The ClC chloride channels catalyse the selective flow of Cl- ions across cell membranes, thereby regulating electrical excitation in skeletal muscle and the flow of salt and water across epithelial barriers. Genetic defects in ClC Cl- channels underlie several familial muscle and kidney diseases. Here we present the X-ray structures of two prokaryotic ClC Cl- channels from Salmonella enterica serovar typhimurium and Escherichia coli at 3.0 and 3.5 A, respectively. Both structures reveal two identical pores, each pore being formed by a separate subunit contained within a homodimeric membrane protein. Individual subunits are composed of two roughly repeated halves that span the membrane with opposite orientations. This antiparallel architecture defines a selectivity filter in which a Cl- ion is stabilized by electrostatic interactions with alpha-helix dipoles and by chemical coordination with nitrogen atoms and hydroxyl groups. These findings provide a structural basis for further understanding the function of ClC Cl- channels, and establish the physical and chemical basis of their anion selectivity.
Ion channels exhibit two essential biophysical properties; that is, selective ion conduction, and the ability to gate-open in response to an appropriate stimulus. Two general categories of ion channel gating are defined by the initiating stimulus: ligand binding (neurotransmitter- or second-messenger-gated channels) or membrane voltage (voltage-gated channels). Here we present the structural basis of ligand gating in a K(+) channel that opens in response to intracellular Ca(2+). We have cloned, expressed, analysed electrical properties, and determined the crystal structure of a K(+) channel (MthK) from Methanobacterium thermoautotrophicum in the Ca(2+)-bound, opened state. Eight RCK domains (regulators of K(+) conductance) form a gating ring at the intracellular membrane surface. The gating ring uses the free energy of Ca(2+) binding in a simple manner to perform mechanical work to open the pore.
Living cells regulate the activity of their ion channels through a process known as gating. To open the pore, protein conformational changes must occur within a channel's membrane-spanning ion pathway. KcsA and MthK, closed and opened K(+) channels, respectively, reveal how such gating transitions occur. Pore-lining 'inner' helices contain a 'gating hinge' that bends by approximately 30 degrees. In a straight conformation four inner helices form a bundle, closing the pore near its intracellular surface. In a bent configuration the inner helices splay open creating a wide (12 A) entryway. Amino-acid sequence conservation suggests a common structural basis for gating in a wide range of K(+) channels, both ligand- and voltage-gated. The open conformation favours high conduction by compressing the membrane field to the selectivity filter, and also permits large organic cations and inactivation peptides to enter the pore from the intracellular solution.
The Kir3.1 K+ channel participates in heart rate control and neuronal excitability through G‐protein and lipid signaling pathways. Expression in Escherichia coli has been achieved by replacing three fourths of the transmembrane pore with the pore of a prokaryotic Kir channel, leaving the cytoplasmic pore and membrane interfacial regions of Kir3.1 origin. Two structures were determined at 2.2 Å. The selectivity filter is identical to the Streptomyces lividans K+ channel within error of measurement (r.m.s.d.<0.2 Å), suggesting that K+ selectivity requires extreme conservation of three‐dimensional structure. Multiple K+ ions reside within the pore and help to explain voltage‐dependent Mg2+ and polyamine blockade and strong rectification. Two constrictions, at the inner helix bundle and at the apex of the cytoplasmic pore, may function as gates: in one structure the apex is open and in the other, it is closed. Gating of the apex is mediated by rigid‐body movements of the cytoplasmic pore subunits. Phosphatidylinositol 4,5‐biphosphate‐interacting residues suggest a possible mechanism by which the signaling lipid regulates the cytoplasmic pore.
The intracellular C-terminal domain structure of a six-transmembrane K+ channel from Escherichia coli has been solved by X-ray crystallography at 2.4 A resolution. The structure is representative of a broad class of domains/proteins that regulate the conductance of K+ (here referred to as RCK domains) in prokaryotic K+ transporters and K+ channels. The RCK domain has a Rossmann-fold topology with unique positions, not commonly conserved among Rossmann-fold proteins, composing a well-conserved salt bridge and a hydrophobic dimer interface. Structure-based amino acid sequence alignments and mutational analysis are used to demonstrate that an RCK domain is also present and is an important component of the gating machinery in eukaryotic large-conductance Ca2+ activated K+ channels.
