus oocytes or other target cells that are capable of processing newly translated protein into the surface membrane. These approaches, combined with voltage-clamp analysis of ion channel currents, have been especially powerful in the identification of structure-function relationships in ion channels. But oocytes express endogenous ion channels, neurotransmitter receptors and receptor-channel subunits, complicating the interpretation of results in mRNA-injected eggs. Furthermore, it is difficult to control experimentally the membrane lipids and post-translational modifications that underlie the regulation and modulation of ion channels in intact cells. A cell-free system for ion channel expression is ideal for good experimental control of protein expression and modulatory processes. Here we combine cell-free protein translation, microsomal membrane processing of nascent channel proteins, and reconstitution of newly synthesized ion channels into planar lipid bilayers to synthesize, glycosylate, process into membranes, and record in vitro the activity of functional Shaker potassium channels.

Toward an understanding of structure and function of ion channels 1

The second half of the 1980s is certain to be considered a turning point in the study of ion channels. Within the last few years, monumental advances in the application of molecular biology, single-channel recording, and direct molecular characterization have been brought to bear on the problem of relating the molecular structure of the ion channel proteins to their function in the cell membrane. Structure-function relationships can now be studied at a level of detail that was unimagined a decade ago. Recently, advances made with the techniques of molecular biology appear to have dominated the literature in this field; however, innovative strategies of structural characterization and electrical measurements of functioning channels in native and artificial membranes continue to break new ground. This paper is a selective review of current progress in understanding structure-function relationships in ion channels. The relative usefulness of determining amino acid sequences of channel proteins together with the resulting deductions about 3-dimensional structure and function will be evaluated with respect to the potential importance of studying the channel molecules more directly by biochemical, immunological, and electrophysiological methods. A full understanding of the details of channel structure and its relationship to function may be realized in the near future as a result of the interdisciplinary application of biophysical, biochemical, and molecular biological techniques.