Helical structure of phospholamban in membrane bilayers

Perturbations of Native Membrane Protein Structure in Alkyl Phosphocholine Detergents: A Critical Assessment of NMR and Biophysical Studies

Membrane proteins perform a host of vital cellular functions. Deciphering the molecular mechanisms whereby they fulfill these functions requires detailed biophysical and structural investigations. Detergents have proven pivotal to extract the protein from its native surroundings. Yet, they provide a milieu that departs significantly from that of the biological membrane, to the extent that the structure, the dynamics, and the interactions of membrane proteins in detergents may considerably vary, as compared to the native environment. Understanding the impact of detergents on membrane proteins is, therefore, crucial to assess the biological relevance of results obtained in detergents. Here, we review the strengths and weaknesses of alkyl phosphocholines (or foscholines), the most widely used detergent in solution-NMR studies of membrane proteins. While this class of detergents is often successful for membrane protein solubilization, a growing list of examples points to destabilizing and denaturing properties, in particular for α-helical membrane proteins. Our comprehensive analysis stresses the importance of stringent controls when working with this class of detergents and when analyzing the structure and dynamics of membrane proteins in alkyl phosphocholine detergents.

Solid-state NMR methods for oriented membrane proteins

Oriented-sample solid-state NMR represents one of few experimental methods capable of characterising the membrane-bound conformation of proteins in the cell membrane. Since the technique was developed 25 years ago, the technique has been applied to study the structure of helix bundle membrane proteins and antimicrobial peptides, characterise protein-lipid interactions, and derive information on dynamics of the membrane anchoring of membrane proteins. We will review the major developments in various aspects of oriented-sample solid-state NMR, including sample-preparation methods, pulse sequences, theory required to interpret the experiments, perspectives for and guidelines to new experiments, and a number of representative applications.

Topology and immersion depth of an integral membrane protein by paramagnetic rates from dissolved oxygen

In studies of membrane proteins, knowledge of protein topology can provide useful insight into both structure and function. In this work, we present a solution NMR method for the measurement the tilt angle and average immersion depth of alpha helices in membrane proteins, from analysis of the paramagnetic relaxation rate enhancements arising from dissolved oxygen. No modification to the micelle or protein is necessary, and the topology of both transmembrane and amphipathic helices are readily determined. We apply this method to the measure the topology of a monomeric mutant of phospholamban (AFA-PLN), a 52-residue membrane protein containing both an amphipathic and a transmembrane alpha helix. In dodecylphosphocholine micelles, the amphipathic helix of AFA-PLN was found to have a tilt angle of 87° ± 1° and an average immersion depth of 13.2 Å. The transmembrane helix was found to have an average immersion depth of 5.4 Å, indicating residues 41 and 42 are closest to the micelle centre. The resolution of paramagnetic relaxation rate enhancements from dissolved oxygen compares favourably to those from Ni (II), a hydrophilic paramagnetic species.

Frequency-selective heteronuclear dephasing and selective carbonyl labeling to deconvolute crowded spectra of membrane proteins by magic angle spinning NMR

We present a new method that combines carbonyl-selective labeling with frequency-selective heteronuclear recoupling to resolve the spectral overlap of magic angle spinning (MAS) NMR spectra of membrane proteins in fluid lipid membranes with broad lines and high redundancy in the primary sequence. We implemented this approach in both heteronuclear (15)N-(13)C(α) and homonuclear (13)C-(13)C dipolar assisted rotational resonance (DARR) correlation experiments. We demonstrate its efficacy for the membrane protein phospholamban reconstituted in fluid PC/PE/PA lipid bilayers. The main advantage of this method is to discriminate overlapped (13)C(α) resonances by strategically labeling the preceding residue. This method is highly complementary to (13)C(i-1)(')-(15)N(i)-(13)C(i)(α) and (13)C(i-1)(α)-(15)N(i-1)-(13)C(i)(') experiments to distinguish inter-residue spin systems at a minimal cost to signal-to-noise.

On the function of pentameric phospholamban: ion channel or storage form?

Phospholamban (PLN) is an integral membrane protein that inhibits the sarcoplasmic reticulum Ca(2+)-ATPase, thereby regulating muscle contractility. We report a combined electrochemical and theoretical study demonstrating that the pentameric PLN does not possess channel activity for conducting chloride or calcium ions across the lipid membrane. This suggests that the pentameric configuration of PLN primarily serves as a storage form for the regulatory function of muscle relaxation by the PLN monomer.

Cytoplasmic residues of phospholamban interact with membrane surfaces in the presence of SERCA: a new role for phospholipids in the regulation of cardiac calcium cycling?

The 52-amino acid transmembrane protein phospholamban (PLB) regulates calcium cycling in cardiac cells by forming a complex with the sarco(endo)plasmic reticulum calcium ATPase (SERCA) and reversibly diminishing the rate of calcium uptake by the sarcoplasmic reticulum. The N-terminal cytoplasmic domain of PLB interacts with the cytoplasmic domain of SERCA, but, in the absence of the enzyme, can also associate with the surface of anionic phospholipid membranes. This work investigates whether the cytoplasmic domain of PLB can also associate with membrane surfaces in the presence of SERCA, and whether such interactions could influence the regulation of the enzyme. It is shown using solid-state NMR and isothermal titration calorimetry (ITC) that an N-terminally acetylated peptide representing the first 23 N-terminal amino acids of PLB (PLB1-23) interacts with membranes composed of zwitterionic phosphatidylcholine (PC) and anionic phosphatidylglycerol (PG) lipids in the absence and presence of SERCA. Functional measurements of SERCA in sarcoplasmic reticulum (SR) vesicles, planar SR membranes and reconstituted into PC/PG membranes indicate that PLB1-23 lowers the maximal rate of ATP hydrolysis by acting at the cytoplasmic face of the enzyme. A small, but statistically significant, reduction in the inhibitory effect of the peptide is observed for SERCA reconstituted into PC/PG membranes compared to SERCA in membranes of PC alone. It is suggested that interactions between the cytoplasmic domain of PLB and negatively charged phospholipids might play a role in moderating the regulation of SERCA, with implications for cardiac muscle contractility.

