Purification and Crystallization of the Respiratory Complex Formate Dehydrogenase-N from Escherichia Coli

Acta Crystallographica. Section D, Biological Crystallography. Jan, 2002  |  Pubmed ID: 11752799

A membrane-protein complex, formate dehydrogenase-N from Escherichia coli, has been purified and crystallized. This molybdenum-containing enzyme, composed of alpha, beta and gamma subunits, is the major electron donor to the nitrate respiratory chain of E. coli. The formate dehydrogenase-N crystals belong to the cubic space group P2(1)3, with unit-cell parameters a = b = c = 203 A. An asymmetric unit of the crystals is assumed to contain one formate dehydrogenase-N monomer (MW 170 kDa). One data set to 1.6 A resolution, with 342 711 independent observations (94.4% complete) and an R(merge) of 0.08, has been collected from a single crystal. This is the highest resolution data set reported for a membrane-protein complex to date.

The X-ray Crystal Structures of Wild-type and EQ(I-286) Mutant Cytochrome C Oxidases from Rhodobacter Sphaeroides

Journal of Molecular Biology. Aug, 2002  |  Pubmed ID: 12144789

The structure of cytochrome c oxidase from Rhodobacter sphaeroides has been solved at 2.3/2.8A (anisotropic resolution). This high-resolution structure revealed atomic details of a bacterial terminal oxidase including water molecule positions and a potential oxygen pathway, which has not been reported in other oxidase structures. A comparative study of the wild-type and the EQ(I-286) mutant enzyme revealed structural rearrangements around E(I-286) that could be crucial for proton transfer in this enzyme. In the structure of the mutant enzyme, EQ(I-286), which cannot transfer protons during oxygen reduction, the side-chain of Q(I-286) does not have the hydrogen bond to the carbonyl oxygen of M(I-107) that is seen in the wild-type structure. Furthermore, the Q(I-286) mutant has a different arrangement of water molecules and residues in the vicinity of the Q side-chain. These differences between the structures could reflect conformational changes that take place upon deprotonation of E(I-286) during turnover of the wild-type enzyme, which could be part of the proton-pumping machinery of the enzyme.

Structure and Function of Quinone Binding Membrane Proteins

Advances in Protein Chemistry. 2003  |  Pubmed ID: 12629970

Structure and Mechanism of the Lactose Permease of Escherichia Coli

Science (New York, N.Y.). Aug, 2003  |  Pubmed ID: 12893935

Membrane transport proteins that transduce free energy stored in electrochemical ion gradients into a concentration gradient are a major class of membrane proteins. We report the crystal structure at 3.5 angstroms of the Escherichia coli lactose permease, an intensively studied member of the major facilitator superfamily of transporters. The molecule is composed of N- and C-terminal domains, each with six transmembrane helices, symmetrically positioned within the permease. A large internal hydrophilic cavity open to the cytoplasmic side represents the inward-facing conformation of the transporter. The structure with a bound lactose homolog, beta-D-galactopyranosyl-1-thio-beta-D-galactopyranoside, reveals the sugar-binding site in the cavity, and residues that play major roles in substrate recognition and proton translocation are identified. We propose a possible mechanism for lactose/proton symport (co-transport) consistent with both the structure and a large body of experimental data.

The Lactose Permease of Escherichia Coli: Overall Structure, the Sugar-binding Site and the Alternating Access Model for Transport

FEBS Letters. Nov, 2003  |  Pubmed ID: 14630326

Membrane transport proteins transduce free energy stored in electrochemical ion gradients into a concentration gradient and are a major class of membrane proteins, many of which play important roles in human health and disease. Recently, the X-ray structure of the Escherichia coli lactose permease (LacY), an intensively studied member of a large group of related membrane transport proteins, was solved at 3.5 A. LacY is composed of N- and C-terminal domains, each with six transmembrane helices, symmetrically positioned within the molecule. The structure represents the inward-facing conformation, as evidenced by a large internal hydrophilic cavity open to the cytoplasmic side. The structure with a bound lactose homolog reveals the sugar-binding site in the cavity, and a mechanism for translocation across the membrane is proposed in which the sugar-binding site has alternating accessibility to either side of the membrane.

Structural Comparison of Lactose Permease and the Glycerol-3-phosphate Antiporter: Members of the Major Facilitator Superfamily

Current Opinion in Structural Biology. Aug, 2004  |  Pubmed ID: 15313234

Structural knowledge of the major facilitator superfamily has dramatically increased during the past year with the emergence of the structures of three members of this family of transporters. All three structures reveal 12 transmembrane helices forming two distinct domains, and could imply that members of this superfamily have preserved both secondary and tertiary structure elements during evolution.

