Synthetic null-cysteine phospholamban analogue and the corresponding transmembrane domain inhibit the Ca-ATPase

Chemical synthesis, functional reconstitution, and electron paramagnetic resonance (EPR) have been used to analyze the structure and function of phospholamban (PLB), a 52-residue integral membrane protein that regulates the calcium pump (Ca-ATPase) in cardiac sarcoplasmic reticulum (SR). PLB exists in equilibrium between monomeric and pentameric forms, as observed by SDS-PAGE, EPR, and fluorescence. It has been proposed that inhibition of the pump is due primarily to the monomeric form, with both pentameric stability and inhibition dependent primarily on the transmembrane (TM) domain. To test these hypotheses, we have studied the physical and functional properties of a synthetic null-cysteine PLB analogue that is entirely monomeric on SDS-PAGE, and compared it with the synthetic null-cysteine TM domain (residues 26-52). The TM domain was found to be primarily oligomeric on SDS-PAGE, and boundary lipid spin label analysis in lipid bilayers verified that the isolated TM domain is more oligomeric than the full-length parent molecule. These results indicate that the stability of the PLB pentamer is due primarily to attractive interactions between hydrophobic TM domains, overcoming the repulsive electrostatic interactions between the cationic cytoplasmic domains (residues 1-25). When reconstituted into liposomes containing the Ca-ATPase, the null-cysteine TM domain had the same inhibitory function as that of the full-length parent molecule. We conclude that the TM domain of PLB is sufficient for inhibitory function, the oligomeric stability of PLB does not determine its inhibitory activity, and the three Cys residues in the TM domain are not required for inhibitory function.     

Toward a high-resolution structure of phospholamban: design of soluble transmembrane domain mutants

Determination of a high-resolution structure of the phospholamban (PLB) transmembrane domain by X-ray crystallography or NMR is handicapped by the hydrophobic nature of the peptide. Interestingly, the crystal structure of the five-stranded parallel coiled-coil oligomerization domain from cartilage oligomeric matrix protein (COMPcc) shows marked similarities to a model proposed for the pentameric transmembrane domain of PLB. Contrary to the putative coiled-coil domain of PLB, COMPcc contains mostly hydrophilic amino acids on the surface, resulting in a soluble molecule. Here, we report the design of soluble PLB transmembrane domain variants by combining the surface residues of COMPcc and the hydrophobic interior of the transmembrane domain of PLB. The soluble PLB variants formed pentameric structures as revealed by analytical ultracentrifugation. After redox shuffling, they showed unspecific disulfide bridge patterns similar to that of the chemically synthesized wild-type PLB transmembrane domain. These results suggest a structural homology between the soluble PLB mutants and the wild-type PLB transmembrane domain. Together with the data reported in the literature, they furthermore indicate that residues Leu37, Ile40, Leu44, and Ile47 of the PLB sequence specify pentamer formation. In contrast, a designed recombinant COMPcc mutant, COMP-ARCC, which was engineered to contain the two PLB cysteines that potentially could form an interchain disulfide bridge, formed a specific disulfide bond pattern. This finding indicates structural differences between the transmembrane domain of PLB and COMPcc. The soluble PLB variants may be used to determine a high-resolution structure of the PLB pentamer by X-ray crystallography.     

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.     

Cysteine Mutagenesis Reveals Transmembrane Residues Associated with Charge Translocation in Prestin

The solute carrier transmembrane protein prestin (SLC26A5) drives an active electromechanical transduction process in cochlear outer hair cells that increases hearing sensitivity and frequency discrimination in mammals. A large intramembraneous charge movement, the nonlinear capacitance (NLC), is the electrical signature of prestin function. The transmembrane domain (TMD) helices and residues involved in the intramembrane charge displacement remain unknown. We have performed cysteine-scanning mutagenesis with serine or valine replacement to investigate the importance of cysteine residues to prestin structure and function. The distribution of oligomeric states and membrane abundance of prestin was also probed to investigate whether cysteine residues participate in prestin oligomerization and/or NLC. Our results reveal that 1) Cys-196 (TMD 4) and Cys-415 (TMD 10) do not tolerate serine replacement, and thus maintaining hydrophobicity at these locations is important for the mechanism of charge movement; 2) Cys-260 (TMD 6) and Cys-381 (TMD 9) tolerate serine replacement and are probably water-exposed; and 3) if disulfide bonds are present, they do not serve a functional role as measured via NLC. These novel findings are consistent with a recent structural model, which proposes that prestin contains an occluded aqueous pore, and we posit that the orientations of transmembrane domain helices 4 and 10 are essential for proper prestin function.     

