Your search keyword '"Sean C. Little"' showing total 3 results

1. Eps15 Homology Domain-containing Protein 3 Regulates Cardiac T-type Ca2+ Channel Targeting and Function in the Atria

Author

Crystal F. Kline, Thomas J. Hund, Sean C. Little, Hassan Musa, Hamid Band, Michael A. Makara, Peter J. Mohler, John D. Higgins, and Jerry Curran

Subjects

Cardiac function curve, medicine.medical_specialty, Endosome, Heart Ventricles, Endosomes, Biology, Biochemistry, Substrate Specificity, Calcium Channels, T-Type, Electrocardiography, Mice, Heart Rate, Internal medicine, Cardiac conduction, medicine, Animals, Ankyrin, Myocytes, Cardiac, Heart Atria, Cytoskeleton, Molecular Biology, Alleles, Ion channel, Oligonucleotide Array Sequence Analysis, Mice, Knockout, chemistry.chemical_classification, Muscle Cells, Molecular Bases of Disease, Cell Biology, Protein Structure, Tertiary, Cell biology, Phenotype, Endocrinology, Gene Expression Regulation, chemistry, Membrane protein, Cardiovascular Diseases, Mutation, Endosomal transport, cardiovascular system, Calcium, Carrier Proteins, Protein Binding

Abstract

Proper trafficking of membrane-bound ion channels and transporters is requisite for normal cardiac function. Endosome-based protein trafficking of membrane-bound ion channels and transporters in the heart is poorly understood, particularly in vivo. In fact, for select cardiac cell types such as atrial myocytes, virtually nothing is known regarding endosomal transport. We previously linked the C-terminal Eps15 homology domain-containing protein 3 (EHD3) with endosome-based protein trafficking in ventricular cardiomyocytes. Here we sought to define the roles and membrane protein targets for EHD3 in atria. We identify the voltage-gated T-type Ca2+ channels (CaV3.1, CaV3.2) as substrates for EHD3-dependent trafficking in atria. Mice selectively lacking EHD3 in heart display reduced expression and targeting of both Cav3.1 and CaV3.2 in the atria. Furthermore, functional experiments identify a significant loss of T-type-mediated Ca2+ current in EHD3-deficient atrial myocytes. Moreover, EHD3 associates with both CaV3.1 and CaV3.2 in co-immunoprecipitation experiments. T-type Ca2+ channel function is critical for proper electrical conduction through the atria. Consistent with these roles, EHD3-deficient mice demonstrate heart rate variability, sinus pause, and atrioventricular conduction block. In summary, our findings identify CaV3.1 and CaV3.2 as substrates for EHD3-dependent protein trafficking in heart, provide in vivo data on endosome-based trafficking pathways in atria, and implicate EHD3 as a key player in the regulation of atrial myocyte excitability and cardiac conduction. Background: Endosome-based protein trafficking in the heart is poorly understood. Results: Functional targeting and expression of the T-type Ca2+ channel (TTCC) in the atria requires the endosomal protein, EHD3. Conclusion: Impaired endosomal transport leads to cardiac rhythm and conduction disorders. Significance: Understanding endosome-based protein trafficking in the heart may provide new therapeutic targets for cardiovascular disease.

Published

2015

2. Molecular Mechanisms Underlying Cardiac Protein Phosphatase 2A Regulation in Heart

Author

Wen Dun, Patrick Wright, Sean T. DeGrande, Cynthia A. Carnes, Jedidiah S. Snyder, Ahmet Kilic, Nathaniel P. Murphy, Robert S.D. Higgins, Derek J. Nixon, Mark E. Anderson, Penelope A. Boyden, Sean C. Little, Thomas J. Hund, Philip F. Binkley, and Peter J. Mohler

Subjects

Transcription, Genetic, Immunoprecipitation, Protein subunit, Phosphatase, macromolecular substances, Biology, Polymerase Chain Reaction, environment and public health, Biochemistry, Mice, Dogs, Animals, Humans, Ankyrin, Protein Phosphatase 2, Molecular Biology, DNA Primers, chemistry.chemical_classification, Base Sequence, Kinase, Myocardium, Molecular Bases of Disease, Cell Biology, Protein phosphatase 2, Cell biology, enzymes and coenzymes (carbohydrates), chemistry, Protein Biosynthesis, embryonic structures, cardiovascular system, Phosphorylation, Signal transduction, Signal Transduction