Lactose Permease As a Paradigm for Membrane Transport Proteins (Review)

Molecular Membrane Biology. Jul-Aug, 2004  |  Pubmed ID: 15371012

Our structural knowledge of the major facilitator superfamily (MFS) has dramatically increased in the past year with three structures of proteins from the MFS (oxalate/formate antiporter; lactose/proton symporter and the P(i)/glycerol-3-phosphate antiporter). All three structures revealed 12 transmembrane helices forming two distinct domains and could imply that members of the MFS have preserved both secondary as well as tertiary structural elements during evolution. Lactose permease, a particularly well-studied member of the MFS, has been extensively explored by a number of molecular biological, biochemical and biophysical approaches. In this review, we take a closer look at the structure of LacY and incorporate a wealth of biochemical and biophysical data in order to propose a possible mechanism for lactose/proton symport. In addition, we make some brief comparisons between the structures of LacY and GlpT.

The Crystal Structure of the Primary Ca2+ Sensor of the Na+/Ca2+ Exchanger Reveals a Novel Ca2+ Binding Motif

The Journal of Biological Chemistry. Aug, 2006  |  Pubmed ID: 16774926

The Na+/Ca2+ exchanger is a plasma membrane protein that regulates intracellular Ca2+ levels in cardiac myocytes. Transport activity is governed by Ca2+, and the primary Ca2+ sensor (CBD1) is located in a large cytoplasmic loop connecting two transmembrane helices. The binding of Ca2+ to the CBD1 sensory domain results in conformational changes that stimulate the exchanger to extrude Ca2+. Here, we present a crystal structure of CBD1 at 2.5A resolution, which reveals a novel Ca2+ binding site consisting of four Ca2+ ions arranged in a tight planar cluster. This intricate coordination pattern for a Ca2+ binding cluster is indicative of a highly sensitive Ca2+ sensor and may represent a general platform for Ca2+ sensing.

What We Know About the Structure of NCX1 and How It Relates to Its Function

Annals of the New York Academy of Sciences. Mar, 2007  |  Pubmed ID: 17303833

NCX1 is modeled to contain nine transmembrane segments (TMS) with a large intracellular loop between TMS 5-6 and two reentrant loops connecting TMS 2-3 and TMS 7-8. NCX1 also contains two regions of internal repeats. The alpha repeats are composed of TMS 2 and 3 and TMS 7 and 8 and are involved in ion binding and transport. The beta repeats are in the large intracellular loop and are involved in binding of regulatory Ca2+. Our studies on the structure/function analysis of NCX1 have focused on the alpha- and beta-repeat regions and on how the TMS pack in the membrane. We have examined the alpha1 repeat by mutagenesis of residues modeled to be in the reentrant loop and TMS 3 and by determination of ion affinities of the mutants. Our results show that TMS 3 and not the reentrant loop is involved in Na+ binding. No mutants demonstrated altered affinity for transported Ca2+. We have synthesized a fusion protein composed of the beta1 repeat. This fusion protein was expressed in Escherichia coli and purified. The fusion protein binds Ca2+ and shows conformational changes on binding. The crystal structure of the beta1 repeat shows that it is composed of a seven-stranded beta-sandwich with Ca2+-binding sites located at one end of the sandwich. Four Ca2+ ions bind to the beta1 repeat in a manner reminiscent of Ca2+ binding to C2 domains. Packing of TMS in the membrane has been studied by cross-linking induced mobility shifts on SDS-PAGE. Interactions between TMS 1, 2, 3, 6, 7, and 8 have been identified.

The Second Ca2+-binding Domain of the Na+ Ca2+ Exchanger is Essential for Regulation: Crystal Structures and Mutational Analysis

Proceedings of the National Academy of Sciences of the United States of America. Nov, 2007  |  Pubmed ID: 17962412

The Na(+)-Ca(2+) exchanger plays a central role in cardiac contractility by maintaining Ca(2+) homeostasis. Two Ca(2+)-binding domains, CBD1 and CBD2, located in a large intracellular loop, regulate activity of the exchanger. Ca(2+) binding to these regulatory domains activates the transport of Ca(2+) across the plasma membrane. Previously, we solved the structure of CBD1, revealing four Ca(2+) ions arranged in a tight planar cluster. Here, we present structures of CBD2 in the Ca(2+)-bound (1.7-A resolution) and -free (1.4-A resolution) conformations. Like CBD1, CBD2 has a classical Ig fold but coordinates only two Ca(2+) ions in primary and secondary Ca(2+) sites. In the absence of Ca(2+), Lys(585) stabilizes the structure by coordinating two acidic residues (Asp(552) and Glu(648)), one from each of the Ca(2+)-binding sites, and prevents a substantial protein unfolding. We have mutated all of the acidic residues that coordinate the Ca(2+) ions and have examined the effects of these mutations on regulation of exchange activity. Three mutations (E516L, D578V, and E648L) at the primary Ca(2+) site completely remove Ca(2+) regulation, placing the exchanger into a constitutively active state. These are the first data defining the role of CBD2 as a regulatory domain in the Na(+)-Ca(2+) exchanger.