Phosphomimetic mutations increase phospholamban oligomerization and alter the structure of its regulatory complex

To investigate the effect of phosphorylation on the interactions of phospholamban (PLB) with itself and its regulatory target, SERCA, we measured FRET from CFP-SERCA or CFP-PLB to YFP-PLB in live AAV-293 cells. Phosphorylation of PLB was mimicked by mutations S16E (PKA site) or S16E/T17E (PKA+CaMKII sites). FRET increased with protein concentration up to a maximum (FRET(max)) that was taken to represent the intrinsic FRET of the bound complex. The concentration dependence of FRET yielded dissociation constants (K(D)) for the PLB-PLB and PLB-SERCA interactions. PLB-PLB FRET data suggest pseudo-phosphorylation of PLB increased oligomerization of PLB but did not alter PLB pentamer quaternary structure. PLB-SERCA FRET experiments showed an apparent decrease in binding of PLB to SERCA and an increase in the apparent PLB-SERCA binding cooperativity. It is likely that these changes are secondary effects of increased oligomerization of PLB; a change in the inherent affinity of monomeric PLB for SERCA was not detected. In addition, PLB-SERCA complex FRET(max) was reduced by phosphomimetic mutations, suggesting the conformation of the regulatory complex is significantly altered by PLB phosphorylation.

Structural characterization of Ca(2+)-ATPase-bound phospholamban in lipid bilayers by solid-state nuclear magnetic resonance (NMR) spectroscopy

Phospholamban (PLN) regulates cardiac contractility by modulation of sarco(endo)plasmic reticulum calcium ATPase (SERCA) activity. While PLN and SERCA1a, an isoform from skeletal muscle, have been structurally characterized in great detail, direct information about the conformation of PLN in complex with SERCA has been limited. We used solid-state NMR (ssNMR) spectroscopy to deduce structural properties of both the A 36F 41A 46 mutant (AFA-PLN) and wild-type PLN (WT-PLN) when bound to SERCA1a after reconstitution in a functional lipid bilayer environment. Chemical-shift assignments in all domains of AFA-PLN provide direct evidence for the presence of two terminal alpha helices connected by a linker region of reduced structural order that differs from previous findings on free PLN. ssNMR experiments on WT-PLN show no significant difference in binding compared to AFA-PLN and do not support the coexistence of a significantly populated dynamic state of PLN after formation of the PLN/SERCA complex. A combination of our spectroscopic data with biophysical and biochemical data using flexible protein-protein docking simulations provides a structural basis for understanding the interaction between PLN and SERCA1a.

Structural and dynamic basis of phospholamban and sarcolipin inhibition of Ca(2+)-ATPase

Phospholamban (PLN) and sarcolipin (SLN) are two single-pass membrane proteins that regulate Ca2+-ATPase (SERCA), an ATP-driven pump that translocates calcium ions into the lumen of the sarcoplasmic reticulum, initiating muscle relaxation. Both proteins bind SERCA through intramembrane interactions, impeding calcium translocation. While phosphorylation of PLN at Ser-16 and/or Thr-17 reestablishes calcium flux, the regulatory mechanism of SLN remains elusive. SERCA has been crystallized in several different states along the enzymatic reaction coordinates, providing remarkable mechanistic information; however, the lack of high-resolution crystals in the presence of PLN and SLN limits the current understanding of the regulatory mechanism. This brief review offers a survey of our hybrid structural approach using solution and solid-state NMR methodologies to understand SERCA regulation from the point of view of PLN and SLN. These results have improved our understanding of the calcium translocation process and are the basis for designing new therapeutic approaches to ameliorate muscle malfunctions.

Structural constraints on the transmembrane and juxtamembrane regions of the phospholamban pentamer in membrane bilayers: Gln29 and Leu52

The Ca2+-ATPase of cardiac muscle cells transports Ca2+ ions against a concentration gradient into the sarcoplasmic reticulum and is regulated by phospholamban, a 52-residue integral membrane protein. It is known that phospholamban inhibits the Ca2+ pump during muscle contraction and that inhibition is removed by phosphorylation of the protein during muscle relaxation. Phospholamban forms a pentameric complex with a central pore. The solid-state magic angle spinning (MAS) NMR measurements presented here address the structure of the phospholamban pentamer in the region of Gln22-Gln29. Rotational echo double resonance (REDOR) NMR measurements show that the side chain amide groups of Gln29 are in close proximity, consistent with a hydrogen-bonded network within the central pore. 13C MAS NMR measurements are also presented on phospholamban that is 1-13C-labeled at Leu52, the last residue of the protein. pH titration of the C-terminal carboxyl group suggests that it forms a ring of negative charge on the lumenal side of the sarcoplasmic reticulum membrane. The structural constraints on the phospholamban pentamer described in this study are discussed in the context of a multifaceted mechanism for Ca2+ regulation that may involve phospholamban as both an inhibitor of the Ca2+ ATPase and as an ion channel.

Side chain and backbone dynamics of phospholamban in phospholipid bilayers utilizing 2H and 15N solid-state NMR spectroscopy

2H and 15N solid-state NMR spectroscopic techniques were used to investigate both the side chain and backbone dynamics of wild-type phospholamban (WT-PLB) and its phosphorylated form (P-PLB) incorporated into 1-palmitoyl-2-oleoyl-sn-glycerophosphocholine (POPC) phospholipid bilayers. 2H NMR spectra of site-specific CD3-labeled WT-PLB (at Leu51, Ala24, and Ala15) in POPC bilayers were similar under frozen conditions (-25 degrees C). However, significant differences in the line shapes of the 2H NMR spectra were observed in the liquid crystalline phase at and above 0 degrees C. The 2H NMR spectra indicate that Leu51, located toward the lower end of the transmembrane (TM) helix, shows restricted side chain motion, implying that it is embedded inside the POPC lipid bilayer. Additionally, the line shape of the 2H NMR spectrum of CD3-Ala24 reveals more side chain dynamics, indicating that this residue (located in the upper end of the TM helix) has additional backbone and internal side chain motions. 2H NMR spectra of both WT-PLB and P-PLB with CD3-Ala15 exhibit strong isotropic spectral line shapes. The dynamic isotropic nature of the 2H peak can be attributed to side chain and backbone motions to residues located in an aqueous environment outside the membrane. Also, the spectra of 15N-labeled amide WT-PLB at Leu51 and Leu42 residues showed only a single powder pattern component indicating that these two 15N-labeled residues located in the TM helix are motionally restricted at 25 degrees C. Conversely, 15N-labeled amide WT-PLB at Ala11 located in the cytoplasmic domain showed both powder and isotropic components at 25 degrees C. Upon phosphorylation, the mobile component contribution increases at Ala11. The 2H and 15N NMR data indicate significant backbone motion for the cytoplasmic domain of WT-PLB when compared to the transmembrane section.

