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257 results on '"Swank, Douglas M."'

9. A Restrictive Cardiomyopathy Mutation in an Invariant Proline at the Myosin Head/Rod Junction Enhances Head Flexibility and Function, Yielding Muscle Defects in Drosophila

Author

Achal, Madhulika, Trujillo, Adriana S., Melkani, Girish C., Farman, Gerrie P., Ocorr, Karen, Viswanathan, Meera C., Kaushik, Gaurav, Newhard, Christopher S., Glasheen, Bernadette M., Melkani, Anju, Suggs, Jennifer A., Moore, Jeffrey R., Swank, Douglas M., Bodmer, Rolf, Cammarato, Anthony, and Bernstein, Sanford I.

Published
2016
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28. 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
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29. A Drosophilacardiac myosin increases jump muscle stretch activation and shortening deactivation

Author

Bell, Kaylyn M., Brown, Alon T., Van Houten, Sarah K., Blice-Baum, Anna C., Kronert, William A., Loya, Amy K., Camillo, Jared Rafael T., Cammarato, Anthony, Corr, David T., Bernstein, Sanford I., and Swank, Douglas M.

Abstract

Stretch activation (SA), a delayed increase in force production following rapid muscle lengthening, is critical to the function of vertebrate cardiac muscle and insect asynchronous indirect flight muscle (IFM). SA enables or increases power generation in muscle types used in a cyclical manner. Recently, myosin isoform expression has been implicated as a mechanism for varying the amplitude of SA in some muscle types. For instance, we found that expressing a larval Drosophilamyosin isoform in a muscle type with minimal SA, the Drosophilajump muscle, substantially increased SA amplitude and enabled positive cyclical power generation. To test if other myosin isoforms could increase SA amplitude and if the Drosophilaheart benefits from SA, we identified two Drosophilacardiac myosin isoforms, CardM1 and CardM2, and expressed them in Drosophilajump muscle. CardM1, CardM2 and control jump muscle fibers all displayed the characteristic phase 3 of SA, with CardM2 SA amplitude ∼60% greater than that of CardM1 and control fibers. Increasing [Pi] from 0 mM to 16 mM increased CardM2 SA tension amplitude by 74%, yet had minimal or no effect on CardM1 or control muscle SA amplitude. CardM2 displayed the most prominent phase 3 dip when we induced shortening deactivation (SD), a delayed decrease in force following muscle shortening. The magnitude of CardM2 shortening deactivation tension was ∼50% greater than control or CardM1 fibers. This along with its greater stretch activated tension caused CardM2 to be the only isoform to produce positive power when its fiber length was sinusoidally oscillated. The results support our hypotheses that some myosin isoforms enable greater SA tension levels and suggest that the Drosophilaheart is benefiting from SA and SD in a manner similar to vertebrate hearts.

Published
2025
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30. The converter domain modulates kinetic properties of Drosophila myosin

Author

Littlefield, Kimberly Palmiter, Swank, Douglas M., Sanchez, Becky M., Knowles, Aileen F., Warshaw, David M., and Bernstein, Sanford I.

Subjects
Drosophila -- Research, Molecular dynamics -- Research, Cell research, Biological sciences
Abstract

Recently the converter domain, an integral part of the 'mechanical element' common to all molecular motors, was proposed to modulate the kinetic properties of Drosophila chimeric myosin isoforms. Here we investigated the molecular basis of actin filament velocity ([V.sub.actin]) changes previously observed with the chimeric EMB-IC and IFI-EC myosin proteins [the embryonic body wall muscle (EMB) and indirect flight muscle isoforms (IFI) with genetic substitution of the IFI and EMB converter domains, respectively]. In the laser trap assay the IFI and IFI-EC myosins generate the same unitary step displacement (IFI = 7.3 [+ or -] 1.0 nm, IFI-EC = 5.8 [+ or -] 0.9 nm; means [+ or -] SE). Thus converter-mediated differences in the kinetics of strong actin-myosin binding, rather than the mechanical capabilities of the protein, must account for the observed [V.sub.actin] values. Basal and actin-activated ATPase assays and skinned fiber mechanical experiments definitively support a role for the converter domain in modulating the kinetic properties of the myosin protein. We propose that the converter domain kinetically couples the [P.sub.i] and ADP release steps that occur during the cross-bridge cycle. actin-activated adenosine 5'-triphosphatase activity; unitary step displacement; skinned fiber preparations; cross-bridge cycle; chemomechanical coupling

Published
2003

36. Shortening deactivation: quantifying a critical component of cyclical muscle contraction.

Author

Loya, Amy K., Van Houten, Sarah K., Glasheen, Bernadette M., and Swank, Douglas M.

