Toward the fourth dimension of membrane protein structure: insight into dynamics from spin-labeling EPR spectroscopy

Trapping membrane proteins in the confines of a crystal lattice obscures dynamic modes essential for interconversion between multiple conformations in the functional cycle. Moreover, lattice forces could conspire with detergent solubilization to stabilize a minor conformer in an ensemble thus confounding mechanistic interpretation. Spin labeling in conjunction with electron paramagnetic resonance (EPR) spectroscopy offers an exquisite window into membrane protein dynamics in the native-like environment of a lipid bilayer. Systematic application of spin labeling and EPR identifies sequence-specific secondary structures, defines their topology and their packing in the tertiary fold. Long range distance measurements (60 ?-80 ?) between pairs of spin labels enable quantitative analysis of equilibrium dynamics and triggered conformational changes. This review highlights the contribution of spin labeling to bridging structure and mechanism. Efforts to develop methods for determining structures from EPR restraints and to increase sensitivity and throughput promise to expand spin labeling applications in membrane protein structural biology.     

Identifying conformational changes with site-directed spin labeling

Site-direct spin labeling combined with electron paramagnetic resonance (EPR) spectroscopy is a powerful tool for detecting structural changes in proteins. This review provides examples that illustrate strategies for interpreting the data in terms of specific rearrangements in secondary and tertiary structure. The changes in the mobility and solvent accessibility of the spin label side chains, and in the distances between spin labels, report (i) rigid body motions of alpha-helices and beta-strands (ii) relative movements of domains and (iii) changes in secondary structure. Such events can be monitored in the millisecond time-scale, making it possible to follow structural changes during function. There is no upper limit to the size of proteins that can be investigated, and only 50-100 picomoles of protein are required. These features make site-directed spin labeling an attractive approach for the study of structure and dynamics in a wide range of systems.     

De novo high-resolution protein structure determination from sparse spin-labeling EPR data

As many key proteins evade crystallization and remain too large for nuclear magnetic resonance spectroscopy, electron paramagnetic resonance (EPR) spectroscopy combined with site-directed spin labeling offers an alternative approach for obtaining structural information. Such information must be translated into geometric restraints to be used in computer simulations. Here, distances between spin labels are converted into distance ranges between beta carbons by using a "motion-on-a-cone" model, and a linear-correlation model links spin-label accessibility to the number of neighboring residues. This approach was tested on T4-lysozyme and alphaA-crystallin with the de novo structure prediction algorithm Rosetta. The results demonstrate the feasibility of obtaining highly accurate, atomic-detail models from EPR data by yielding 1.0 A and 2.6 A full-atom models, respectively. Distance restraints between amino acids far apart in sequence but close in space are most valuable for structure determination. The approach can be extended to other experimental techniques such as fluorescence spectroscopy, substituted cysteine accessibility method, or mutational studies.     

Structural aspects of thiol-specific spin labeling of human plasma low density lipoprotein

A novel thiol-specific spin labeling procedure for the protein component (apoprotein B, apoB) of low density lipoproteins (LDLs) is presented. A methanethiosulfonate spin label was used to probe the free cysteine residues of apoB with electron paramagnetic resonance (EPR) spectroscopy. The results indicated that the spin labeled sites are predominantly buried in the LDL particle in two distinct environments that differ in their mobility restrictions. The suitability of thiol-specific labeling for the study of the stability and conformation of apoB was demonstrated in experiments with denaturing agents. The results presented in this work offer a new approach for the matching of EPR data with the primary structure of apoB.     

The determinants of the oligomeric structure in Hsp16.5 are encoded in the alpha-crystallin domain

The determinants of the oligomeric assembly of Hsp16.5, a small heat-shock protein (sHSP) from Methanococcus jannaschii, were explored via site-directed truncation and site-directed spin labeling. For this purpose, subunit contacts around the two-, three- and four-fold symmetry axes were fingerprinted using patterns of proximities between nitroxide spin labels introduced at selected sites. The lack of change in this fingerprint in an N-terminal truncation of the protein demonstrates that the interactions are encoded in the alpha-crystallin domain. In contrast, the truncation of the N-terminal domain of Mycobacterium tuberculosis Hsp16.3, a bacterial sHSP with an equally short N-terminal region, results in the dissociation of the oligomer to a trimer. These results, in conjunction with those from previous truncation studies in mammalian sHSP, suggest that as the alpha-crystallin domain evolved to encode a smaller basic unit than the overall oligomer, the control of the assembly and dynamics of the oligomeric structure became encoded in the N-terminal domain.     

