Xiaoqiong Dong scite author profile

We have used time-resolved fluorescence resonance energy transfer (TR-FRET) to characterize the interaction between phospholamban (PLB) and the sarcoplasmic reticulum (SR) Ca-ATPase (SERCA) under conditions that relieve SERCA inhibition. Unphosphorylated PLB inhibits SERCA in cardiac SR, but inhibition is relieved by either micromolar Ca2+ or PLB phosphorylation. In both cases, it has been proposed that inhibition is relieved by dissociation of the complex. To test this hypothesis, we attached fluorophores to the cytoplasmic domains of SERCA and PLB, and reconstituted them functionally in lipid bilayers. TR-FRET, which permitted simultaneous measurement of SERCA-PLB binding and structure, was measured as a function of PLB phosphorylation and [Ca2+]. In all cases, two structural states of the SERCA-PLB complex were resolved, probably corresponding to the previously described T and R structural states of the PLB cytoplasmic domain. Phosphorylation of PLB at S16 completely relieved inhibition, partially dissociated the SERCA-PLB complex, and shifted the T/R equilibrium within the bound complex toward the R state. Since the PLB concentration in cardiac SR is at least 10 times that in our FRET measurements, we calculate that most of SERCA contains bound phosphorylated PLB in cardiac SR, even after complete phosphorylation. 4 μM Ca2+ completely relieved inhibition but did not induce a detectable change in SERCA-PLB binding or cytoplasmic domain structure, suggesting a mechanism involving structural changes in SERCA’s transmembrane domain. We conclude that Ca2+ and PLB phosphorylation relieve SERCA-PLB inhibition by distinct mechanisms, but both are achieved primarily by structural changes within the SERCA-PLB complex, not by dissociation of that complex.

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Structural and Functional Dynamics of an Integral Membrane Protein Complex Modulated by Lipid Headgroup Charge

James

Dong

et al. 2012

Journal of Molecular Biology

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We have used membrane surface charge to modulate the structural dynamics of an integral membrane protein, phospholamban (PLB), and thereby its functional inhibition of the sarcoplasmic reticulum Ca-ATPase (SERCA). It was previously shown by EPR, in vesicles of neutral lipids, that the PLB cytoplasmic domain is in equilibrium between an ordered T state and a dynamically disordered R state, and that phosphorylation of PLB increases the R state and relieves SERCA inhibition, suggesting that R is less inhibitory. Here we sought to control the T/R equilibrium by an alternative means – varying the lipid headgroup charge, thus perturbing the electrostatic interaction of PLB’s cationic cytoplasmic domain with the membrane surface. We resolved the T and R states not only by EPR in the absence of SERCA, but also by time-resolved fluorescence resonance energy transfer (TR-FRET) from SERCA to PLB, thus probing directly the SERCA-PLB complex. Compared to neutral lipids, anionic lipids increased both the T population and SERCA inhibition, while cationic lipids had the opposite effects. In contrast to conventional models, decreased inhibition was not accompanied by decreased binding. We conclude that PLB binds to SERCA in two distinct structural states of the cytoplasmic domain, an inhibitory T state that interacts strongly with the membrane surface, and a less inhibitory R state that interacts more strongly with the anionic SERCA cytoplasmic domain. Modulating membrane surface charge provides an effective way of investigating the correlation between structural dynamics and function of integral membrane proteins.

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Synthetic Phosphopeptides Enable Quantitation of the Content and Function of the Four Phosphorylation States of Phospholamban in Cardiac Muscle

Ablorh

Dong

James

et al. 2014

Journal of Biological Chemistry

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Background: Phosphorylation of phospholamban regulates cardiac calcium transport, but the content and function of the four phosphorylation states of phospholamban are unknown. Results: Synthetic phosphopeptides solved both problems. Conclusion:The phosphorylation states were quantified in normal and hypertrophic pig hearts, and each has a distinct effect on calcium transport. Significance: This information is needed for improved diagnosis and treatment of heart failure.

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Synergistic FRET assays for drug discovery targeting RyR2 channels

Rebbeck

Ginsburg

et al. 2022

Journal of Molecular and Cellular Cardiology

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Protein Kinase a Activation Reduces Calmodulin-Ryanodine Affinity in R176Q/+ and R2474S/+ Knock-in Mouse

Uchinoumi

Stefanon

Said

et al. 2017

Journal of Cardiac Failure

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Xiaoqiong Dong

Time-resolved FRET reveals the structural mechanism of SERCA–PLB regulation

Structural and Functional Dynamics of an Integral Membrane Protein Complex Modulated by Lipid Headgroup Charge

Synthetic Phosphopeptides Enable Quantitation of the Content and Function of the Four Phosphorylation States of Phospholamban in Cardiac Muscle

Synergistic FRET assays for drug discovery targeting RyR2 channels

Protein Kinase a Activation Reduces Calmodulin-Ryanodine Affinity in R176Q/+ and R2474S/+ Knock-in Mouse

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