How Does Regulatory Ca2+ Regulate the Na+-Ca2+ Exchanger?

Channels (Austin, Tex.). Nov-Dec, 2007  |  Pubmed ID: 18690047

Spatial and temporal regulation of intracellular Ca2+ concentrations is a fundamental requirement for life. The mammalian cardiac Na+-Ca2+ exchanger serves as the main mechanism for Ca2+ efflux after heart contraction. Exchange activity is highly regulated by intracellular Ca2+, which binds two regulatory domains (CBD1 and CBD2) and triggers the full activity of the exchanger. We solved the X-ray crystallographic structure of CBD2 in the presence and absence of Ca2+. Together with mutational analysis of the Ca2+ binding sites, this study reveals the crucial role of one of the two bound Ca2+ ions and helps propose hypotheses on the mechanism of regulation of the exchanger.

The Crystal Structure of Mouse VDAC1 at 2.3 A Resolution Reveals Mechanistic Insights into Metabolite Gating

Proceedings of the National Academy of Sciences of the United States of America. Nov, 2008  |  Pubmed ID: 18988731

The voltage-dependent anion channel (VDAC) constitutes the major pathway for the entry and exit of metabolites across the outer membrane of the mitochondria and can serve as a scaffold for molecules that modulate the organelle. We report the crystal structure of a beta-barrel eukaryotic membrane protein, the murine VDAC1 (mVDAC1) at 2.3 A resolution, revealing a high-resolution image of its architecture formed by 19 beta-strands. Unlike the recent NMR structure of human VDAC1, the position of the voltage-sensing N-terminal segment is clearly resolved. The alpha-helix of the N-terminal segment is oriented against the interior wall, causing a partial narrowing at the center of the pore. This segment is ideally positioned to regulate the conductance of ions and metabolites passing through the VDAC pore.

The Crystal Structure of a Sodium Galactose Transporter Reveals Mechanistic Insights into Na+/sugar Symport

Science (New York, N.Y.). Aug, 2008  |  Pubmed ID: 18599740

Membrane transporters that use energy stored in sodium gradients to drive nutrients into cells constitute a major class of proteins. We report the crystal structure of a member of the solute sodium symporters (SSS), the Vibrio parahaemolyticus sodium/galactose symporter (vSGLT). The approximately 3.0 angstrom structure contains 14 transmembrane (TM) helices in an inward-facing conformation with a core structure of inverted repeats of 5 TM helices (TM2 to TM6 and TM7 to TM11). Galactose is bound in the center of the core, occluded from the outside solutions by hydrophobic residues. Surprisingly, the architecture of the core is similar to that of the leucine transporter (LeuT) from a different gene family. Modeling the outward-facing conformation based on the LeuT structure, in conjunction with biophysical data, provides insight into structural rearrangements for active transport.

Structure and Functional Analysis of a Ca2+ Sensor Mutant of the Na+/Ca2+ Exchanger

The Journal of Biological Chemistry. May, 2009  |  Pubmed ID: 19332552

The mammalian Na(+)/Ca(2+) exchanger, NCX1.1, serves as the main mechanism for Ca(2+) efflux across the sarcolemma following cardiac contraction. In addition to transporting Ca(2+), NCX1.1 activity is also strongly regulated by Ca(2+) binding to two intracellular regulatory domains, CBD1 and CBD2. The structures of both of these domains have been solved by NMR spectroscopy and x-ray crystallography, greatly enhancing our understanding of Ca(2+) regulation. Nevertheless, the mechanisms by which Ca(2+) regulates the exchanger remain incompletely understood. The initial NMR study showed that the first regulatory domain, CBD1, unfolds in the absence of regulatory Ca(2+). It was further demonstrated that a mutation of an acidic residue involved in Ca(2+) binding, E454K, prevents this structural unfolding. A contradictory result was recently obtained in a second NMR study in which Ca(2+) removal merely triggered local rearrangements of CBD1. To address this issue, we solved the crystal structure of the E454K-CBD1 mutant and performed electrophysiological analyses of the full-length exchanger with mutations at position 454. We show that the lysine substitution replaces the Ca(2+) ion at position 1 of the CBD1 Ca(2+) binding site and participates in a charge compensation mechanism. Electrophysiological analyses show that mutations of residue Glu-454 have no impact on Ca(2+) regulation of NCX1.1. Together, structural and mutational analyses indicate that only two of the four Ca(2+) ions that bind to CBD1 are important for regulating exchanger activity.