Spectroscopic validation of the pentameric structure of phospholamban

Phospholamban (PLN) regulates calcium translocation within cardiac myocytes by shifting sarco(endo)plasmic reticulum Ca(2+)-ATPase (SERCA) affinity for calcium. Although the monomeric form of PLN (6 kDa) is the principal inhibitory species, recent evidence suggests that the PLN pentamer (30 kDa) also is able to bind SERCA. To date, several membrane architectures of the pentamer have been proposed, with different topological orientations for the cytoplasmic domain: (i) extended from the bilayer normal by 50-60 degrees; (ii) continuous alpha-helix tilted 28 degrees relative to the bilayer normal; (iii) pinwheel geometry, with the cytoplasmic helix perpendicular to the bilayer normal and in contact with the surface of the bilayer; and (iv) bellflower structure, in which the cytoplasmic domain helix makes approximately 20 degrees angle with respect to the membrane bilayer normal. Using a variety of cell membrane mimicking systems (i.e., lipid vesicles, oriented lipid bilayers, and detergent micelles) and a combination of multidimensional solution/solid-state NMR and EPR spectroscopies, we tested the different structural models. We conclude that the pinwheel topology is the predominant conformation of pentameric PLN, with the cytoplasmic domain interacting with the membrane surface. We propose that the interaction with the bilayer precedes SERCA binding and may mediate the interactions with other proteins such as protein kinase A and protein phosphatase 1.

Oligomeric structure, dynamics, and orientation of membrane proteins from solid-state NMR

Solid-state NMR is a versatile and powerful tool for determining the dynamic structure of membrane proteins at atomic resolution. I review the recent progress in determining the orientation, the internal and global protein dynamics, the oligomeric structure, and the ligand-bound structure of membrane proteins with both alpha-helical and beta sheet conformations. Examples are given that illustrate the insights into protein function that can be gained from the NMR structural information.

Phospholamban and its phosphorylated form interact differently with lipid bilayers: a 31P, 2H, and 13C solid-state NMR spectroscopic study

Phospholamban (PLB) is a 52-amino acid integral membrane protein that helps to regulate the flow of Ca(2+) ions in cardiac muscle cells. Recent structural studies on the PLB pentamer and the functionally active monomer (AFA-PLB) debate whether its cytoplasmic domain, in either the phosphorylated or dephosphorylated states, is alpha-helical in structure as well as whether it associates with the lipid head groups (Oxenoid, K. (2005) Proc. Natl. Acad. Sci. U.S.A. 102, 10870-10875; Karim, C. B. (2004) Proc. Natl. Acad. Sci. U.S.A. 101, 14437-14442; Andronesi, C.A. (2005) J. Am. Chem. Soc. 127, 12965-12974; Li, J. (2003) Biochemistry 42, 10674-10682; Metcalfe, E. E. (2005) Biochemistry 44, 4386-4396: Clayton, J. C. (2005) Biochemistry 44, 17016-17026). Comparing the secondary structure of the PLB pentamer and its phosphorylated form (P-PLB) as well as their interaction with the lipid bilayer is crucial in order to understand its regulatory function. Therefore, in this study, the full-length wild-type (WT) PLB and P-PLB were incorporated into 1-palmitoyl-2-oleoyl-sn-glycero-phosphocholine (POPC) phospholipid bilayers and studied utilizing solid-state NMR spectroscopy. The analysis of the (2)H and (31)P solid-state NMR data of PLB and P-PLB in POPC multilamellar vesicles (MLVs) indicates that a direct interaction takes place between both proteins and the phospholipid head groups. However, the interaction of P-PLB with POPC bilayers was less significant compared that with PLB. Moreover, the secondary structure using (13)C=O site-specific isotopically labeled Ala15-PLB and Ala15-P-PLB in POPC bilayers suggests that this residue, located in the cytoplasmic domain, is a part of an alpha-helical structure for both PLB and P-PLB.

Membrane assembly of simple helix homo-oligomers studied via molecular dynamics simulations

The assembly of simple transmembrane helix homo-oligomers is studied by combining a generalized Born implicit membrane model with replica exchange molecular dynamics simulations to sample the conformational space of various oligomerization states and the native oligomeric conformation. Our approach is applied to predict the structures of transmembrane helices of three proteins--glycophorin A, the M2 proton channel, and phospholamban--using only peptide sequence and the native oligomerization state information. In every case, the methodology reproduces native conformations that are in good agreement with available experimental structural data. Thus, our method should be useful in the prediction of native structures of transmembrane domains of other peptides. When we ignore the experimental constraint on the native oligomerization state and attempt de novo prediction of the structure and oligomerization state based only on sequence and simple energetic considerations, we identify the pentamer as the most stable oligomer for phospholamban. However, for the glycophorin A and the M2 proton channels, we tend to predict higher oligomers as more stable. Our studies demonstrate that reliable predictions of the structure of transmembrane helical oligomers can be achieved when the observed oligomerization state is imposed as a constraint, but that further efforts are needed for the de novo prediction of both structure and oligomeric state.