Abstract

Kinase/phosphatase balance governs cardiac excitability in health and disease. Although detailed mechanisms for cardiac kinase regulation are established, far less is known regarding cardiac protein phosphatase 2A (PP2A) regulation. This is largely due to the complexity of the PP2A holoenzyme structure (combinatorial assembly of three subunit enzyme from >17 subunit genes) and the inability to segregate "global" PP2A function from the activities of multiple "local" holoenzyme populations. Here we report that PP2A catalytic, regulatory, and scaffolding subunits are tightly regulated at transcriptional, translational, and post-translational levels to tune myocyte function at base line and in disease. We show that past global read-outs of cellular PP2A activity more appropriately represent the collective activity of numerous individual PP2A holoenzymes, each displaying a specific subcellular localization (dictated by select PP2A regulatory subunits) as well as local specific post-translational catalytic subunit methylation and phosphorylation events that regulate local and rapid holoenzyme assembly/disassembly (via leucine carboxymethyltransferase 1/phosphatase methylesterase 1 (LCMT-1/PME-1). We report that PP2A subunits are selectively regulated between human and animal models, across cardiac chambers, and even within specific cardiac cell types. Moreover, this regulation can be rapidly tuned in response to cellular activation. Finally, we report that global PP2A is altered in human and experimental models of heart disease, yet each pathology displays its own distinct molecular signature though specific PP2A subunit modulatory events. These new data provide an initial view into the signaling pathways that govern PP2A function in heart but also establish the first step in defining specific PP2A regulatory targets in health and disease.

Published

2013

3. AMP-activated Protein Kinase Phosphorylates Cardiac Troponin I at Ser-150 to Increase Myofilament Calcium Sensitivity and Blunt PKA-dependent Function

Author

Janel Jin, Brandon J. Biesiadecki, Elizabeth A. Brundage, Jonathan P. Davis, Sean C. Little, Ariyoporn Thawornkaiwong, Benjamin R. Nixon, and R. John Solaro

Subjects

inorganic chemicals, medicine.medical_specialty, Myofilament, macromolecular substances, AMP-Activated Protein Kinases, environment and public health, Biochemistry, Myofibrils, AMP-activated protein kinase, Internal medicine, Troponin I, Serine, medicine, Animals, Humans, Phosphorylation, Protein kinase A, Molecular Biology, biology, Cardiac muscle, AMPK, Cell Biology, musculoskeletal system, Myocardial Contraction, Rats, Cell biology, enzymes and coenzymes (carbohydrates), Endocrinology, medicine.anatomical_structure, Protein Structure and Folding, cardiovascular system, biology.protein, bacteria, Calcium, Cattle, Rabbits, PRKCE, Signal Transduction

Abstract

AMP-activated protein kinase (AMPK) is an energy-sensing enzyme central to the regulation of metabolic homeostasis. In the heart AMPK is activated during cardiac stress-induced ATP depletion and functions to stimulate metabolic pathways that restore the AMP/ATP balance. Recently it was demonstrated that AMPK phosphorylates cardiac troponin I (cTnI) at Ser-150 in vitro. We sought to determine if the metabolic regulatory kinase AMPK phosphorylates cTnI at Ser-150 in vivo to alter cardiac contractile function directly at the level of the myofilament. Rabbit cardiac myofibrils separated by two-dimensional isoelectric focusing subjected to a Western blot with a cTnI phosphorylation-specific antibody demonstrates that cTnI is endogenously phosphorylated at Ser-150 in the heart. Treatment of myofibrils with the AMPK holoenzyme increased cTnI Ser-150 phosphorylation within the constraints of the muscle lattice. Compared with controls, cardiac fiber bundles exchanged with troponin containing cTnI pseudo-phosphorylated at Ser-150 demonstrate increased sensitivity of calcium-dependent force development, blunting of both PKA-dependent calcium desensitization, and PKA-dependent increases in length dependent activation. Thus, in addition to the defined role of AMPK as a cardiac metabolic energy gauge, these data demonstrate AMPK Ser-150 phosphorylation of cTnI directly links the regulation of cardiac metabolic demand to myofilament contractile energetics. Furthermore, the blunting effect of cTnI Ser-150 phosphorylation cross-talk can uncouple the effects of myofilament PKA-dependent phosphorylation from β-adrenergic signaling as a novel thin filament contractile regulatory signaling mechanism.

Published

2012