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.     

The yeast mitochondrial citrate transport protein. Probing the roles of cysteines, Arg(181), and Arg(189) in transporter function

Utilizing site-directed mutagenesis in combination with chemical modification of mutated residues, we have studied the roles of cysteine and arginine residues in the mitochondrial citrate transport protein (CTP) from Saccharomyces cerevisiae. Our strategy consisted of the sequential replacement of each of the four endogenous cysteine residues with Ser or in the case of Cys(73) with Val. Wild-type and mutated forms of the CTP were overexpressed in Escherichia coli, purified, and reconstituted in phospholipid vesicles. During the sequential replacement of each Cys, the effects of both hydrophilic and hydrophobic sulfhydryl reagents were examined. The data indicate that Cys(73) and Cys(256) are primarily responsible for inhibition of the wild-type CTP by hydrophilic sulfhydryl reagents. Experiments conducted with triple Cys replacement mutants (i.e. Cys(192) being the only remaining Cys) indicated that sulfhydryl reagents no longer inhibit but in fact stimulate CTP function 2-3-fold. Following the simultaneous replacement of all four endogenous Cys, the functional properties of the resulting Cys-less CTP were shown to be quite similar to those of the wild-type protein. Finally, utilizing the Cys-less CTP as a template, the roles of Arg(181) and Arg(189), two positively charged residues located within transmembrane domain IV, in CTP function were examined. Replacement of either residue with a Cys abolishes function, whereas replacement with a Lys or a Cys that is subsequently covalently modified with (2-aminoethyl)methanethiosulfonate hydrobromide, a reagent that restores positive charge at this site, supports CTP function. The results clearly show that positive charge at these two positions is essential for CTP function, although the chemistry of the guanidinium residue is not. Finally, these studies: (i) definitely demonstrate that Cys residues do not play an important role in the mechanism of the CTP; (ii) prove the utility of the Cys-less CTP for studying structure/function relationships within this metabolically important protein; and (iii) have led to the hypothesis that the polar face of alpha-helical transmembrane domain IV, within which Arg(181), Arg(189), and Cys(192) are located, constitutes an essential portion of the citrate translocation pathway through the membrane.     

X-ray structure of a water-soluble analog of the membrane protein phospholamban: sequence determinants defining the topology of tetrameric and pentameric coiled coils

Phospholamban (PLB) is a pentameric transmembrane protein that regulates the Ca(2+)-dependent ATPase SERCA2a in sarcoplasmic reticulum membranes. We previously described the computational design of a water-soluble variant of phospholamban, WSPLB, which reproduced many of the structural and functional properties of the native membrane-soluble protein. While the full-length WSPLB forms a pentamer in solution, a truncated variant forms very stable tetramers. To obtain insight into the tetramer-pentamer cytoplasmic switch, we solved the crystal structure of the truncated construct, WSPLB 21-52. This peptide has a heptad sequence repeat with Leu residues at a- and Ile at d-positions from residues 31-52. The crystal structure revealed that WSPLB 21-52 adopted an antiparallel tetrameric coiled coil. This topology contrasts with the parallel topology of an analogue of the coiled-coil of GCN4 with the same Leu(a) Ile(d) repeat. Analysis of these structures revealed how the nature of the partially exposed residues at e- and g-positions influence the topology formed by the bundle. We also constructed a model for the pentameric form of PLB using the coiled-coil parameters derived from a single monomer in the tetrameric structure. This model suggests that both buried and interfacial hydrogen bonds are important for stabilizing the parallel pentamer.     