Structural Dynamics and Topology of Phospholamban in Oriented Lipid Bilayers Using Multidimensional Solid-State NMR

Phospholamban (PLN), a single-pass membrane protein, regulates heart muscle contraction and relaxation by reversible inhibition of the sarco(endo)plasmic reticulum Ca-ATPase (SERCA). Studies in detergent micelles and oriented lipid bilayers have shown that in its monomeric form PLN adopts a dynamic L shape (bent or T state) that is in conformational equilibrium with a more dynamic R state. In this paper, we use solid-state NMR on both uniformly and selectively labeled PLN to refine our initial studies, describing the topology and dynamics of PLN in oriented lipid bilayers. Two-dimensional PISEMA (polarization inversion spin exchange at the magic angle) experiments carried out in DOPC/DOPE mixed lipid bilayers reveal a tilt angle of the transmembrane domain with respect to the static magnetic field, of 21 +/- 2 degrees and, at the same time, map the rotation angle of the transmembrane domain with respect to the bilayer. PISEMA spectra obtained with selectively labeled samples show that the cytoplasmic domain of PLN is helical and makes an angle of 93 +/- 6 degrees with respect to the bilayer normal. In addition, using samples tilted by 90 degrees , we find that the transmembrane domain of PLN undergoes fast long-axial rotational diffusion about the bilayer normal with the cytoplasmic domain undergoing this motion and other complex dynamics, scaling the values of chemical shift anisotropy. While this dynamic was anticipated by previous solution NMR relaxation studies in micelles, these measurements in the anisotropic lipid environment reveal new dynamic and conformational features encoded in the free protein that might be crucial for SERCA recognition and subsequent inhibition.

The structural properties of the transmembrane segment of the integral membrane protein phospholamban utilizing 13C CPMAS, 2H, and REDOR solid-state NMR spectroscopy

Solid-state NMR spectroscopic techniques were used to investigate the secondary structure of the transmembrane peptide phospholamban (TM-PLB), a sarcoplasmic Ca(2+) regulator. (13)C cross-polarization magic angle spinning spectra of (13)C carbonyl-labeled Leu39 of TM-PLB exhibited two peaks in a pure 1-palmitoyl-2-oleoyl-phosphocholine (POPC) bilayer, each due to a different structural conformation of phospholamban as characterized by the corresponding (13)C chemical shift. The addition of a negatively charged phospholipid (1-palmitoyl-2-oleoylphosphatidylglycerol (POPG)) to the POPC bilayer stabilized TM-PLB to an alpha-helical conformation as monitored by an enhancement of the alpha-helical carbonyl (13)C resonance in the corresponding NMR spectrum. (13)C-(15)N REDOR solid-state NMR spectroscopic experiments revealed the distance between the (13)C carbonyl carbon of Leu39 and the (15)N amide nitrogen of Leu42 to be 4.2+/-0.2A indicating an alpha-helical conformation of TM-PLB with a slight deviation from an ideal 3.6 amino acid per turn helix. Finally, the quadrupolar splittings of three (2)H labeled leucines (Leu28, Leu39, and Leu51) incorporated in mechanically aligned DOPE/DOPC bilayers yielded an 11 degrees +/-5 degrees tilt of TM-PLB with respect to the bilayer normal. In addition to elucidating valuable TM-PLB secondary structure information, the solid-state NMR spectroscopic data indicates that the type of phospholipids and the water content play a crucial role in the secondary structure and folding of TM-PLB in a phospholipid bilayer.

NMR determination of photorespiration in intact leaves using in vivo 13CO2 labeling

Solid-state 13C NMR measurements of intact soybean leaves labeled by 13CO2 lead to the conclusion that photorespiration is 17% of photosynthesis for a well-watered and fertilized plant. This is the first direct assessment of the level of photorespiration in a functioning plant. A 13C{31P} rotational-echo double-resonance (REDOR) measurement tracked the incorporation of 13C label into intermediates in the Calvin cycle as a function of time. For labeling times of 5 min or less, the isotopic enrichment of the Calvin cycle depends on the flux of labeled carbon from 13CO2, relative to the flux of unlabeled carbon from glycerate returned from the photorespiratory cycle. Comparisons of these two rates for a fixed value of the 13CO2 concentration indicate that the ratio of the rate of photosynthesis to the rate of photorespiration of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) in soybean leaves is 5.7. This translates into a photorespiratory CO2 loss that is 21% of net CO2 assimilation, about 80% of the value estimated from Rubisco kinetics parameters. The ratio of rates is reduced at low external CO2 concentrations, as measured by net carbon assimilation rates. The carbon assimilation was determined from 13C-label spin counts converted into total carbon by the REDOR-determined isotopic enrichments of the Calvin cycle. The net carbon assimilation rates indicate that the rate of decarboxylation of glycine is not directly proportional to the oxygenase activity of Rubisco as is commonly assumed.

Determination of Membrane Protein Structure and Dynamics by Magic-Angle-Spinning Solid-State NMR Spectroscopy†

It is shown that molecular structure and dynamics of a uniformly labeled membrane protein can be studied under magic-angle-spinning conditions. For this purpose, dipolar recoupling experiments are combined with novel through-bond correlation schemes that probe mobile protein segments. These NMR schemes are demonstrated on a uniformly [13C,15N] variant of the 52-residue polypeptide phospholamban. When reconstituted in lipid bilayers, the NMR data are consistent with an alpha-helical trans-membrane segment and a cytoplasmic domain that exhibits a high degree of structural disorder.

Investigation of Ligand-Receptor Systems by High-Resolution Solid-State NMR: Recent Progress and Perspectives

Solid-state Nuclear Magnetic Resonance (NMR) provides a general method to study molecular structure and dynamics in a non-crystalline and insoluble environment. We discuss the latest methodological progress to construct 3D molecular structures from solid-state NMR data obtained under magic-angle-spinning conditions. As shown for the neurotensin/NTS-1 system, these methods can be readily applied to the investigation of ligand-binding to G-protein coupled receptors.

