Martin Gustavsson

Allosteric regulation of SERCA by phosphorylation-mediated conformational shift of phospholamban

Significance The sarcoplasmic reticulum Ca2+-ATPase (SERCA)/phospholamban complex regulates cardiac muscle contractility by controlling Ca2+ transport from the cytosol to the lumen of the sarcoplasmic reticulum. By mapping the interactions between these two membrane proteins, we found that SERCA function depends on the equilibria between transient conformational states of phospholamban. Phosphorylation of phospholamban shifts the equilibria, enhancing SERCA function. This mechanism explains why tuning phospholamban’s structural dynamics can modulate SERCA function and may aid in designing innovative therapeutic approaches to heart failure. The membrane protein complex between the sarcoplasmic reticulum Ca2+-ATPase (SERCA) and phospholamban (PLN) controls Ca2+ transport in cardiomyocytes, thereby modulating cardiac contractility. β-Adrenergic-stimulated phosphorylation of PLN at Ser-16 enhances SERCA activity via an unknown mechanism. Using solid-state nuclear magnetic resonance spectroscopy, we mapped the physical interactions between SERCA and both unphosphorylated and phosphorylated PLN in membrane bilayers. We found that the allosteric regulation of SERCA depends on the conformational equilibrium of PLN, whose cytoplasmic regulatory domain interconverts between three different states: a ground T state (helical and membrane associated), an excited R state (unfolded and membrane detached), and a B state (extended and enzyme-bound), which is noninhibitory. Phosphorylation at Ser-16 of PLN shifts the populations toward the B state, increasing SERCA activity. We conclude that PLN’s conformational equilibrium is central to maintain SERCA’s apparent Ca2+ affinity within a physiological window. This model represents a paradigm shift in our understanding of SERCA regulation by posttranslational phosphorylation and suggests strategies for designing innovative therapeutic approaches to enhance cardiac muscle contractility.

cAMP-Dependent Protein Kinase A Selects the Excited State of the Membrane Substrate Phospholamban

Phosphorylation of membrane proteins is a central regulatory and signaling mechanism across cell compartments. However, the recognition process and phosphorylation mechanism of membrane-bound substrates by kinases are virtually unknown. cAMP-dependent protein kinase A (PKA) is a ubiquitous enzyme that phosphorylates several soluble and membrane-bound substrates. In cardiomyocytes, PKA targets phospholamban (PLN), a membrane protein that inhibits the sarcoplasmic reticulum Ca(2+)-ATPase (SERCA). In the unphosphorylated state, PLN binds SERCA, reducing the calcium uptake and generating muscle contraction. PKA phosphorylation of PLN at S16 in the cytoplasmic helix relieves SERCA inhibition, initiating muscle relaxation. Using steady-state kinetic assays, NMR spectroscopy, and molecular modeling, we show that PKA recognizes and phosphorylates the excited, membrane-detached R-state of PLN. By promoting PLN from a ground state to an excited state, we obtained a linear relationship between rate of phosphorylation and population of the excited state of PLN. The conformational equilibrium of PLN is crucial to regulate the extent of PLN phosphorylation and SERCA inhibition.

Probing ground and excited states of phospholamban in model and native lipid membranes by magic angle spinning NMR spectroscopy.

In this paper, we analyzed the ground and excited states of phospholamban (PLN), a membrane protein that regulates sarcoplasmic reticulum calcium ATPase (SERCA), in different membrane mimetic environments. Previously, we proposed that the conformational equilibria of PLN are central to SERCA regulation. Here, we show that these equilibria detected in micelles and bicelles are also present in native sarcoplasmic reticulum lipid membranes as probed by MAS solid-state NMR. Importantly, we found that the kinetics of conformational exchange and the extent of ground and excited states in detergent micelles and lipid bilayers are different, revealing a possible role of the membrane composition on the allosteric regulation of SERCA. Since the extent of excited states is directly correlated to SERCA inhibition, these findings open up the exciting possibility that calcium transport in the heart can be controlled by the lipid bilayer composition. This article is part of a Special Issue entitled: Membrane protein structure and function.