Recent breakthroughs in the high-resolution structural elucidation of ion channels and transporters are prompting a growing interest in methods for characterizing integral membrane proteins. These methods are proving extremely valuable in facilitating the production of X-ray diffraction-grade crystals. Here we present a robust and straightforward mass spectrometric procedure that utilizes matrix-assisted laser desorption/ionization to analyze integral membrane proteins in the presence of detergents. The utility of this method is illustrated with examples of high-quality mass spectral data obtained from membrane proteins for which atomic resolution structural studies are ongoing.
The CC-chemokine receptor 5 (CCR5) is the major coreceptor for the entry of macrophage-tropic (R5) HIV-1 strains into target cells. Posttranslational sulfation of tyrosine residues in the N-terminal tail of CCR5 is critical for high affinity interaction of the receptor with the HIV-1 envelope glycoprotein gp120 in complex with CD4. Here, we focused on defining precisely the sulfation pattern of the N terminus of CCR5 by using recombinant human tyrosylprotein sulfotransferases TPST-1 and TPST-2 to modify a synthetic peptide that corresponds to amino acids 2-18 of the receptor (CCR5 2-18). Analysis of the reaction products was made with a combination of reversed-phase HPLC, proteolytic cleavage, and matrix-assisted laser desorption͞ionization-time-of-flight mass spectrometry (MALDI-TOF MS). We found that CCR5 2-18 is sulfated by both TPST isoenzymes leading to a final product with four sulfotyrosine residues. Sulfates were added stepwise to the peptide producing specific intermediates with one, two, or three sulfotyrosines. The pattern of sulfation in these intermediates suggests that Tyr-14 and Tyr-15 are sulfated first, followed by Tyr-10, and finally Tyr-3. These results represent a detailed analysis of the multiple sulfation reaction of a peptide substrate by TPSTs and provide a structural basis for understanding the role of tyrosine sulfation of CCR5 in HIV-1 coreceptor and chemokine receptor function. The CC-chemokine receptor 5 (CCR5) is a member of the protein superfamily of G protein-coupled receptors (GPCRs) (1-3). High-affinity binding of the CC-chemokines MIP-1␣, MIP-1, RANTES (1-3), or MCP-2 (4) to CCR5 induces signaling through G proteins of the G i subfamily (1) and leads to chemotactic responses in CCR5-expressing leukocytes (5).In addition to their physiological function in chemokine signaling, some chemokine receptors are used as coreceptors by HIV-1. Entry of HIV-1 into target cells is mediated by the sequential interaction of the envelope glycoprotein gp120 with CD4 and a chemokine receptor on the cell membrane (6). CCR5 and CXCR4 are the primary HIV-1 coreceptors in vivo (7,8). CCR5, in particular, is the principal coreceptor for macrophage-tropic HIV-1 strains (R5 isolates) that are commonly transmitted between individuals (6, 9). A naturally occurring CCR5 mutant (⌬32) with a deletion in the second extracellular loop results in impaired membrane expression of the receptor and leads to resistance to HIV-1 infection in homozygous individuals (6).Interaction with both types of CCR5 ligands, CC-chemokines and the HIV-1 gp120-CD4 complex, involves the N-terminal domain, as well as other extracellular regions of the receptor (10-13). Within the N-terminal domain, a region rich in tyrosine residues and acidic amino acid residues ( Fig. 1; residues 2-18) was identified as a major determinant of HIV-1 coreceptor function (11,12,(14)(15)(16)(17). Sequence similarities with proteins known to be modified by tyrosine O-sulfation, a posttranslational modification mediated by tyrosylprotein sulfotransfera...
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