Phospholamban pentamer quaternary conformation determined by in-gel fluorescence anisotropy

We measured in-gel fluorescence anisotropy of phospholamban (PLB) labeled with the biarsenical fluorophore FlAsH at three different sites on the cytoplasmic domain. The 6 kDa monomer bands of FlAsH-tetracysPLB showed high anisotropy (r = 0.29), reflecting null homotransfer and low mobility (S = 0.85) on the nanosecond time scale of the FlAsH fluorescence lifetime. 30 kDa bands (pentameric PLB) within the same lanes exhibited low anisotropy, suggesting intrapentameric fluorescence energy homotransfer between PLB subunits. FlAsH labels positioned at residue -6, 5, or 23 showed a graduated pattern of fluorescence depolarization corresponding to resonance energy transfer radii of 46 +/-2, 38 +/- 4, and <25 A, respectively. Pentamer anisotropy increased with heating or fluorescence photobleaching toward a maximum value similar to that determined for monomeric PLB. Fluorescence resonance energy heterotransfer was also observed in vitro and in vivo within PLB pentamers colabeled with FlAsH and the biarsenical fluorophore ReAsH. In vitro heterotransfer efficiencies were graduated by labeling position, in harmony with homotransfer results. The calculated transfer radii compare favorably to distances predicted by a computer molecular model of the phospholamban pentamer constructed from NMR solution structures. The data support a helical pinwheel model for the PLB pentamer, in which the cytoplasmic domains bend sharply outward from the central bundle of helices.

Probing the Oligomeric State of Phospholamban Variants in Phospholipid Bilayers from Solid-State NMR Measurements of Rotational Diffusion Rates

Phospholamban (PLB) is a small transmembrane protein that regulates calcium transport across the sarcoplasmic reticulum (SR) of cardiac cells. PLB self-associates into pentamers within sodium dodecyl sulfate (SDS) micelles, but the oligomeric status of PLB in SR membranes is not known. This work has shown that a mutant of PLB, with all native cysteine residues replaced by alanine (Ala-PLB), runs as a monomer on SDS-PAGE gels, in agreement with previous studies [Karim et al. (2000) Biochemistry 39, 10892-10897]. By contrast, a peptide representing the transmembrane domain of the cysteine-free mutant (TM-Ala-PLB) coexists as pentamers, dimers, and monomers on gels. Solid-state NMR methods were used to examine the size and heterogeneity of Ala-PLB and TM-Ala-PLB labeled with (13)C and (2)H in the transmembrane domain and incorporated into dimyristoylphosphatidylcholine (DMPC) bilayers. Wide line (2)H NMR and (13)C cross-polarization magic-angle spinning (CP-MAS) NMR spectra of Ala-PLB and TM-Ala-PLB revealed two distinct species of each of the proteins in the membranes. In the case of Ala-PLB one species was present initially and a second species emerged after 12 h. Measurements of (1)H-(13)C dipolar couplings for the two species of Ala-PLB showed that the rotational diffusion of one species was relatively rapid, defined by a correlation time (tau(R)) of less than 10 micros, whereas the rotation of the other species was comparatively slow (tau(R) approximately 60 micros). These results suggest that although Ala-PLB runs as a monomer on gels, a mixture of different oligomeric forms of the protein, possibly monomers and pentamers, is present in DMPC bilayers. Caution must therefore be exercised in using SDS-PAGE to draw conclusions about the oligomeric state of PLB variants in lipid bilayers.

Determination of helical membrane protein topology using residual dipolar couplings and exhaustive search algorithm: application to phospholamban

Dipolar waves are distinct hallmarks of both the secondary and tertiary structures of alpha-helical proteins that are immobilized in membrane bilayers or embedded in anisotropic media. We present a simple, semi-empirical approach that exploits the modulation of the amplitude and average of dipolar waves to determine the topology of alpha-helical proteins. Moreover, we describe the application of this method for the structural determination of a detergent solubilized membrane protein, phospholamban (PLB) that is involved in calcium regulation of cardiac muscle. When combined with high-resolution solid-state NMR data, this method can serve as a fast route for determining the topology of helical membrane proteins solubilized in detergent micelles.

Probing membrane protein orientation and structure using fast magic-angle-spinning solid-state NMR

One and two-dimensional solid-state NMR experiments are discussed that permit probing local structure and overall molecular conformation of membrane-embedded polypeptides under Magic Angle Spinning. The functional dependence of a series of anisotropic recoupling schemes is analyzed using theoretical and numerical methods. These studies lead to the construction of a set of polarization dephasing or transfer units that probe local backbone conformation and overall molecular orientation within the same NMR experiment. Experimental results are shown for a randomly oriented peptide and for two model membrane-peptides reconstituted into lipid bilayers and oriented on polymer films according to a method proposed by Bechinger et al.

Investigating the Dynamic Properties of the Transmembrane Segment of Phospholamban Incorporated into Phospholipid Bilayers Utilizing 2H and 15N Solid-State NMR Spectroscopy

(2)H and (15)N solid-state NMR spectroscopic techniques were used to investigate the membrane composition, orientation, and side-chain dynamics of the transmembrane segment of phospholamban (TM-PLB), a sarcoplasmic Ca(2+)-regulator protein. (2)H NMR spectra of (2)H-labeled leucine (deuterated at one terminal methyl group) incorporated at different sites (CD(3)-Leu28, CD(3)-Leu39, and CD(3)-Leu51) along the TM-PLB peptide exhibited line shapes characteristic of either methyl group reorientation about the C(gamma)-C(delta) bond axis or by additional librational motion about the C(alpha)-C(beta) and C(beta)-C(gamma) bond axes. The (2)H NMR line shapes of all CD(3)-labeled leucines are very similar below 0 degrees C, indicating that all of the residues are located inside the lipid bilayer. At higher temperatures, all three labeled leucine residues undergo rapid reorientation about the C(alpha)-C(beta), C(beta)-C(gamma), and C(gamma)-C(delta) bond axes as indicated by (2)H line-shape simulations and reduced quadrupolar splittings. At all of the temperatures studied, the (2)H NMR spectra indicated that the Leu51 side chain has less motion than Leu39 or Leu28, which is attributed to its incorporation in the pentameric PLB leucine zipper motif. The (15)N powder spectra of Leu39 and Leu42 residues indicated no backbone motion, while Leu28 exhibited slight backbone motion. The chemical-shift anisotropy tensor values for (15)N-labeled Leu TM-PLB were sigma(11) = 50.5 ppm, sigma(22) = 80.5 ppm, and sigma(33) = 229 ppm within +/-3 ppm experimental error. The (15)N chemical-shift value from the mechanically aligned spectrum of (15)N-labeled Leu39 PLB in DOPC/DOPE phospholipid bilayers was 220 ppm and is characteristic of a TM peptide that is nearly parallel with the bilayer normal.

