Your search keyword '"Hsu, Karen H."' showing total 13 results

1. Drosophila myosin mutants model the disparate severity of type 1 and type 2B distal arthrogryposis and indicate an enhanced actin affinity mechanism

Author

Guo, Yiming, Kronert, William A., Hsu, Karen H., Huang, Alice, Sarsoza, Floyd, Bell, Kaylyn M., Suggs, Jennifer A., Swank, Douglas M., and Bernstein, Sanford I.

Published

2020

2. Myosin Transducer Inter-Strand Communication Is Critical for Normal ATPase Activity and Myofibril Structure

Author

Kronert, William A., primary, Hsu, Karen H., additional, Madan, Aditi, additional, Sarsoza, Floyd, additional, Cammarato, Anthony, additional, and Bernstein, Sanford I., additional

Published

2022

3. The R369 Myosin Residue within Loop 4 Is Critical for Actin Binding and Muscle Function in Drosophila

Author

Trujillo, Adriana S., primary, Hsu, Karen H., additional, Viswanathan, Meera C., additional, Cammarato, Anthony, additional, and Bernstein, Sanford I., additional

Published

2022

4. Myosin dilated cardiomyopathy mutation S532P disrupts actomyosin interactions, leading to altered muscle kinetics, reduced locomotion, and cardiac dilation in Drosophila

Author

Trujillo, Adriana S., primary, Hsu, Karen H., additional, Puthawala, Joy, additional, Viswanathan, Meera C., additional, Loya, Amy, additional, Irving, Thomas C., additional, Cammarato, Anthony, additional, Swank, Douglas M., additional, and Bernstein, Sanford I., additional

Published

2021

5. Alternative N-terminal regions of Drosophila myosin heavy chain II regulate communication of the purine binding loop with the essential light chain

Author

Bloemink, Marieke J., primary, Hsu, Karen H., additional, Geeves, Michael A., additional, and Bernstein, Sanford I., additional

Published

2020

6. Reductions in ATPase activity, actin sliding velocity, and myofibril stability yield muscle dysfunction inDrosophilamodels of myosin-based Freeman–Sheldon syndrome

Author

Rao, Deepti S., primary, Kronert, William A., additional, Guo, Yiming, additional, Hsu, Karen H., additional, Sarsoza, Floyd, additional, and Bernstein, Sanford I., additional

Published

2019

7. Structural and Biochemical Mechanisms of Myosin-Induced Dilated Cardiomyopathy

Author

Hsu, Karen H., primary, Trujillo, Adriana, additional, Irving, Thomas C., additional, and Bernstein, Sanford I., additional

Published

2018

8. Reductions in ATPase activity, actin sliding velocity, and myofibril stability yield muscle dysfunction in Drosophilamodels of myosin-based Freeman–Sheldon syndrome

Author

Rao, Deepti S., Kronert, William A., Guo, Yiming, Hsu, Karen H., Sarsoza, Floyd, and Bernstein, Sanford I.

Abstract

Drosophilamodels of Freeman–Sheldon syndrome show dominant allele-specific defects, as in the human disease. Defective communication between the nucleotide-binding site of myosin and its force-producing lever arm disrupts ATPase activity, actin motility, muscle function, and myofibril stability.

Published

2019

9. Abstract 18852: Myofilament Length Dependent Activation: Role of Titin

Author

AIT MOU, Younss, primary, Hsu, Karen H, additional, Greaser, Marion, additional, Irving, Thomas C, additional, and deTombe, Pieter P, additional

Published

2014

10. Cardiac Thin Filament Structural Modulation by Sarcomere Length

Author

Aitmou, Younss, primary, Hsu, Karen H., additional, Kumar, Mohit, additional, Szczesna-Cordary, Danuta, additional, Greaser, Marion L., additional, Irving, Tom C., additional, and deTombe, Pieter P., additional

Published

2014

11. Titin-Based Modulation of Sarcomere Structure as Revealed by Equatorial X-Ray Diffraction

Author

Hsu, Karen H., primary, Ait-Mou, Younss, additional, de Tombe, Pieter P., additional, and Irving, Thomas C., additional

Published

2014

12. Impact of Troponin-I Phosphorylation on Human Cardiac Myofilament Function

Author

Hsu, Karen H., primary, Zhang, Menjie, additional, Witayavanitkul, Namthip, additional, Irving, Thomas C., additional, and de Tombe, Pieter P., additional

Published

2014

13. Reductions in ATPase activity, actin sliding velocity, and myofibril stability yield muscle dysfunction in Drosophila models of myosin-based Freeman-Sheldon syndrome.

Author

Rao DS, Kronert WA, Guo Y, Hsu KH, Sarsoza F, and Bernstein SI

Subjects

Animals, Animals, Genetically Modified, Disease Models, Animal, Flight, Animal, Heterozygote, Homozygote, Models, Molecular, Muscle, Skeletal ultrastructure, Mutation genetics, Myosins chemistry, Protein Domains, Reproducibility of Results, Actins metabolism, Adenosine Triphosphatases metabolism, Craniofacial Dysostosis physiopathology, Drosophila melanogaster metabolism, Muscle, Skeletal physiopathology, Myofibrils metabolism, Myosins metabolism

Abstract

Using Drosophila melanogaster, we created the first animal models for myosin-based Freeman-Sheldon syndrome (FSS), a dominant form of distal arthrogryposis defined by congenital facial and distal skeletal muscle contractures. Electron microscopy of homozygous mutant indirect flight muscles showed normal (Y583S) or altered (T178I, R672C) myofibril assembly followed by progressive disruption of the myofilament lattice. In contrast, all alleles permitted normal myofibril assembly in the heterozygous state but caused myofibrillar disruption during aging. The severity of myofibril defects in heterozygotes correlated with the level of flight impairment. Thus our Drosophila models mimic the human condition in that FSS mutations are dominant and display varied degrees of phenotypic severity. Molecular modeling indicates that the mutations disrupt communication between the nucleotide-binding site of myosin and its lever arm that drives force production. Each mutant myosin showed reduced in vitro actin sliding velocity, with the two more severe alleles significantly decreasing the catalytic efficiency of actin-activated ATP hydrolysis. The observed reductions in actin motility and catalytic efficiency may serve as the mechanistic basis of the progressive myofibrillar disarray observed in the Drosophila models as well as the prolonged contractile activity responsible for skeletal muscle contractures in FSS patients.

Published

2019