Crystal Packing Analysis of Murine VDAC1 Crystals in a Lipidic Environment Reveals Novel Insights on Oligomerization and Orientation

Channels (Austin, Tex.). May-Jun, 2009  |  Pubmed ID: 19574737

All eukaryotic cells require efficient trafficking of metabolites between the mitochondria and the rest of the cell. This exchange is carried out by the dominant protein in the outer mitochondrial membrane (OMM), the Voltage Dependent Anion Channel (VDAC), which serves as the primary pathway for the exchange of ions and metabolites between the cytoplasm and the intermembrane space of the mitochondria. Additionally, VDAC provides a scaffold for the binding of modulator proteins to the mitochondria and has been implicated in mitochondria-dependent cell death. We recently determined the structure of the murine VDAC1 (mVDAC1) at 2.3 A resolution crystallized in a native-like bilayer environment. The high-resolution structure provided concise structural details about the voltage-sensing N-terminal domain and catalyzed new hypotheses regarding the gating mechanisms for metabolites and ions that transit the OMM. In this study, the crystal packing of mVDAC1 is analyzed revealing a strong antiparallel dimer that further assemble as hexamers mimicking the native oligomeric packing observed in EM and AFM images of the OMM. Oligomerization has been shown to be important for VDAC regulation and function, and mVDAC1 crystal packing in a lipidic medium reveals insights on how oligomerization is accomplished using protein-protein and protein-lipid interactions. Furthermore, orientation of VDAC in the OMM remains uncertain due to inconsistencies in antibody labeling studies. The physiological implications of a novel antiparallel arrangement are addressed that may clarify these conflicting biochemical data.

Structure and Function of Na(+)-symporters with Inverted Repeats

Current Opinion in Structural Biology. Aug, 2009  |  Pubmed ID: 19631523

Symporters are membrane proteins that couple energy stored in electrochemical potential gradients to drive the cotransport of molecules and ions into cells. Traditionally, proteins are classified into gene families based on sequence homology and functional properties, for example the sodium glucose (SLC5 or Sodium Solute Symporter Family, SSS or SSF) and GABA (SLC6 or Neurotransmitter Sodium Symporter Family, NSS or SNF) symporter families [1-4]. Recently, it has been established that four Na(+)-symporter proteins with unrelated sequences have a common structural core containing an inverted repeat of 5 transmembrane (TM) helices [5(**)-8(**)]. Analysis of these four structures reveals that they reside in different conformations along the transport cycle providing atomic insight into the mechanism of sodium solute cotransport.

Keeping an Eye on Membrane Transport by TR-WAXS

Structure (London, England : 1993). Sep, 2009  |  Pubmed ID: 19748336

In this issue of Structure, Andersson et al. apply time-resolved wide angle X-ray scattering (TR-WAXS) to follow light-induced conformational changes for both bacteriorhodopsin and proteorhodopsin and probe real-time dynamics at atomic resolution.

The Electrostatics of VDAC: Implications for Selectivity and Gating

Journal of Molecular Biology. Feb, 2010  |  Pubmed ID: 20005234

The voltage-dependent anion channel (VDAC) is the major pathway mediating the transfer of metabolites and ions across the mitochondrial outer membrane. Two hallmarks of the channel in the open state are high metabolite flux and anion selectivity, while the partially closed state blocks metabolites and is cation selective. Here we report the results from electrostatics calculations carried out on the recently determined high-resolution structure of murine VDAC1 (mVDAC1). Poisson-Boltzmann calculations show that the ion transfer free energy through the channel is favorable for anions, suggesting that mVDAC1 represents the open state. This claim is buttressed by Poisson-Nernst-Planck calculations that predict a high single-channel conductance indicative of the open state and an anion selectivity of 1.75--nearly a twofold selectivity for anions over cations. These calculations were repeated on mutant channels and gave selectivity changes in accord with experimental observations. We were then able to engineer an in silico mutant channel with three point mutations that converted mVDAC1 into a channel with a preference for cations. Finally, we investigated two proposals for how the channel gates between the open and the closed state. Both models involve the movement of the N-terminal helix, but neither motion produced the observed voltage sensitivity, nor did either model result in a cation-selective channel, which is observed experimentally. Thus, we were able to rule out certain models for channel gating, but the true motion has yet to be determined.