Structure of a Quinobenzoxazine−G-Quadruplex Complex by REDOR NMR

Rotational-echo double resonance solid-state (31)P[(19)F] and (13)C[(19)F] NMR spectra have been used to locate the binding of a fluoroquinobenzoxazine to a DNA G-quadruplex labeled by phosphorothioation and [methyl-(13)C]thymidine.

Screening Molecular Associations with Lipid Membranes Using Natural Abundance 13C Cross-Polarization Magic-Angle Spinning NMR and Principal Component Analysis

We describe an NMR approach for detecting the interactions between phospholipid membranes and proteins, peptides, or small molecules. First, 1H-13C dipolar coupling profiles are obtained from hydrated lipid samples at natural isotope abundance using cross-polarization magic-angle spinning NMR methods. Principal component analysis of dipolar coupling profiles for synthetic lipid membranes in the presence of a range of biologically active additives reveals clusters that relate to different modes of interaction of the additives with the lipid bilayer. Finally, by representing profiles from multiple samples in the form of contour plots, it is possible to reveal statistically significant changes in dipolar couplings, which reflect perturbations in the lipid molecules at the membrane surface or within the hydrophobic interior.

NMR solution structure and topological orientation of monomeric phospholamban in dodecylphosphocholine micelles

Phospholamban is an integral membrane protein that regulates the contractility of cardiac muscle by maintaining cardiomyocyte calcium homeostasis. Abnormalities in association of protein kinase A with PLB have recently been linked to human heart failure, where a single mutation is responsible for dilated cardiomyopathy. To date, a high-resolution structure of phospholamban in a lipid environment has been elusive. Here, we describe the first structure of recombinant, monomeric, biologically active phospholamban in lipid-mimicking dodecylphosphocholine micelles as determined by multidimensional NMR experiments. The overall structure of phospholamban is "L-shaped" with the hydrophobic domain approximately perpendicular to the cytoplasmic portion. This is in agreement with our previously published solid-state NMR data. In addition, there are two striking discrepancies between our structure and those reported previously for synthetic phospholamban in organic solvents: a), in our structure, the orientation of the cytoplasmic helix is consistent with the amphipathic nature of these residues; and b), within the hydrophobic helix, residues are positioned on two discrete faces of the helix as consistent with their functional roles ascribed by mutagenesis. This topology renders the two phosphorylation sites, Ser-16 and Thr-17, more accessible to kinases.

Cell cycle-dependent dynamic localization of a bacterial response regulator with a novel di-guanylate cyclase output domain

Pole development is coordinated with the Caulobacter crescentus cell cycle by two-component signaling proteins. We show that an unusual response regulator, PleD, is required for polar differentiation and is sequestered to the cell pole only when it is activated by phosphorylation. Dynamic localization of PleD to the cell pole provides a mechanism to temporally and spatially control the signaling output of PleD during development. Targeting of PleD to the cell pole is coupled to the activation of a C-terminal guanylate cyclase domain, which catalyzes the synthesis of cyclic di-guanosine monophosphate. We propose that the local action of this novel-type guanylate cyclase might constitute a general regulatory principle in bacterial growth and development.

Characterization of the Complex of a Trifluoromethyl-Substituted Shikimate-Based Bisubstrate Inhibitor and 5-Enolpyruvylshikimate-3-phosphate Synthase by REDOR NMR

A combination of (15)N[(19)F], (31)P[(15)N], and (31)P[(19)F] rotational-echo double-resonance NMR has been used to characterize the conformation of a bound trifluoromethylketal, shikimate-based bisubstrate inhibitor of 5-enolpyruvylshikimate-3-phosphate synthase. The solid-state NMR experiments were performed on the complex formed in solution and then lyophilized at low temperatures in the presence of stabilizing lyoprotectants. The results of these experiments indicate that none of the side chains of the six arginines that surround the active site forms a compact salt bridge with the phosphate groups of the bound inhibitor.

Compensating for pulse imperfections in REDOR

Rotational-echo double resonance (REDOR) is a magic-angle spinning technique for measuring heteronuclear dipolar couplings. Rotor-synchronized pi pulses recouple the dipolar interaction. The accuracy of a REDOR determination of distance or orientation depends totally on the quality of the dephased (recoupled) and full-echo spectra. We present a scheme for measuring and compensating for the effects of pulse imperfections in REDOR experiments. No assumptions are made about the quality of the pi pulses, and no pulses are added or taken away in implementing the compensation for incomplete REDOR dephasing by imperfect pi pulses.

Phosphorylation by cAMP-dependent protein kinase modulates the structural coupling between the transmembrane and cytosolic domains of phospholamban

We have used frequency-domain fluorescence spectroscopy to investigate the structural linkage between the transmembrane and cytosolic domains of the regulatory protein phospholamban (PLB). Using an engineered PLB having a single cysteine (Cys(24)) derivatized with the fluorophore N-(1-pyrenyl)maleimide (PMal), we have used fluorescence resonance energy transfer (FRET) to measure the average spatial separation and conformational heterogeneity between PMal bound to Cys(24) in the transmembrane domain and Tyr(6) in the cytosolic domain near the amino terminus of PLB. In these measurements, PMal serves as a FRET donor, and Tyr(6) serves as a FRET acceptor following its nitration by tetranitromethane. The native structure of PLB is retained following site-directed mutagenesis and chemical modification, as indicated by the ability of the derivatized PLB to fully regulate the Ca-ATPase following their co-reconstitution. To assess how phosphorylation modulates the structure of PLB itself, FRET measurements were made following reconstitution of PLB in membrane vesicles made from extracted sarcoplasmic reticulum membrane lipids. We find that the cytosolic domain of PLB assumes a wide range of conformations relative to the transmembrane sequence, consistent with other structural data indicating the presence of a flexible hinge region between the transmembrane and cytosolic domains of PLB. Phosphorylation of Ser(16) by PKA results in a 3 A decrease in the spatial separation between PMal at Cys(24) and nitroTyr(6) and an almost 2-fold decrease in conformational heterogeneity, suggesting a stabilization of the hinge region of PLB possibly through an electrostatic linkage between phosphoSer(16) and Arg(13) that promotes a coil-to-helix transition. This structural transition has the potential to function as a conformational switch, since inhibition of the Ca-ATPase requires disruption of the secondary structure of PLB in the vicinity of the hinge element to permit association with the nucleotide binding domain at a site located approximately 50 A above the membrane surface. Following phosphorylation, the stabilization of the helical content in the hinge domain will disrupt this inhibitory interaction by reducing the maximal dimension of the cytosolic domain of PLB. Thus, stabilization of the structure of PLB following phosphorylation of Ser(16) is part of a switching mechanism, which functions to alter binding interactions between PLB and the nucleotide binding domain of the Ca-ATPase that modulates enzyme inhibition.