Activating and Deactivating Roles of Lipid Bilayers on the Ca 2+ -ATPase/Phospholamban Complex

The physicochemical properties of the lipid bilayer shape the structure and topology of membrane proteins and regulate their biological function. Here, we investigated the functional effects of various lipid bilayer compositions on the sarcoplasmic reticulum (SR) Ca(2+)-ATPase (SERCA) in the presence and absence of its endogenous regulator, phospholamban (PLN). In the cardiac muscle, SERCA hydrolyzes one ATP molecule to translocate two Ca(2+) ions into the SR membrane per enzymatic cycle. Unphosphorylated PLN reduces SERCAs affinity for Ca(2+) and affects the enzymatic turnover. We varied bilayer thickness, headgroup, and fluidity and found that both the maximal velocity (V(max)) of the enzyme and its apparent affinity for Ca(2+) (K(Ca)) are strongly affected. Our results show that (a) SERCAs V(max) has a biphasic dependence on bilayer thickness, reaching maximum activity with 22-carbon lipid chain length, (b) phosphatidylethanolamine (PE) and phosphatidylserine (PS) increase Ca(2+) affinity, and (c) monounsaturated lipids afford higher SERCA V(max) and Ca(2+) affinity than diunsaturated lipids. The presence of PLN removes the activating effect of PE and shifts SERCAs activity profile, with a maximal activity reached in bilayers with 20-carbon lipid chain length. Our results in synthetic lipid systems compare well with those carried out in native SR lipids. Importantly, we found that specific membrane compositions closely reproduce PLN effects (V(max) and K(Ca)) found in living cells, reconciling an ongoing controversy regarding the regulatory role of PLN on SERCA function. Taken with the physiological changes occurring in the SR membrane composition, these studies underscore a possible allosteric role of the lipid bilayers on the SERCA/PLN complex.

Paramagnetic-based NMR restraints lift residual dipolar coupling degeneracy in multidomain detergent-solubilized membrane proteins.

Residual dipolar couplings (RDCs) are widely used as orientation-dependent NMR restraints to improve the resolution of the NMR conformational ensemble of biomacromolecules and define the relative orientation of multidomain proteins and protein complexes. However, the interpretation of RDCs is complicated by the intrinsic degeneracy of analytical solutions and protein dynamics that lead to ill-defined orientations of the structural domains (ghost orientations). Here, we illustrate how restraints from paramagnetic relaxation enhancement (PRE) experiments lift the orientational ambiguity of multidomain membrane proteins solubilized in detergent micelles. We tested this approach on monomeric phospholamban (PLN), a 52-residue membrane protein, which is composed of two helical domains connected by a flexible loop. We show that the combination of classical solution NMR restraints (NOEs and dihedral angles) with RDC and PRE constraints resolves topological ambiguities, improving the convergence of the PLN structural ensemble and giving the depth of insertion of the protein within the micelle. The combination of RDCs with PREs will be necessary for improving the accuracy and precision of membrane protein conformational ensembles, where three-dimensional structures are dictated by interactions with the membrane-mimicking environment rather than compact tertiary folds common in globular proteins.

Structures of the Excited States of Phospholamban and Shifts in Their Populations upon Phosphorylation.

Phospholamban is an integral membrane protein that controls the calcium balance in cardiac muscle cells. As the function and regulation of this protein require the active involvement of low populated states in equilibrium with the native state, it is of great interest to acquire structural information about them. In this work, we calculate the conformations and populations of the ground state and the three main excited states of phospholamban by incorporating nuclear magnetic resonance residual dipolar couplings as replica-averaged structural restraints in molecular dynamics simulations. We then provide a description of the manner in which phosphorylation at Ser16 modulates the activity of the protein by increasing the sizes of the populations of its excited states. These results demonstrate that the approach that we describe provides a detailed characterization of the different states of phospholamban that determine the function and regulation of this membrane protein. We anticipate that the knowledge of conformational ensembles enable the design of new dominant negative mutants of phospholamban by modulating the relative populations of its conformational substates.

Synthesis of a-factor peptide from Saccharomyces cerevisiae and photoactive analogues via Fmoc solid phase methodology.

a-Factor from Saccharomyces cerevisiae is a farnesylated dodecapeptide involved in mating. The molecule binds to a G-protein coupled receptor and hence serves as a simple system for studying the interactions between prenylated molecules and their cognate receptors. Here, we describe the preparation of a-factor and two photoactive analogues via Fmoc solid-phase peptide synthesis using hydrazinobenzoyl AM NovaGel™ resin; the structure of the synthetic a-factor was confirmed by MS-MS analysis and NMR; the structures of the analogues were confirmed by MS-MS analysis. Using a yeast growth arrest assay, the analogues were found to have activity comparable to a-factor itself.