Computational design of a water-soluble analog of phospholamban

Membrane proteins and water-soluble proteins share a similar core. This similarity suggests that it should be possible to water-solubilize membrane proteins by mutating only their lipid-exposed residues. We have developed computational tools to design water-soluble variants of helical membrane proteins, using the pentameric phospholamban (PLB) as our test case. To water-solublize PLB, the membrane-exposed positions were changed to polar or charged amino acids, while the putative core was left unaltered. We generated water-soluble phospholamban (WSPLB), and compared its properties to its predecessor PLB. In aqueous solution, WSPLB mimics all of the reported properties of PLB including oligomerization state, helical structure, and stabilization upon phosphorylation. We also characterized the truncated mutant WSPLB (21-52) comprising only the former transmembrane segment of PLB. This peptide shows a decreased specificity for forming a pentameric oligomerization state.     

Conformational changes within the cytosolic portion of phospholamban upon release of Ca-ATPase inhibition

Phospholamban (PLB) is a major target of the beta-adrenergic cascade in the heart, functioning to modulate contractile force by altering the rate of calcium re-sequestration by the Ca-ATPase. Functionally, inhibition by PLB binding is manifested by shifts in the calcium dependence of Ca-ATPase activation toward higher calcium levels; phosphorylation of PLB by PKA reverses the inhibitory action of PLB. To investigate structural changes in the cytoplasmic portion of PLB that result from either the phosphorylation of PLB by cAMP-dependent protein kinase (PKA) or calcium binding to the Ca-ATPase, we have used frequency-domain fluorescence spectroscopy to measure the spatial separation and conformational heterogeneity between N-(1-pyrenyl)maleimide, covalently bound to a single cysteine (Cys(24)) engineered near the membrane surface of the transmembrane domain of PLB, and Tyr(6) in the cytosolic domain. Irrespective of calcium activation of the Ca-ATPase or phosphorylation of Ser(16) in PLB by PKA, we find that PLB remains tightly associated with the Ca-ATPase in a well-defined conformation. However, calcium activation of the Ca-ATPase induces an increase in the overall dimensions of the cytoplasmic portion of bound PLB, whereas PLB phosphorylation results in a more compact structure, consistent with increased helical content induced by a salt link between phospho-Ser(16) and Arg(13). Thus, enzyme activation of the Ca-ATPase may occur through different mechanisms: calcium binding to high-affinity sites within the Ca-ATPase functions to overcome conformational constraints imposed by PLB on the N-domain of the Ca-ATPase; alternatively, phosphorylation stabilizes the backbone fold of PLB to release inhibitory interactions with the Ca-ATPase.     

Analysis of the stability and function of nucleoplasmin through cysteine mutants

Xenopus laevis nucleoplasmin is a pentameric nuclear chaperone. The relation between the structure and the multifunctional aspects of the molecule has not yet been clearly established. In the course of analysing a C-terminally His-tagged recombinant version of the region equivalent to the trypsin resistant core (r-NP142) of the molecule, we found that this domain exhibited a substantially decreased oligomerization potential. To better understand the role of the three cysteines of nucleoplasmin on its pentameric functional structure, we have selectively mutated these residues to serine and generated three mutants (C15S, C35S, and C45S) both for the complete recombinant nucleoplasmin (r-NP) and the truncated r-NP142 non-tagged forms. We demonstrate that there are no disulphide bridges stabilizing either the monomer or the pentamer. Neither C15S nor C35S has any structural effects, while the mutation C45S abolishes the ability of r-NP142 to pentamerize. This structural impairment suggests that hydrophobic interactions of Cys 45 are critical for the stability of the protein. Our studies allow to analyse for the first time the structural and functional properties of nucleoplasmin in its monomeric form.     

Molecular dynamics studies on structure and dynamics of phospholamban monomer and pentamer in membranes

Phospholamban (PLB) is an integral membrane protein of 52 residues that regulates the activity of the sarcoplasmic reticulum calcium pump in cardiac muscle cells through reversible phosphorylation of Ser16. To explore its possible conformations and dynamics in a monomeric state, we have performed comparative molecular dynamics simulations of unphosphorylated and phosphorylated PLB (pPLB) with various orientations in POPC membranes. The simulations indicate that dynamics of the cytoplasmic domain is highly dependent on its interactions with membranes, that is, large conformational changes in the absence of membrane interactions, but very restricted dynamics in their presence. pPLB shows more structural flexibility in its cytoplasmic domain, which is consistent with experimental observations. We have also performed a simulation of a PLB pentameric structure (the so‐called bellflower model), recently determined in micelles, to investigate its behaviors in a POPC membrane. The cytoplasmic domain in each monomer shows uncorrelated dynamics and undergoes large conformational changes toward the membrane surface during the simulation, which supports the so‐called pinwheel model of the PLB pentamer structure. The hydrophobic nature of the pentameric pore excludes water molecules in the pore region, which illustrates that the pore appears to be an energetic barrier for ion and water translocation. Proteins 2009. © 2008 Wiley‐Liss, Inc.     