Conformation of a bound inhibitor of blood coagulant factor Xa

13C[(15)N] and (13)C[(19)F] rotational-echo double-resonance NMR have been used to characterize the enzyme-bound structure of ZK-816042, an amidine-imidazoline inhibitor of human factor Xa (FXa). The NMR experiments were performed on a lyophilized FXa-inhibitor complex. The complex was formed in solution in the presence of stabilizing excipients and frozen after gradual supercooling prior to lyophilization. The results indicate that the inhibitor binds with a distribution of orientations of the imidazoline ring.

Structure and function of integral membrane protein domains resolved by peptide-amphiphiles: application to phospholamban

We have used synthetic lipidated peptides ("peptide-amphiphiles") to study the structure and function of isolated domains of integral transmembrane proteins. We used 9-fluorenylmethyloxycarbonyl (Fmoc) solid-phase peptide synthesis to prepare full-length phospholamban (PLB(1-52)) and its cytoplasmic (PLB(1-25)K: phospholamban residues 1-25 plus a C-terminal lysine), and transmembrane (PLB(26-52)) domains, and a 38-residue model alpha-helical sequence as a control. We created peptide-amphiphiles by linking the C-terminus of either the isolated cytoplasmic domain or the model peptide to a membrane-anchoring, lipid-like hydrocarbon tail. Circular dichroism measurements showed that the model peptide-amphiphile, either in aqueous suspension or in lipid bilayers, had a higher degree of alpha-helical secondary structure than the unlipidated model peptide. We hypothesized that the peptide-amphiphile system would allow us to study the function and structure of the PLB(1-25)K cytoplasmic domain in a native-like configuration. We compared the function (inhibition of the Ca-ATPase in reconstituted membranes) and structure (via CD) of the PLB(1-25) amphiphile to that of PLB and its isolated transmembrane and cytoplasmic domains. Our results indicate that the cytoplasmic domain PLB(1-25)K has no effect on Ca-ATPase (calcium pump) activity, even when tethered to the membrane in a manner mimicking its native configuration, and that the transmembrane domain of PLB is sufficient for inhibition of the Ca-ATPase.

REDOR with a relative full-echo reference

REDOR and REDOR-like 13C[19F] and 2H[19F] NMR experiments have been performed on lyophilized whole cells of Staphylococcus aureus. The bacteria were grown to maturity on media containing L-[13C(3)]alanine or L-[methyl-d(3)]alanine, and then complexed with the 4-fluorobiphenyl derivative of chloroeremomycin, an analogue of the widely used antibiotic, vancomycin. The position of the 19F of the drug bound in the bacterial cell wall was determined relative to L-alanine 13C and 2H labels in the peptidoglycan peptide stem that was closest to the fluorinated biphenyl moiety of the drug. These determinations were made by dipolar recoupling methods that do not require an absolute measurement of the REDOR full echo (the signal observed without rotor-synchronized dephasing pulses) of the labels in the peptide stem.

Solid-state NMR reveals structural changes in phospholamban accompanying the functional regulation of Ca2+-ATPase

Calcium transport across the sarcoplasmic reticulum of cardiac myocytes is regulated by a reversible inhibitory interaction between the Ca2+-ATPase and the small transmembrane protein phospholamban (PLB). A nullcysteine analogue of PLB, containing isotope labels in the transmembrane domain or cytoplasmic domain, was reconstituted into membranes in the absence and presence of the SERCA1 isoform of Ca2+-ATPase for structural investigation by cross-polarization magic-angle spinning (CP-MAS) NMR. PLB lowered the maximal hydrolytic activity of SERCA1 and its affinity for calcium in membrane preparations suitable for structural analysis by NMR. Novel backbone amide proton-deuterium exchange CP-MAS NMR experiments on the two PLB analogues co-reconstituted with SERCA1 indicated that labeled residues Leu42 and Leu44 were situated well within the membrane interior, whereas Pro21 and Ala24 lie exposed outside the membrane. Internuclear distance measurements on PLB using rotational resonance NMR indicated that the sequences Pro21-Ala24 and Leu42-Leu44 adopt an alpha-helical structure in pure lipid bilayers, which is unchanged in the presence of Ca2+-ATPase. By contrast, rotational echo double resonance (REDOR) NMR experiments revealed that the sequence Ala24-Gln26 switches from an alpha-helix in pure lipid membranes to a more extended structure in the presence of SERCA1, which may reflect local structural distortions which change the orientations of the transmembrane and cytoplasmic domains. These results suggest that Ca2+-ATPase has a long-range effect on the structure of PLB around residue 25, which promotes the functional association of the two proteins.

Folding in lipid membranes (FILM): a novel method for the prediction of small membrane protein 3D structures

We present the results of applying a novel knowledge-based method (FILM) to the prediction of small membrane protein structures. The basis of the method is the addition of a membrane potential to the energy terms (pairwise, solvation, steric, and hydrogen bonding) of a previously developed ab initio technique for the prediction of tertiary structure of globular proteins (FRAGFOLD). The method is based on the assembly of supersecondary structural fragments taken from a library of highly resolved protein structures using a standard simulated annealing algorithm. The membrane potential has been derived by the statistical analysis of a data set made of 640 transmembrane helices with experimentally defined topology and belonging to 133 proteins extracted from the SWISS-PROT database. Results obtained by applying the method to small membrane proteins of known 3D structure show that the method is able to predict, at a reasonable accuracy level, both the helix topology and the conformations of these proteins.