Inter- and intra-molecular distances determined by EPR spectroscopy and site-directed spin labeling reveal protein-protein and protein-oligonucleotide interaction

Recent developments including pulse and multi-frequency techniques make the combination of site-directed spin labeling and electron paramagnetic resonance (EPR) spectroscopy an attractive approach for the study of protein-protein or protein-oligonucleotide interaction. Analysis of the spin label side chain mobility, its solvent accessibility, the polarity of the spin label micro-environment and distances between spin label side chains allow the modeling of protein domains or protein-protein interaction sites and their conformational changes with a spatial resolution at the level of the backbone fold. Structural changes can be detected with millisecond time resolution. Inter- and intra-molecular distances are accessible in the range from approximately 0.5 to 8 nm by the combination of continuous wave and pulse EPR methods. Recent applications include the study of transmembrane substrate transport, membrane channel gating, gene regulation and signal transfer.     

Cryoelectron microscopy and EPR analysis of engineered symmetric and polydisperse Hsp16.5 assemblies reveals determinants of polydispersity and substrate binding

We have identified sequence and structural determinants of oligomer size, symmetry, and polydispersity in the small heat shock protein super family. Using an insertion mutagenesis strategy that mimics evolutionary sequence divergence, we induced the ordered oligomer of Methanococcus jannaschii Hsp16.5 to transition to either expanded symmetric or polydisperse assemblies. A hybrid approach combining spin labeling EPR and cryoelectron microscopy imaging at 10A resolution reveals that the underlying plasticity is mediated by a packing interface with minimal contacts and a flexible C-terminal tether between dimers. Twenty-four dimeric building blocks related by octahedral symmetry assemble into the expanded symmetric oligomer. In contrast, the polydisperse variant has an ordered dimeric building block that heterogeneously packs to yield oligomers of various sizes. Increased exposure of the N-terminal region in the Hsp16.5 variants correlates with enhanced binding to destabilized mutants of T4 lysozyme, whereas deletion of this region reduces binding. Transition to larger intermediates with enhanced substrate binding capacity has been observed in other small heat shock proteins including lens alpha-crystallin mutants linked to congenital cataract. Together, these results provide a mechanistic perspective on substrate recognition and binding by the small heat shock protein superfamily.     

Describing the structure and assembly of protein filaments by EPR spectroscopy of spin-labeled side chains

In this review we summarize our approach to the study of Intermediate Filament (IF) structure and assembly by electron paramagnetic resonance (EPR) spectroscopy of site-directed spin labels. Using vimentin, a homopolymeric type III IF protein, we demonstrate that this approach serves as a general paradigm for studying protein filament structure and assembly. These strategies will be useful in exploring the structure and assembly properties of other filamentous or aggregation-prone systems.     

Comparing the structural dynamics of the human KCNE3 in reconstituted micelle and lipid bilayered vesicle environments

KCNE3 is a single transmembrane protein of the KCNE family that modulates the function and trafficking of several voltage-gated potassium channels, including KCNQ1. Structural studies of KCNE3 have been previously conducted in a wide range of model membrane mimics. However, it is important to assess the impact of the membrane mimics used on the observed conformation and dynamics. In this study, we have optimized a method for the reconstitution of the KCNE3 into POPC/POPG lipid bilayer vesicles for electron paramagnetic resonance (EPR) spectroscopy. Our CD spectroscopic data suggested that the degree of regular secondary structure for KCNE3 protein reconstituted into lipid bilayered vesicle is significantly higher than in DPC detergent micelles. Electron paramagnetic resonance (EPR) spectroscopy in combination with site-directed spin labeling (SDSL) was used to probe the structural dynamics of S49C, M59C, L67C, V85C, and S101C mutations of KCNE3 in both DPC micelles and in POPC/POPG lipid bilayered vesicles. Our CW-EPR power saturation data suggested that the site S74C is buried inside the lipid bilayered membrane while the site V85C is located outside the membrane, in contrast to DPC micelle results. These results suggest that the KCNE3 micelle structures need to be refined using data obtained in the lipid bilayered vesicles in order to ascertain the native structure of KCNE3. This work will provide guidelines for detailed structural studies of KCNE3 in a more native membrane environment and comparing the lipid bilayer results to the isotropic bicelle structure and to the KCNQ1-bound cryo-EM structure.     