Post-translational Modifications of Integral Membrane Proteins Resolved by Top-down Fourier Transform Mass Spectrometry with Collisionally Activated Dissociation

Molecular & Cellular Proteomics : MCP. May, 2010  |  Pubmed ID: 20093275

Integral membrane proteins remain a challenge to proteomics because they contain domains with physicochemical properties poorly suited to today's bottom-up protocols. These transmembrane regions may potentially contain post-translational modifications of functional significance, and thus development of protocols for improved coverage in these domains is important. One way to achieve this goal is by using top-down mass spectrometry whereby the intact protein is subjected to mass spectrometry and dissociation. Here we describe top-down high resolution Fourier transform mass spectrometry with collisionally activated dissociation to study post-translationally modified integral membrane proteins with polyhelix bundle and transmembrane porin motifs and molecular masses up to 35 kDa. On-line LC-MS analysis of the bacteriorhodopsin holoprotein yielded b- and y-ions that covered the full sequence of the protein and cleaved 79 of 247 peptide bonds (32%). The experiment proved that the mature sequence consists of residues 14-261, confirming N-terminal propeptide cleavage and conversion of N-terminal Gln-14 to pyrrolidone carboxylic acid (-17.02 Da) and C-terminal removal of Asp-262. Collisionally activated dissociation fragments localized the N(6)-(retinylidene) modification (266.20 Da) between residues 225-248 at Lys-229, the sole available amine in this stretch. Off-line nanospray of all eight subunits of the cytochrome b(6)f complex from the cyanobacterium Nostoc PCC 7120 defined various post-translational modifications, including covalently attached c-hemes (615.17 Da) on cytochromes f and b. Analysis of murine mitochondrial voltage-dependent anion channel established the amenability of the transmembrane beta-barrel to top-down MS and localized a modification site of the inhibitor Ro 68-3400 at Cys-232. Where neutral loss of the modification is a factor, only product ions that carry the modification should be used to assign its position. Although bond cleavage in some transmembrane alpha-helical domains was efficient, other regions were refractory such that their primary structure could only be inferred from the coincidence of genomic translation with precursor and product ions that spanned them.

Gated Access to the Pore of a P2X Receptor: Structural Implications for Closed-open Transitions

The Journal of Biological Chemistry. Mar, 2010  |  Pubmed ID: 20093367

P2X receptors are ligand-gated cation channels that transition from closed to open states upon binding ATP. The crystal structure of the closed zebrafish P2X4.1 receptor directly reveals that the ion-conducting pathway is formed by three transmembrane domain 2 (TM2) alpha-helices, each being provided by the three subunits of the trimer. However, the transitions in TM2 that accompany channel opening are incompletely understood and remain unresolved. In this study, we quantified gated access to Cd(2+) at substituted cysteines in TM2 of P2X2 receptors in the open and closed states. Our data for the closed state are consistent with the zebrafish P2X4.1 structure, with isoleucines and threonines (Ile-332 and Thr-336) positioned one helical turn apart lining the channel wall on approach to the gate. Our data for the open state reveal gated access to deeper parts of the pore (Thr-339, Val-343, Asp-349, and Leu-353), suggesting the closed channel gate is between Thr-336 and Thr-339. We also found unexpected interactions between native Cys-348 and D349C that result in tight Cd(2+) binding deep within the intracellular vestibule in the open state. Interpreted with a P2X2 receptor structural model of the closed state, our data suggest that the channel gate opens near Thr-336/Thr-339 and is accompanied by movement of the pore-lining regions, which narrow toward the cytosolic end of TM2 in the open state. Such transitions would relieve the barrier to ion flow and render the intracellular vestibule less splayed during channel opening in the presence of ATP.

Fluorescence Detection of Heavy Atom Labeling (FD-HAL): A Rapid Method for Identifying Covalently Modified Cysteine Residues by Phasing Atoms

Journal of Structural Biology. Feb, 2010  |  Pubmed ID: 20152903

Membrane protein crystallography frequently stalls at the phase determination stage due to poor crystal diffraction and the inability to identify heavy atom derivatization prior to data collection. Thus, a majority of time, effort and resources are invested preparing potential derivatized crystals for synchrotron data collection and analysis without knowledge of heavy atom labeling. To remove this uncertainty, we introduce Fluorescence Detection of Heavy Atom Labeling (FD-HAL) using tetramethylrhodamine-5-maleimide (a fluorescent maleimide compound) to monitor in-gel cysteine residue accessibility and ascertain covalent modification by mercury, platinum and gold compounds. We have tested this technique on three integral membrane proteins (LacY, vSGLT and mVDAC1) and can quickly assess the optimal concentrations, time and heavy atom compound to derivatize free cysteine residues in order to facilitate crystal phasing. This, in conjunction with cysteine scanning for incorporating heavy atoms at strategic positions, is a useful tool that will considerably assist in phasing membrane protein structures.

