AI Article Synopsis
- - Myosin family proteins are motor proteins that use ATP to generate force along actin filaments, and this study focuses on how temperature affects their corkscrewing motion.
- - The research involved in vitro assays with a specific myosin (Drosophila myosin IC) and found that increasing temperature (from 25°C to 35°C) leads to higher gliding and rotational velocities of actin filaments.
- - Results show that at warmer temperatures, the gliding velocity increases more than the rotational velocity, suggesting temperature influences how myosin IC generates torque on actin filaments, which could be important for understanding muscle function at physiological temperatures.
Article Abstract
Myosin family proteins are ATP-driven, actin filament-based motor proteins that generate force along actin filaments. In in vitro actin filament gliding assays, certain myosins generate rotation of gliding actin filaments around their long axes. In this study, we assessed the effects of temperature on the corkscrewing motion of actin filaments, including factors like gliding and rotational velocities and corkscrewing pitch. The corkscrewing motion was driven by a nonprocessive, full-length single-headed Drosophila myosin IC attached to an antibody adsorbed onto a cover glass. We performed an in vitro actin filament corkscrewing assay at temperatures ranging from 25 °C to 35 °C. We found that the gliding and rotational velocities and the pitch of corkscrewing actin filaments generated by myosin IC molecules increased with increasing temperature. Since the pitch is determined by dividing the gliding velocity by the rotational velocity, an increase in the pitch indicates that the gliding velocity increased faster than the rotational velocity with increasing temperature. These results suggest that temperature has distinct effects on the gliding and rotational forces produced by myosin IC, with implications for interpreting the temperature effect on torque-generation mechanisms driven by myosins on actin filaments at physiological temperatures.
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| http://dx.doi.org/10.1016/j.bbrc.2024.149597 | DOI Listing |
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