Structural origins of nitroxide side chain dynamics on membrane protein α-helical sites

Understanding the structure and dynamics of membrane proteins in their native, hydrophobic environment is important to understanding how these proteins function. EPR spectroscopy in combination with site-directed spin labeling (SDSL) can measure dynamics and structure of membrane proteins in their native lipid environment; however, until now the dynamics measured have been qualitative due to limited knowledge of the nitroxide spin label's intramolecular motion in the hydrophobic environment. Although several studies have elucidated the structural origins of EPR line shapes of water-soluble proteins, EPR spectra of nitroxide spin-labeled proteins in detergents or lipids have characteristic differences from their water-soluble counterparts, suggesting significant differences in the underlying molecular motion of the spin label between the two environments. To elucidate these differences, membrane-exposed α-helical sites of the leucine transporter, LeuT, from Aquifex aeolicus, were investigated using X-ray crystallography, mutational analysis, nitroxide side chain derivatives, and spectral simulations in order to obtain a motional model of the nitroxide. For each crystal structure, the nitroxide ring of a disulfide-linked spin label side chain (R1) is resolved and makes contacts with hydrophobic residues on the protein surface. The spin label at site I204 on LeuT makes a nontraditional hydrogen bond with the ortho-hydrogen on its nearest neighbor F208, whereas the spin label at site F177 makes multiple van der Waals contacts with a hydrophobic pocket formed with an adjacent helix. These results coupled with the spectral effect of mutating the i ± 3, 4 residues suggest that the spin label has a greater affinity for its local protein environment in the low dielectric than on a water-soluble protein surface. The simulations of the EPR spectra presented here suggest the spin label oscillates about the terminal bond nearest the ring while maintaining weak contact with the protein surface. Combined, the results provide a starting point for determining a motional model for R1 on membrane proteins, allowing quantification of nitroxide dynamics in the aliphatic environment of detergent and lipids. In addition, initial contributions to a rotamer library of R1 on membrane proteins are provided, which will assist in reliably modeling the R1 conformational space for pulsed dipolar EPR and NMR paramagnetic relaxation enhancement distance determination.     

电子顺磁共振测量蛋白质分子内选定位点之间距离的方法及应用

蛋白质分子的结构决定了其特性和功能,准确测量蛋白质分子中特殊位点之间的距离对其结构解析至关重要。该文在简要介绍电子顺磁共振(electron paramagnetic resonance,EPR)方法测量蛋白质分子内未偶自旋之间距离基本原理的基础上,重点综述了近年来EPR结合定点自旋标记(site-directed spin label,SDSL)技术在研究蛋白质结构与功能方面的应用情况,归纳了EPR-SDSL方法测量距离的特点和存在问题,并提出了改进用连续波EPR技术测量距离的准确度的思路和实现方法。     

Conformational changes of the betaine transporter BetP from Corynebacterium glutamicum studied by pulse EPR spectroscopy

The betaine transporter BetP from Corynebacterium glutamicum is activated by hyperosmotic stress critically depending on the presence and integrity of its sensory C-terminal domain. The conformational properties of the trimeric BetP reconstituted in liposomes in the inactive state and during osmotic activation were investigated by site-directed spin labeling and electron paramagnetic resonance (EPR) spectroscopy. Comparison of intra- and intermolecular inter spin distance distributions obtained by double electron-electron resonance (DEER) EPR with the crystal structure of BetP by means of a rotamer library analysis suggest a rotation of BetP protomers within the trimer by about 15° as compared to the X-ray structure. Furthermore, we observed conformational changes upon activation of BetP, which are reflected in changes of the distances between positions 545 and 589 of different protomers in the trimer. Introduction of proline at positions 550 and 572, both leading to BetP variants with a permanent (low level) transport activity, caused changes of the DEER data similar to those observed for the activated and inactivated state, respectively. This indicates that not only displacements of the C-terminal domain in general but also concomitant interactions of its primary structure with surrounding protein domains and/or lipids are crucial for the activity regulation of BetP.     

Protein structural dynamics revealed by site-directed spin labeling and multifrequency EPR

Multifrequency electron paramagnetic resonance (EPR), combined with site-directed spin labeling, is a powerful spectroscopic tool to characterize protein dynamics. The lineshape of an EPR spectrum reflects combined rotational dynamics of the spin probe's local motion within a protein, reorientations of protein domains, and overall protein tumbling. All these motions can be restricted and anisotropic, and separation of these motions is important for thorough characterization of protein dynamics. Multifrequency EPR distinguishes between different motions of a spin-labeled protein, due to the frequency dependence of EPR resolution to fast and slow motion of a spin probe. This gives multifrequency EPR its unique capability to characterize protein dynamics in great detail. In this review, we analyze what makes multifrequency EPR sensitive to different rates of spin probe motion and discuss several examples of its usage to separate spin probe dynamics and overall protein dynamics, to characterize protein backbone dynamics, and to resolve protein conformational states.     