Ca2+ ATPase Conformational Transitions in Lipid Bilayers Mapped by Site-directed Ethylation and Solid-State NMR

To transmit signals across cellular compartments, many membrane-embedded enzymes undergo extensive conformational rearrangements. Monitoring these events in lipid bilayers by NMR at atomic resolution has been challenging due to the large size of these systems. It is further exacerbated for large mammalian proteins that are difficult to express and label with NMR-active isotopes. Here, we synthesized and engineered (13)C ethyl groups on native cysteines to map the structural transitions of the sarcoplasmic reticulum Ca(2+)-ATPase, a 110 kDa transmembrane enzyme that transports Ca(2+) into the sarcoplasmic reticulum. Using magic angle spinning NMR, we monitored the chemical shifts of the methylene and methyl groups of the derivatized cysteine residues along the major steps of the enzymatic cycle. The methylene chemical shifts are sensitive to the ATPase conformational changes induced upon nucleotide and Ca(2+) ion binding and are ideal probes for active and inactive states of the enzyme. This new approach is extendable to large mammalian enzymes and signaling proteins with native or engineered cysteine residues in their amino acid sequence.

Tuning the Structural Coupling Between the Transmembrane and Cytoplasmic Domains of Phospholamban to Control SERCA Inhibition

Phospholamban (PLN) is the endogenous inhibitor of the sarco(endo)plasmic reticulum Ca2+ ATPase (SERCA), the integral membrane enzyme responsible for 70% of the Ca2+ shuttling into the SR, inducing cardiac muscle relaxation in humans. Dysfunctions in SERCA:PLN interactions have been implicated as having a critical role in cardiac disease. Based on the success of the Chien Group with S16E PLN, a pseudo-phosphorylated PLN species which halted the progression of heart failure in animal models, we wish to further develop PLN species to improve SERCA function by rationally designing mutations based on the structural and biophysical data available on the system. The present study seeks to introduce single and multiple glycine mutations in the loop domain of PLN in order to tune the structural coupling between the cytoplasmic and transmembrane helix, and ascertain the effects on SERCA function. These studies further develop the model by which the control of enzyme function is performed by altering the structural dynamics of a small inhibitor can then be translated to other membrane enzymes, such as the Na/K-ATPase.

Structural Dynamics of Phosphorylated Pentameric Phospholamban in Lipid Membranes using a Combination of Solution and Solid-State NMR Spectroscopy

Phospholamban (PLN) is a 52-residue membrane protein that regulates the cardiac sarcoplasmic reticulum Ca2+ATPase (SERCA). PLN is in equilibrium between monomeric and pentameric species. The monomer binds to and decreases the rate of Ca2+ transport of SERCA. This inhibitory action is relieved upon PLN phosphorylation at Serine-16 and Threonine-17. Here, we present the structural dynamics of fully phosphorylated pentameric PLN by a combination of solution and solid-state NMR spectroscopy. SDS-PAGE analysis revealed a higher thermal stability of the phosphorylated pentameric PLN (at Ser-16, Thr-17 and both) with respect to the unphosphorylated protein when reconstituted in different lipids and detergents.Conventional T1, T2, and heteronuclear steady state NOEs experiments were used to probe fast (ps-ns) dynamics of the amide backbone upon phosphorylation at Ser-16, revealing a significant increase of the dynamics in this time scale. Slower (µs-ms) dynamics were probed by measuring rotating frame R(1rho) and R(2rho) dispersion curves using a new adiabatic irradiation scheme.The structural and topological effects of phosphorylation in pentameric PLN were investigated using solid-state NMR experiments on mechanically and magnetically oriented lipid systems. For the mechanically oriented samples, phosphorylated PLN was reconstituted in DOPC/DOPE lipid bilayers and uniaxially aligned between glass plates. For magnetically oriented samples, the protein was reconstituted in DMPC/Triton X-100 bicelles. Two-dimensional PISEMA and SAMPI4 experiments were used to determine the topology of PLN in lipid membranes. Chemical shifts anisotropy and dipolar coupling values were also used in combination with solution NMR restraints to determine a preliminary high-resolution structure of fully phosphorylated pentameric PLN.These studies reveal residue-by-residue details of the pentameric PLN structure and topology upon phosphorylation.