Subjects
MUSCLE contraction, DROSOPHILA
Abstract

A muscle undergoing cyclical contractions requires fast and efficient muscle activation and relaxation to generate high power with relatively low energetic cost. To enhance activation and increase force levels during shortening, some muscle types have evolved stretch activation (SA), a delayed increased in force following rapid muscle lengthening. SA's complementary phenomenon is shortening deactivation (SD), a delayed decrease in force following muscle shortening. SD increases muscle relaxation, which decreases resistance to subsequent muscle lengthening. Although it might be just as important to cyclical power output, SD has received less investigation than SA. To enable mechanistic investigations into SD and quantitatively compare it to SA, we developed a protocol to elicit SA and SD from Drosophila and Lethocerus indirect flight muscles (IFM) and Drosophila jump muscle. When normalized to isometric tension, Drosophila IFM exhibited a 118% SD tension decrease, Lethocerus IFM dropped by 97%, and Drosophila jump muscle decreased by 37%. The same order was found for normalized SA tension: Drosophila IFM increased by 233%, Lethocerus IFM by 76%, and Drosophila jump muscle by only 11%. SD occurred slightly earlier than SA, relative to the respective length change, for both IFMs; but SD was exceedingly earlier than SA for jump muscle. Our results suggest SA and SD evolved to enable highly efficient IFM cyclical power generation and may be caused by the same mechanism. However, jump muscle SA and SD mechanisms are likely different, and may have evolved for a role other than to increase the power output of cyclical contractions. [ABSTRACT FROM AUTHOR]

Published
2022
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49. Author response: Prolonged cross-bridge binding triggers muscle dysfunction in a Drosophila model of myosin-based hypertrophic cardiomyopathy

Author

Kronert, William A, primary, Bell, Kaylyn M, additional, Viswanathan, Meera C, additional, Melkani, Girish C, additional, Trujillo, Adriana S, additional, Huang, Alice, additional, Melkani, Anju, additional, Cammarato, Anthony, additional, Swank, Douglas M, additional, and Bernstein, Sanford I, additional

Published
2018
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50. Prolonged myosin binding increases muscle stiffness in Drosophilamodels of Freeman-Sheldon syndrome

Author

Bell, Kaylyn M., Huang, Alice, Kronert, William A., Bernstein, Sanford I., and Swank, Douglas M.

Abstract

Freeman-Sheldon syndrome (FSS) is characterized by congenital contractures resulting from dominant point mutations in the embryonic isoform of muscle myosin. To investigate its disease mechanism, we used Drosophilamodels expressing FSS myosin mutations Y583S or T178I in their flight and jump muscles. We isolated these muscles from heterozygous mutant Drosophilaand performed skinned fiber mechanics. The most striking mechanical alteration was an increase in active muscle stiffness. Y583S/+and T178I/+fibers’ elastic moduli increased 70 and 77%, respectively. Increased stiffness contributed to decreased power generation, 49 and 66%, as a result of increased work absorbed during the lengthening portion of the contractile cycle. Slower muscle kinetics also contributed to the mutant phenotype, as shown by 17 and 32% decreases in optimal frequency for power generation, and 27 and 41% slower muscle apparent rate constant 2πb. Combined with previous measurements of slower in vitro actin motility, our results suggest a rate reduction of at least one strongly bound cross-bridge cycle transition that increases the time myosin spends strongly bound to actin, ton. Increased tonwas further supported by decreased ATP affinity and a 16% slowing of jump muscle relaxation rate in T178I heterozygotes. Impaired muscle function caused diminished flight and jump ability of Y583S/+and T178I/+ Drosophila. Based on our results, assuming that our model system mimics human skeletal muscle, we propose that one mechanism driving FSS is elevated muscle stiffness arising from prolonged tonin developing muscle fibers.

Published
2021
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