Probing iso-1-cytochrome c structure by site-directed spin labeling and electron paramagnetic resonance techniques

A cysteine-specific methanethiosulfonate spin label was introduced into yeast iso-1-cytochrome c at three different positions. The modified forms of cytochrome c included: the wild-type protein labeled at naturally occurring C102, and two mutated proteins, S47C and L85C, labeled at positions 47 and 85, respectively (both S47C and L85C derived from the protein in which C102 had been replaced by threonine). All three spin-labeled protein derivatives were characterized using electron paramagnetic resonance (EPR) techniques. The continuous wave (CW) EPR spectrum of spin label attached to L85C differed from those recorded for spin label attached to C102 or S47C, indicating that spin label at position 85 was more immobilized and exhibited more complex tumbling than spin label at two other positions. The temperature dependence of the CW EPR spectra and CW EPR power saturation revealed further differences of spin-labeled L85C. The results were discussed in terms of application of the site-directed spin labeling technique in probing the local dynamic structure of iso-1-cytochrome c.     

Resting state conformation of the MsbA homodimer as studied by site-directed spin labeling

MsbA is the ABC transporter for lipid A and is found in the inner membranes of Gram-negative bacteria such as Escherichia coli. Without MsbA present, bacterial cells accumulate a toxic amount of lipid A within their inner membranes. A crystal structure of MsbA was recently obtained that provides an excellent starting point for functional dynamics studies in membranes [Chang, and Roth (2001) Science 293, 1793-1800]. Although a structure of MsbA is now available, many questions remain concerning its mechanism of transport. Site-directed spin labeling (SDSL) electron paramagnetic resonance (EPR) spectroscopy is a powerful approach for characterizing local areas within a large protein structure in addition to detecting and following changes in local structure due to dynamic interactions within a protein. The quaternary structure of the resting state of the MsbA homodimer reconstituted into lipid membranes has been evaluated by SDSL EPR spectroscopy and chemical cross-linking techniques. SDSL and cross-linking results are consistent with the controversial resting state conformation of the MsbA homodimer found in the crystal structure, with the tips of the transmembrane helices forming a dimer interface. The position of MsbA in the membrane bilayer along with the relative orientation of the transmembrane helical bundles with respect to one another has been determined. Characterization of the resting state of the MsbA homodimer is essential for future studies on the functional dynamics of this membrane transporter.     

Substrate-induced conformational changes of the periplasmic N-terminus of an outer-membrane transporter by site-directed spin labeling

The structure and dynamics of the N-terminal and core regions of BtuB, an outer membrane vitamin B(12) transporter from Escherichia coli, were investigated by site-directed spin labeling. Cysteine mutants were generated by site-directed mutagenesis to place spin labels in the N-terminal region (residues 1-17), the core region (residues 25-30), and double labels into the Ton box (residues 6-12). BtuB mutants were expressed, spin labeled, purified, and reconstituted into phosphatidylcholine. In the presence of substrate (vitamin B(12)), EPR spectroscopy demonstrates that there is a conformational change in the Ton box similar to that seen previously for BtuB in intact outer membranes. The Ton box is positioned within the beta-barrel of BtuB in the absence of substrate (docked configuration) but becomes unfolded and increases its aqueous exposure upon substrate binding (undocked configuration). This conformational change and the similarity in the EPR spectra between reconstituted and native membranes indicate that BtuB is correctly folded and functional in the reconstituted system. The protein segment on the N-terminal side of the Ton box is highly mobile, and it becomes more mobile in the presence of substrate. Side chains in the region C-terminal to the Ton box also show increases in mobility with substrate addition, but position 16 appears to define a hinge point for this conformation change. EPR line shapes and relaxation data indicate that residues 25-30 form a beta-strand structure, which is analogous to the first beta-strand in the cores of the homologous iron transporters. When substrate binds to BtuB, this first beta-strand remains folded. The EPR spectra of double-nitroxide labels within the Ton box are broadened because of dipolar and collisional exchange interactions. The broadening pattern indicates that the Ton box is not helical but is in an extended or beta-strand structure.     