A structural model of the complex formed by phospholamban and the calcium pump of sarcoplasmic reticulum obtained by molecular mechanics

Phospholamban (PLN) is an intrinsic membrane protein of 52 amino acids that modulates the activity of the reticular Ca(2+) ion pump. We recently solved the three-dimensional structure of chemically synthesized, unphosphorylated, monomeric PLN (C41F) by high-resolution nuclear magnetic resonance spectroscopy in chloroform/methanol. The structure is composed of two alpha-helical regions connected by a beta turn (Type III). We used this structure and the crystallographic structure of the sarcoplasmic reticulum calcium pump (SERCA) recently determined by Toyoshima and co-workers and modeled into its E(2) form by Stokes (1KJU) or by Toyoshima (1FQU). We applied restrained and unrestrained energy optimizations and used the AMBER molecular mechanics force field to model the complex formed between PLN and the pump. The results indicate that transmembrane helix 6 (M6) of the SERCA pump is energetically favored, with respect to the other transmembrane helices, as the PLN binding partner within the membrane and is the only one of these helices that also permits contact between the N-terminal residues of PLN and the critical cytosolic binding loop region of the pump. This result is in agreement with published biochemical data and with the predictions of previous mutagenesis work on the membrane sector of the pump. The model reveals that PLN does not span the entire width of the membrane, that is, its hydrophobic C-terminal end is located near the center of the transmembrane region of the SERCA pump. The model also shows that interaction with M6 is stabilized by additional contacts made by PLN to M4. The contact between the N-terminal portion of PLN and the pump is stabilized by a number of salt and hydrogen-bond bridges, which may be abolished by phosphorylation of PLN. The contacts between the cytosolic portions of PLN and the pump are only observed in the E(2) conformation of the pump. Our model of the complex also offers a plausible structural explanation for the preference of protein kinase A for phosphorylation of Ser16 of PLN.

Phosphorylation induces a conformational transition near the lipid-water interface of phospholamban reconstituted with the Ca-ATPase

We have measured conformational changes of phospholamban (PLB) induced both by its interaction with the SR Ca-ATPase and by phosphorylation of Ser-16 by cAMP-dependent protein kinase (PKA) using an engineered PLB having a single cysteine (Cys-24) derivatized with the fluorophore 2-(4'-maleimidylanilino)naphthalene-6-sulfonic acid (ANSmal). This modified mutant PLB is fully functional when co-reconstituted with the affinity-purified Ca-ATPase in liposomes. ANSmal emission properties and its solvent accessibility indicate that Cys-24 is in an aqueous environment outside the membrane. Fluorescence quenching and time-resolved anisotropy measurements of ANSmal-PLB demonstrate distinct structures for PLB in the free and Ca-ATPase-bound state. Both solvent exposure and probe motions of ANSmal are enhanced upon interaction of PLB with the Ca-ATPase. This conformational transition entails conversion of free PLB in a conformation which is insensitive to one which is sensitive to the phosphorylation state of PLB. Upon phosphorylation of Ca-ATPase-bound PLB, a decreased level of solvent exposure of ANSmal is observed, suggesting that the amino acid sequence of PLB near the lipid-water interface acts as a conformational switch in response to the phosphorylation of PLB. A longer correlation time, resolved by anisotropy measurements, corresponding to polypeptide chain fluctuations, is substantially restricted by interaction of PLB with the Ca-ATPase. This restriction is not reversed by phosphorylation of PLB, indicating that the region around Cys-24 near the lipid-water interface does not undergo dissociation from the Ca-ATPase. These results suggest that the phosphorylation by PKA induces a redistribution of PLB-Ca-ATPase protein contacts to relieve the inhibitory effect of PLB for the activation of calcium transport.

Rotational-echo double resonance characterization of the effects of vancomycin on cell wall synthesis in Staphylococcus aureus

Cross-polarization magic-angle spinning and rotational-echo double resonance 13C and 15N NMR experiments have been performed on intact cells of Staphylococcus aureus labeled with D-[1-13C]alanine and [15N]glycine or with [1-13C]glycine and L-[epsilon-15N]lysine. The cells were harvested during stationary or exponential growth conditions, the latter in media with and without the addition of vancomycin. The results of these experiments allowed the in situ determination of the relative concentrations of peptidoglycan cross-links (the number of peptide-stem D-alanines covalently linked to a pentaglycyl bridge) and bridge-links (the number of peptide-stem lysines covalently linked to a pentaglycyl bridge). The concentration of cross-links remained constant in the presence of vancomycin, whereas the number of bridge-links decreased. These changes suggest that vancomycin (at therapeutic levels) interrupts peptidoglycan synthesis in S. aureus by interference with transglycosylation.

Rotational-echo double resonance characterization of vancomycin binding sites in Staphylococcus aureus

Solid-state NMR experiments with stable isotope-labeled Staphylococcus aureus have provided insight into the structure of the peptidoglycan binding site of a potent fluorobiphenyl derivative of chloroeremomycin (Eli Lilly LY329332). Rotational-echo double resonance (REDOR) NMR provided internuclear distances from the 19F of this glycopeptide antibiotic to natural-abundance 31P and to specific 13C and 15N labels biosynthetically incorporated into the bacteria from labeled alanine, glycine, or lysine in the growth medium. Results from experiments with intact late log phase bacteria and cell walls indicated homogeneous drug-peptidoglycan binding. Drug dimers were not detected in situ, and the hydrophobic fluorobiphenyl group of LY329332 did not insert into the bilayer membrane. A model of the binding site consistent with the REDOR results positions the vancomycin cleft around an un-cross-linked D-Ala-D-Ala peptide stem with the fluorobiphenyl moiety of the antibiotic near the base of a second, proximate stem in a locally ordered peptidoglycan matrix.