Structural and functional features of the transmembrane domain of the Na,K-ATPase beta subunit revealed by tryptophan scanning

In oligomeric P2-ATPases such as Na,K- and H,K-ATPases, beta subunits play a fundamental role in the structural and functional maturation of the catalytic alpha subunit. In the present study we performed a tryptophan scanning analysis on the transmembrane alpha-helix of the Na,K-ATPase beta1 subunit to investigate its role in the stabilization of the alpha subunit, the endoplasmic reticulum exit of alpha-beta complexes, and the acquisition of functional properties of the Na,K-ATPase. Single or multiple tryptophan substitutions in the beta subunits transmembrane domain had no significant effect on the structural maturation of alpha subunits expressed in Xenopus oocytes nor on the level of expression of functional Na,K pumps at the cell surface. Furthermore, tryptophan substitutions in regions of the transmembrane alpha-helix containing two GXXXG transmembrane helix interaction motifs or a cysteine residue, which can be cross-linked to transmembrane helix M8 of the alpha subunit, had no effect on the apparent K(+) affinity of Na,K-ATPase. On the other hand, substitutions by tryptophan, serine, alanine, or cysteine, but not by phenylalanine of two highly conserved tyrosine residues, Tyr(40) and Tyr(44), on another face of the transmembrane helix, perturb the transport kinetics of Na,K pumps in an additive way. These results indicate that at least two faces of the beta subunits transmembrane helix contribute to inter- or intrasubunit interactions and that two tyrosine residues aligned in the beta subunits transmembrane alpha-helix are determinants of intrinsic transport characteristics of Na,K-ATPase.     

Depolymerization of phospholamban in the presence of calcium pump: a fluorescence energy transfer study

Phospholamban (PLB), a 52-amino acid protein, regulates the Ca-ATPase (calcium pump) in cardiac sarcoplasmic reticulum (SR) through PLB phosphorylation mediated by beta-adrenergic stimulation. The mobility of PLB on SDS-PAGE indicates a homopentamer, and it has been proposed that the pentameric structure of PLB is important for its regulatory function. However, the oligomeric structure of PLB must be determined in its native milieu, a lipid bilayer containing the Ca-ATPase. Here we have used fluorescence energy transfer (FET) to study the oligomeric structure of PLB in SDS and dioleoylphosphatidylcholine (DOPC) lipid bilayers reconstituted in the absence and presence of Ca-ATPase. PLB was labeled, specifically at Lys 3 in the cytoplasmic domain, with amine-reactive fluorescent donor/acceptor pairs. FET between donor- and acceptor-labeled subunits of PLB in SDS solution and DOPC lipid bilayers indicated the presence of PLB oligomers. The dependence of FET efficiency on the fraction of acceptor-labeled PLB in DOPC bilayers indicated that it is predominantly an oligomer having 9-11 subunits, with approximately 10% of the PLB as monomer, and the distance between dyes on adjacent PLB subunits is 0.9 +/- 0.1 nm. When labeled PLB was reconstituted with purified Ca-ATPase, FET indicated the depolymerization of PLB into smaller oligomers having an average of 5 subunits, with a concomitant increase in the fraction of monomer to 30-40% and a doubling of the intersubunit distance. We conclude that PLB exists primarily as an oligomer in membranes, and the Ca-ATPase affects the structure of this oligomer, but the Ca-ATPase binds preferentially to the monomer and/or small oligomers. These results suggest that the active inhibitory species of PLB is a monomer or an oligomer having fewer than 5 subunits.     