Probing the local secondary structure of bacteriophage S21 pinholin membrane protein using electron spin echo envelope modulation spectroscopy

There have recently been advances in methods for detecting local secondary structures of membrane protein using electron paramagnetic resonance (EPR). A three pulsed electron spin echo envelope modulation (ESEEM) approach was used to determine the local helical secondary structure of the small hole forming membrane protein, S²¹ pinholin. This ESEEM approach uses a combination of site-directed spin labeling and ²H-labeled side chains. Pinholin S²¹ is responsible for the permeabilization of the inner cytosolic membrane of double stranded DNA bacteriophage host cells. In this study, we report on the overall global helical structure using circular dichroism (CD) spectroscopy for the active form and the negative-dominant inactive mutant form of S²¹ pinholin. The local helical secondary structure was confirmed for both transmembrane domains (TMDs) for the active and inactive S²¹ pinholin using the ESEEM spectroscopic technique. Comparison of the ESEEM normalized frequency domain intensity for each transmembrane domain gives an insight into the α-helical folding nature of these domains as opposed to a π or 3₁₀-helix which have been observed in other channel forming proteins.     

Characterization of the Walker A motif of MsbA using site-directed spin labeling electron paramagnetic resonance spectroscopy

MsbA is an ABC transporter that transports lipid A across the inner membrane of Gram-negative bacteria such as Escherichia coli. Without functional MsbA present, bacterial cells accumulate a toxic amount of lipid A within their inner membranes. A crystal structure of MsbA was recently obtained that provides an excellent starting point for functional dynamics studies in membranes [Chang and Roth (2001) Science 293, 1793-1800]. Although a structure of MsbA is now available, several functionally important motifs common to ABC transporters are unresolved in the crystal structure. The Walker A domain, one of the ABC transporter consensus motifs that is directly involved in ATP binding, is located within a large unresolved region of the MsbA ATPase domain. Site-directed spin labeling (SDSL) electron paramagnetic resonance (EPR) spectroscopy is a powerful technique for characterizing local areas within a large protein structure in addition to detecting and following changes in local structure due to dynamic interactions. MsbA reconstituted into lipid membranes has been evaluated by EPR spectroscopy, and it has been determined that the Walker A domain forms an alpha-helical structure, which is consistent with the structure of this motif observed in other crystallized ABC transporters. In addition, the interaction of the Walker A residues with ATP before, during, and after hydrolysis was followed using SDSL EPR spectroscopy in order to identify the residues directly involved in substrate binding and hydrolysis.     

Small heat-shock protein structures reveal a continuum from symmetric to variable assemblies

The small heat-shock proteins (sHSPs) form a diverse family of proteins that are produced in all organisms. They function as chaperone-like proteins in that they bind unfolded polypeptides and prevent uncontrolled protein aggregation. Here, we present parallel cryo-electron microscopy studies of five different sHSP assemblies: Methanococcus jannaschii HSP16.5, human alphaB-crystallin, human HSP27, bovine native alpha-crystallin, and the complex of alphaB-crystallin and unfolded alpha-lactalbumin. Gel-filtration chromatography indicated that HSP16.5 is the most monodisperse, while HSP27 and the alpha-crystallin assemblies are more polydisperse. Particle images revealed a similar trend showing mostly regular and symmetric assemblies for HSP16.5 particles and the most irregular assemblies with a wide range of diameters for HSP27. A symmetry test on the particle images indicated stronger octahedral symmetry for HSP16.5 than for HSP27 or the alpha-crystallin assemblies. A single particle reconstruction of HSP16.5, based on 5772 particle images with imposed octahedral symmetry, resulted in a structure that closely matched the crystal structure. In addition, the cryo-EM reconstruction revealed internal density presumably corresponding to the flexible 32 N-terminal residues that were not observed in the crystal structure. The N termini were found to partially fill the central cavity making it unlikely that HSP16.5 sequesters denatured proteins in the cavity. A reconstruction calculated without imposed symmetry confirmed the presence of at least loose octahedral symmetry for HSP16.5 in contrast to the other sHSPs examined, which displayed no clear overall symmetry. Asymmetric reconstructions for the alpha-crystallin assemblies, with an additional mass selection step during image processing, resulted in lower resolution structures. We interpret the alpha-crystallin reconstructions to be average representations of variable assemblies and suggest that the resolutions achieved indicate the degree of variability. Quaternary structural information derived from cryo-electron microscopy is related to recent EPR studies of the alpha-crystallin domain fold and dimer interface of alphaA-crystallin.