Bridging the Gap: a GFP-based Strategy for Overexpression and Purification of Membrane Proteins with Intra and Extracellular C-termini

Protein Science : a Publication of the Protein Society. Apr, 2010  |  Pubmed ID: 20196076

Low expression and instability during isolation are major obstacles preventing adequate structure-function characterization of membrane proteins (MPs). To increase the likelihood of generating large quantities of protein, C-terminally fused green fluorescent protein (GFP) is commonly used as a reporter for monitoring expression and evaluating purification. This technique has mainly been restricted to MPs with intracellular C-termini (C(in)) due to GFP's inability to fluoresce in the Escherichia coli periplasm. With the aid of Glycophorin A, a single transmembrane spanning protein, we developed a method to convert MPs with extracellular C-termini (C(out)) to C(in) ones providing a conduit for implementing GFP reporting. We tested this method on eleven MPs with predicted C(out) topology resulting in high level expression. For nine of the eleven MPs, a stable, monodisperse protein-detergent complex was identified using an extended fluorescence-detection size exclusion chromatography procedure that monitors protein stability over time, a critical parameter affecting the success of structure-function studies. Five MPs were successfully cleaved from the GFP tag by site-specific proteolysis and purified to homogeneity. To address the challenge of inefficient proteolysis, we explored expression and purification conditions in the absence of the fusion tag. Contrary to previous studies, optimal expression conditions established with the fusion were not directly transferable for overexpression in the absence of the GFP tag. These studies establish a broadly applicable method for GFP screening of MPs with C(out) topology, yielding sufficient protein suitable for structure-function studies and are superior to expression and purification in the absence GFP fusion tagging.

Transfer of Ion Binding Site from Ether-a-go-go to Shaker: Mg2+ Binds to Resting State to Modulate Channel Opening

The Journal of General Physiology. May, 2010  |  Pubmed ID: 20385745

In ether-à-go-go (eag) K(+) channels, extracellular divalent cations bind to the resting voltage sensor and thereby slow activation. Two eag-specific acidic residues in S2 and S3b coordinate the bound ion. Residues located at analogous positions are approximately 4 A apart in the x-ray structure of a Kv1.2/Kv2.1 chimera crystallized in the absence of a membrane potential. It is unknown whether these residues remain in proximity in Kv1 channels at negative voltages when the voltage sensor domain is in its resting conformation. To address this issue, we mutated Shaker residues I287 and F324, which correspond to the binding site residues in eag, to aspartate and recorded ionic and gating currents in the presence and absence of extracellular Mg(2+). In I287D+F324D, Mg(2+) significantly increased the delay before ionic current activation and slowed channel opening with no readily detectable effect on closing. Because the delay before Shaker opening reflects the initial phase of voltage-dependent activation, the results indicate that Mg(2+) binds to the voltage sensor in the resting conformation. Supporting this conclusion, Mg(2+) shifted the voltage dependence and slowed the kinetics of gating charge movement. Both the I287D and F324D mutations were required to modulate channel function. In contrast, E283, a highly conserved residue in S2, was not required for Mg(2+) binding. Ion binding affected activation by shielding the negatively charged side chains of I287D and F324D. These results show that the engineered divalent cation binding site in Shaker strongly resembles the naturally occurring site in eag. Our data provide a novel, short-range structural constraint for the resting conformation of the Shaker voltage sensor and are valuable for evaluating existing models for the resting state and voltage-dependent conformational changes that occur during activation. Comparing our data to the chimera x-ray structure, we conclude that residues in S2 and S3b remain in proximity throughout voltage-dependent activation.

The 3D Structures of VDAC Represent a Native Conformation

Trends in Biochemical Sciences. Sep, 2010  |  Pubmed ID: 20708406

The most abundant protein of the mitochondrial outer membrane is the voltage-dependent anion channel (VDAC), which facilitates the exchange of ions and molecules between mitochondria and cytosol and is regulated by interactions with other proteins and small molecules. VDAC has been studied extensively for more than three decades, and last year three independent investigations revealed a structure of VDAC-1 exhibiting 19 transmembrane beta-strands, constituting a unique structural class of beta-barrel membrane proteins. Here, we provide a historical perspective on VDAC research and give an overview of the experimental design used to obtain these structures. Furthermore, we validate the protein refolding approach and summarize the biochemical and biophysical evidence that links the 19-stranded structure to the native form of VDAC.

