Abstract

The goal of this research is to determine the molecular mechanisms of catalysis and regulation of active calcium transport in sarcoplasmic reticulum (SR) in skeletal and cardiac muscle. The focus is on the Ca-ATPase, the integral membrane enzyme that pumps calcium into the SR and thus relaxes the muscle, and phospholamban (PLB), the integral membrane peptide involved in regulating the Ca-ATPase in the heart. Our previous work on skeletal muscle, which contains a very similar Ca-ATPase but no PLB, indicates that Ca-ATPase activity is quite dependent on the molecular dynamics and interactions of the SR membrane, including lipid chain motions, lipid-protein interactions, protein dynamics, and protein-protein interactions. In our future work, we will test specific mechanistic hypotheses for these correlations, and we will increase our focus on the study of cardiac SR. We will continue to focus on spectroscopic probe methods to analyze molecular dynamics and interactions, and we will expand our use of biochemical kinetics and molecular genetics to determine more precisely the relationship between physics and function. We will pursue the following specific aims: (1) Develop improved EPR and optical spectroscopic methods for studying membrane molecular dynamics, using sarcoplasmic reticulum (SR) as a model system to demonstrate these techniques. (2) Investigate the oligomeric structure and dynamics of the Ca-ATPase, to determine what changes in molecular motions and interactions are coupled to the Ca-ATPase reaction cycle. (3) Investigate the oligomeric structure and dynamics of phospholamban, in order to test specific models for the changes induced by phosphorylation. (4) Use spectroscopy to probe the interactions between the Ca-ATPase and phospholamban, in order to test specific models for the mechanism of calcium pump regulation. The proposed research brings together a powerful combination of techniques, from biophysics to molecular genetics, to solve the molecular mechanism of calcium transport regulation, which is fundamental to understanding muscle function and malfunction. More generally, the techniques we develop and the lessons we learn about this well-defined system will have broad implications for studying the role of molecular dynamics and interactions in membrane energy transduction mechanisms.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM027906-23
Application #
6635849
Study Section
Biophysical Chemistry Study Section (BBCB)
Program Officer
Chin, Jean
Project Start
1980-04-01
Project End
2004-02-29
Budget Start
2003-03-01
Budget End
2004-02-29
Support Year
23
Fiscal Year
2003
Total Cost
$415,786
Indirect Cost

  Institution

Name
University of Minnesota Twin Cities
Department
Biochemistry
Type
Schools of Medicine
DUNS #
555917996
City
Minneapolis
State
MN
Country
United States
Zip Code
55455

  Publications

Martin, Peter D; James, Zachary M; Thomas, David D (2018) Effect of Phosphorylation on Interactions between Transmembrane Domains of SERCA and Phospholamban. Biophys J 114:2573-2583
Stroik, Daniel R; Yuen, Samantha L; Janicek, Kevyn A et al. (2018) Targeting protein-protein interactions for therapeutic discovery via FRET-based high-throughput screening in living cells. Sci Rep 8:12560
Nelson, Sarah E D; Ha, Kim N; Gopinath, Tata et al. (2018) Effects of the Arg9Cys and Arg25Cys mutations on phospholamban's conformational equilibrium in membrane bilayers. Biochim Biophys Acta Biomembr 1860:1335-1341
Schaaf, Tory M; Peterson, Kurt C; Grant, Benjamin D et al. (2017) Spectral Unmixing Plate Reader: High-Throughput, High-Precision FRET Assays in Living Cells. SLAS Discov 22:250-261
Schaaf, Tory M; Peterson, Kurt C; Grant, Benjamin D et al. (2017) High-Throughput Spectral and Lifetime-Based FRET Screening in Living Cells to Identify Small-Molecule Effectors of SERCA. SLAS Discov 22:262-273
Rebbeck, Robyn T; Nitu, Florentin R; Rohde, David et al. (2016) S100A1 Protein Does Not Compete with Calmodulin for Ryanodine Receptor Binding but Structurally Alters the Ryanodine ReceptorĀ·Calmodulin Complex. J Biol Chem 291:15896-907
Autry, Joseph M; Thomas, David D; Espinoza-Fonseca, L Michel (2016) Sarcolipin Promotes Uncoupling of the SERCA Ca2+ Pump by Inducing a Structural Rearrangement in the Energy-Transduction Domain. Biochemistry 55:6083-6086
McCaffrey, Jesse E; James, Zachary M; Svensson, Bengt et al. (2016) A bifunctional spin label reports the structural topology of phospholamban in magnetically-aligned bicelles. J Magn Reson 262:50-56
Svensson, Bengt; Autry, Joseph M; Thomas, David D (2016) Molecular Modeling of Fluorescent SERCA Biosensors. Methods Mol Biol 1377:503-22
Espinoza-Fonseca, L Michel; Autry, Joseph M; Thomas, David D (2015) Sarcolipin and phospholamban inhibit the calcium pump by populating a similar metal ion-free intermediate state. Biochem Biophys Res Commun 463:37-41

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