A fluorescence energy transfer method for analyzing protein oligomeric structure: application to phospholamban

We have developed a method using fluorescence energy transfer (FET) to analyze protein oligomeric structure. Two populations of a protein are labeled with fluorescent donor and acceptor, respectively, then mixed at a defined donor/acceptor ratio. A theoretical simulation, assuming random mixing and association among protein subunits in a ring-shaped homo-oligomer, was used to determine the dependence of FET on the number of subunits, the distance between labeled sites on different subunits, and the fraction of subunits remaining monomeric. By measuring FET as a function of the donor/acceptor ratio, the above parameters of the oligomeric structure can be resolved over a substantial range of their values. We used this approach to investigate the oligomeric structure of phospholamban (PLB), a 52-amino acid protein in cardiac sarcoplasmic reticulum (SR). Phosphorylation of PLB regulates the SR Ca-ATPase. Because PLB exists primarily as a homopentamer on sodium dodecyl sulfate polyacrylamide gel electrophoresis, it has been proposed that the pentameric structure of PLB is important for its regulatory function. However, this hypothesis must be tested by determining directly the oligomeric structure of PLB in the lipid membrane. To accomplish this goal, PLB was labeled at Lys-3 in the cytoplasmic domain, with two different amine-reactive donor/acceptor pairs, which gave very similar FET results. In detergent solutions, FET was not observed unless the sample was first boiled to facilitate subunit mixing. In lipid bilayers, FET was observed at 25 degrees C without boiling, indicating a dynamic equilibrium among PLB subunits in the membrane. Analysis of the FET data indicated that the dye-labeled PLB is predominantly in oligomers having at least 8 subunits, that 7-23% of the PLB subunits are monomeric, and that the distance between dyes on adjacent PLB subunits is about 10 A. A point mutation of PLB (L37A) that runs as monomer on SDS-PAGE showed no energy transfer, confirming its monomeric state in the membrane. We conclude that FET is a powerful approach for analyzing the oligomeric structure of PLB, and this method is applicable to other oligomeric proteins.     

Rational design of peptide inhibitors of the sarcoplasmic reticulum calcium pump

The sequence of phospholamban (PLB) is practically invariant among mammalian species. The hydrophobic transmembrane domain has 10 leucine and 8 isoleucine residues. Two roles have been proposed for the leucines; one subset stabilizes PLB oligomers, while a second subset physically interacts with SERCA. On the basis of the sequence of the PLB transmembrane domain, we chemically synthesized a series of peptides and tested their ability to regulate SERCA in reconstituted membranes. In all, eight peptides were studied: a peptide corresponding to the null-cysteine transmembrane domain of PLB (TM-Ala-PLB), two polyleucine peptides (Leu18 and Leu24), polyalanine peptides containing 4, 7, and 12 leucine residues (Leu4, Leu7, and Leu12, respectively), and a polyalanine peptide containing the 9 leucine residues present in the transmembrane domain of PLB with and without the essential Asn34 residue (Asn1Leu9 and Leu9, respectively). With the exception of Leu18, co-reconstitution of the peptides revealed effects on the apparent calcium affinity of SERCA. The TM-Ala-PLB peptide possessed approximately 70% of the inhibitory function of wild-type PLB. The remaining peptides exhibited significant inhibitory activity decreasing in the following order: Leu12, Leu9, Leu24, Leu7, and Leu4. Replacing Asn34 of PLB in the Leu9 peptide resulted in superinhibition of SERCA. On the basis of these observations, we conclude that a partial requirement for SERCA inhibition is met by a simple hydrophobic surface on a transmembrane alpha-helix. In addition, the superinhibition observed for the Asn34-containing peptide suggests that the model peptides mimic the inhibitory properties of PLB. A model is presented in which surface complementarity around key amino acid positions is enhanced in the interaction with SERCA.     

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.     

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.     

Structural characterization of recombinant soluble rat neuroligin 1: mapping of secondary structure and glycosylation by mass spectrometry