Rapid Readout Detector Captures Protein Time-resolved WAXS

Nature Methods. Oct, 2010  |  Pubmed ID: 20885435

Structures of Aminoacylase 3 in Complex with Acetylated Substrates

Proceedings of the National Academy of Sciences of the United States of America. Oct, 2010  |  Pubmed ID: 20921362

Trichloroethylene (TCE) is one of the most widespread environmental contaminants, which is metabolized to N-acetyl-S-1,2-dichlorovinyl-L-cysteine (NA-DCVC) before being excreted in the urine. Alternatively, NA-DCVC can be deacetylated by aminoacylase 3 (AA3), an enzyme that is highly expressed in the kidney, liver, and brain. NA-DCVC deacetylation initiates the transformation into toxic products that ultimately causes acute renal failure. AA3 inhibition is therefore a target of interest to prevent TCE induced nephrotoxicity. Here we report the crystal structure of recombinant mouse AA3 (mAA3) in the presence of its acetate byproduct and two substrates: N(α)-acetyl-L-tyrosine and NA-DCVC. These structures, in conjunction with biochemical data, indicated that AA3 mediates substrate specificity through van der Waals interactions providing a dynamic interaction interface, which facilitates a diverse range of substrates.

Water Permeation Through the Sodium-dependent Galactose Cotransporter VSGLT

Biophysical Journal. Oct, 2010  |  Pubmed ID: 20923633

It is well accepted that cotransporters facilitate water movement by two independent mechanisms: osmotic flow through a water channel in the protein and flow driven by ion/substrate cotransport. However, the molecular mechanism of transport-linked water flow is controversial. Some researchers believe that it occurs via cotransport, in which water is pumped along with the transported cargo, while others believe that flow is osmotic in response to an increase in intracellular osmolarity. In this letter, we report the results of a 200-ns molecular dynamics simulation of the sodium-dependent galactose cotransporter vSGLT. Our simulation shows that a significant number of water molecules cross the protein through the sugar-binding site in the presence as well as the absence of galactose, and 70-80 water molecules accompany galactose as it moves from the binding site into the intracellular space. During this event, the majority of water molecules in the pathway are unable to diffuse around the galactose, resulting in water in the inner half of the transporter being pushed into the intracellular space and replaced by extracellular water. Thus, our simulation supports the notion that cotransporters act as both passive water channels and active water pumps with the transported substrate acting as a piston to rectify the motion of water.

The Mechanism of Sodium and Substrate Release from the Binding Pocket of VSGLT

Nature. Dec, 2010  |  Pubmed ID: 21131949

Membrane co-transport proteins that use a five-helix inverted repeat motif have recently emerged as one of the largest structural classes of secondary active transporters. However, despite many structural advances there is no clear evidence of how ion and substrate transport are coupled. Here we report a comprehensive study of the sodium/galactose transporter from Vibrio parahaemolyticus (vSGLT), consisting of molecular dynamics simulations, biochemical characterization and a new crystal structure of the inward-open conformation at a resolution of 2.7 Å. Our data show that sodium exit causes a reorientation of transmembrane helix 1 that opens an inner gate required for substrate exit, and also triggers minor rigid-body movements in two sets of transmembrane helical bundles. This cascade of events, initiated by sodium release, ensures proper timing of ion and substrate release. Once set in motion, these molecular changes weaken substrate binding to the transporter and allow galactose readily to enter the intracellular space. Additionally, we identify an allosteric pathway between the sodium-binding sites, the unwound portion of transmembrane helix 1 and the substrate-binding site that is essential in the coupling of co-transport.

Crystal Structure of Lactose Permease in Complex with an Affinity Inactivator Yields Unique Insight into Sugar Recognition

Proceedings of the National Academy of Sciences of the United States of America. Jun, 2011  |  Pubmed ID: 21593407

Lactose permease of Escherichia coli (LacY) with a single-Cys residue in place of A122 (helix IV) transports galactopyranosides and is specifically inactivated by methanethiosulfonyl-galactopyranosides (MTS-gal), which behave as unique suicide substrates. In order to study the mechanism of inactivation more precisely, we solved the structure of single-Cys122 LacY in complex with covalently bound MTS-gal. This structure exhibits an inward-facing conformation similar to that observed previously with a slight narrowing of the cytoplasmic cavity. MTS-gal is bound covalently, forming a disulfide bond with C122 and positioned between R144 and W151. E269, a residue essential for binding, coordinates the C-4 hydroxyl of the galactopyranoside moiety. The location of the sugar is in accord with many biochemical studies.