Neuroligins (NLs) are a family of transmembrane proteins that function in synapse formation and/or remodeling by interacting with beta-neurexins (beta-NXs) to form heterophilic cell adhesions. The large N-terminal extracellular domain of NLs, required for beta-NX interactions, has sequence homology to the alpha/beta hydrolase fold superfamily of proteins. By peptide mapping and mass spectrometric analysis of a soluble recombinant form of NL1, several structural features of the extracellular domain have been established. Of the nine cysteine residues in NL1, eight are shown to form intramolecular disulfide bonds. Disulfide pairings of Cys 117 to Cys 153 and Cys 342 to Cys 353 are consistent with disulfide linkages that are conserved among the family of alpha/beta hydrolase proteins. The disulfide bond between Cys 172 and Cys 181 occurs within a region of the protein encoded by an alternatively spliced exon. The disulfide pairing of Cys 512 and Cys 546 in NL1 yields a structural motif unique to the NLs, since these residues are highly conserved. The potential N-glycosylation sequons in NL1 at Asn 109, Asn 303, Asn 343, and Asn 547 are shown occupied by carbohydrate. An additional consensus sequence for N-glycosylation at Asn 662 is likely occupied. Analysis of N-linked oligosaccharide content by mass matching paradigms reveals significant microheterogeneous populations of complex glycosyl moieties. In addition, O-linked glycosylation is observed in the predicted stalk region of NL1, prior to the transmembrane spanning domain. From predictions based on sequence homology of NL1 to acetylcholinesterase and the molecular features of NL1 established from mass spectrometric analysis, a novel topology model for NL three-dimensional structure has been constructed.     

Serine 16 phosphorylation induces an order-to-disorder transition in monomeric phospholamban

Phospholamban (PLB) is a 52 amino acid membrane-endogenous regulator of the sarco(endo)plasmic calcium adenosinetriphosphatase (SERCA) in cardiac muscle. PLB's phosphorylation and dephosphorylation at S16 modulate its regulatory effect on SERCA by an undetermined mechanism. In this paper, we use multidimensional (1)H/(15)N solution NMR methods to establish the structural and dynamics basis for PLB's control of SERCA upon S16 phosphorylation. For our studies, we use a monomeric, fully active mutant of PLB, where C36, C41, and C46 have been mutated to A36, F41, and A46, respectively. Our data show that phosphorylation disrupts the "L-shaped" structure of monomeric PLB, causing significant unwinding of both the cytoplasmic helix (domain Ia) and the short loop (residues 17-21) connecting this domain to the transmembrane helix (domains Ib and II). Concomitant with this conformational transition, we also find pronounced changes in both the pico- to nanosecond and the micro- to millisecond time scale dynamics. The (1)H/(15)N heteronuclear NOE values for residues 1-25 are significantly lower than those of unphosphorylated PLB, with slightly lower NOE values in the transmembrane domain, reflecting less restricted motion throughout the whole protein. These data are supported by the faster spin-lattice relaxation rates (R(1)) present in both the cytoplasmic and loop regions and by the enhanced spin-spin transverse relaxation rates (R(2)) observed in the transmembrane domain. These results demonstrate that while S16 phosphorylation induces a localized structural transition, changes in PLB's backbone dynamics are propagated throughout the protein backbone. We propose that the regulatory mechanism of PLB phosphorylation involves an order-to-disorder transition, resulting in a decrease in the PLB inhibition of SERCA.     

Electron paramagnetic resonance reveals a large-scale conformational change in the cytoplasmic domain of phospholamban upon binding to the sarcoplasmic reticulum Ca-ATPase

We used EPR spectroscopy to probe directly the interaction between phospholamban (PLB) and its regulatory target, the sarcoplasmic reticulum Ca-ATPase (SERCA). Synthetic monomeric PLB was prepared with a single cytoplasmic cysteine at residue 11, which was then spin labeled. PLB was reconstituted into membranes in the presence or absence of SERCA, and spin label mobility and accessibility were measured. The spin label was quite rotationally mobile in the absence of SERCA, but became more restricted in the presence of SERCA. SERCA also decreased the dependence of spin label mobility on PLB concentration in the membrane, indicating that SERCA reduces PLB-PLB interactions. The spin label MTSSL, attached to Cys11 on PLB by a disulfide bond, was stable at position 11 in the absence of SERCA. In the presence of SERCA, the spin label was released and a covalent bond was formed between PLB and SERCA, indicating direct interaction of one or more SERCA cysteine residues with Cys11 on PLB. The accessibility of the PLB-bound spin label IPSL to paramagnetic agents, localized in different phases of the membrane, indicates that SERCA greatly reduces the level of interaction of the spin label with the membrane surface. We propose that the cytoplasmic domain of PLB associates with the lipid surface, and that association with SERCA induces a major conformational change in PLB in which the cytoplasmic domain is drawn away from the lipid surface by SERCA.