Bridging the Gap Between Structure and Kinetics of Human SGLT1

American Journal of Physiology. Cell Physiology. Dec, 2011  |  Pubmed ID: 22159082

The Na(+) glucose cotransporter hSGLT1 is a member of a class of membrane proteins that harness Na(+) electrochemical gradients to drive uphill solute transport. While hSGLT1 belongs to one gene family (SLC5), recent structural studies of bacterial Na(+) cotransporters show that Na(+ )transporters in different gene families have the same structural fold. We have constructed homology models of hSGLT1 in two conformations, the inward facing occluded (based on vSGLT), and the outward open (based on Mhp1) conformations, mutated in turn each of the conserved gates and ligand binding residues, expressed the SGLT1 mutants in Xenopus oocytes, and determined the functional consequences using biophysical and biochemical assays. The results establish that mutating the ligand binding residues produce profound changes in the ligand affinity (the half-saturation concentration ,K(0.5)), e.g. mutating sugar binding residues increases the glucose K(0.5) by up to 3-orders of magnitude. Mutation of the external gate residues increases the Na(+) to sugar transport stoichiometry, demonstrating that these residues are critical for efficient cotransport. The changes in phlorizin inhibition constant (K(i)) are proportional to the changes in sugar K(0.5), except in the case of F101C where phlorizin K(i) increases by orders of magnitude without a change in glucose K(0.5). We conclude that glucose and phlorizin occupy the same binding site and that F101 is involved in binding to the phloretin group of the inhibitor. SCAM experiments show that the cysteine residues at the position of the gates and sugar binding site are largely accessible only to external hydrophilic MTS reagents in the presence of external Na(+), demonstrating that the external sugar (and phlorizin) binding vestibule is opened by the presence of external Na(+) and closes after the binding of sugar and phlorizin. Overall, the present results provide a bridge between kinetics and structural studies of cotransporters.

Affixing the N-terminal Alpha Helix of the Voltage Dependent Anion Channel to the Channel's Wall Does Not Prevent Its Voltage Gating

The Journal of Biological Chemistry. Jan, 2012  |  Pubmed ID: 22275367

The Voltage Dependent Anion Channel (VDAC) governs the free exchange of ions and metabolites between the mitochondria and the rest of the cell. The 3D structure of VDAC1 reveals a channel formed by 19 β-strands and an N-terminal α-helix located near the midpoint of the pore. The position of this α-helix causes a narrowing of the cavity but ample space for metabolite passage remains. The participation of the N-terminus of VDAC1 in the voltage-gating process has been well established but the molecular mechanism remains debated; yet, the majority of models entail large conformational changes of this N-terminal segment. Here we report that the pore-lining N-terminal α-helix does not undergo independent structural rearrangements during channel gating. We engineered a double Cys mutant in murine VDAC1 (mVDAC1) that cross links the α-helix to the wall of the β-barrel pore and reconstituted the modified protein into planar lipid bilayers. The modified mVDAC1 exhibited typical voltage gating. These results suggest that the N-terminal α-helix is located inside the pore of VDAC in the open state and remains associated with β-strand 11 of the pore wall during voltage gating.

Characterization and Purification of a Na+/Ca2+ Exchanger from an Archaebacterium

The Journal of Biological Chemistry. Jan, 2012  |  Pubmed ID: 22287543

The superfamily of cation/Ca2+ exchangers includes both Na+/Ca2+ exchangers (NCX) and Na+/Ca2+,K+ exchangers (NCKX) as the families characterized in most detail. These Ca2+ transporters have prominent physiological roles. For example, NCX and NCKX are important in regulation of cardiac contractility and visual processes, respectively. The superfamily also has a large number of members of a YrbG family expressed in prokaryotes. However, no members of this family have been functionally expressed and their transport properties are unknown. We have expressed, purified, and characterized a member of the YrbG family, MaX1 from Methanosarcinia acetivorans. MaX1 catalyzes Ca2+ uptake into membrane vesicles. The Ca2+ uptake requires intravesicular Na+ and is stimulated by an inside positive membrane potential. Despite very limited sequence similarity, MaX1 is a Na+/Ca2+ exchanger with kinetic properties similar to NCX. The availability of a prokaryotic Na+/Ca2+ exchanger should facilitate structural and mechanistic investigations.

Structural Biology. It's All in the Symmetry

Science (New York, N.Y.). Feb, 2012  |  Pubmed ID: 22323810