Browsing by Subject "skeletal muscle"
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Item Anisotropy of Myosin and Actin in Contraction of Skeletal Muscle(2004-12-01) Shepard, Athena A.; Julian Borejdo; Thomas Burghardt; Ben HarrisShepard, Athena A., Anisotropy of Myosin and Actin in Contraction of Skeletal Muscle. Doctor of Philosophy (Molecular Biology and Immunology), December, 2004, 161 pp., 1 table, 42 illustrations, bibliography, 253 titles. Muscle contraction results from the interaction of myosin and actin proteins contained in the muscle sarcomere. During actomyosin interactions, myosin consumes ATP and imparts an impulsive force to actin resulting in sliding of myosin and actin filaments to produce work. These proteins constitute the elementary motor responsible for cellular motility. The overall goal of this research project was to elucidate the mechanism of the actomyosin interaction on a molecular level. Novel time-resolved optical microscopic techniques followed myosin and actin orientation changes during skeletal muscle contraction. Fluorescence anisotropy was used to study the real time orientation changes of myosin, actin, and nucleotide during a single cross bridge cycle beginning in a state of rigor. Rabbit psoas fibers were isolated on a microscopic slide and labeled with fluorescently labeled regulatory light chain to monitor orientation changes of the lever arm of myosin, with fluorescent phalloidin to monitor orientation changes of actin and/or with Alexa ADP to monitor ATP hydrolysis. Caged ATP was perfused into the fiber prior to analysis to allow a small population of cross-bridges to execute a single cross-bridge cycle. Flash photolysis with UV light during analysis converted caged ATP from an inactive from to an active from. Confocal and multi-photon imaging allowed illumination of a small population of fluorescently labeled cross-bridges to measure orientation changes over time. The conclusions of this dissertation are: 1) The regulatory light chain rotates during skeletal muscle contraction and the lever arm model is supported, 2) Release of ADP from S1 corresponds to a single rotation of the lever arm, 3) Actin rotates during skeletal muscle contraction, 4) The rotation of actin is passive, i.e. it rotates as a consequence of dissociation of S1 from actin. The results revealed orientation changes in key contractile proteins during muscle contraction in the non-disease state organism. By understanding the mechanism of muscle contraction in the healthy scenario, hopefully a better understanding of diseased states stemming from mutations in contractile proteins (Usher’s Syndrome, Snell’s Waltzer Disease, and certain familial hypertrophic cardiomyopathies) will be made available, leading to a better preventative measures or treatments to treat such diseases in the future.Item Effects of Exercise Training on the Autophagy-Related Muscular Proteins Expression in Ovariectomized Rats(Frontiers Media S.A., 2019-06-13) Zhong, Weiquan; Shi, Xiangrong; Yuan, Honghua; Bu, Huimin; Wu, Lianlian; Wang, RenweiOvariectomy disrupts estrogen production and homeostasis. However, whether exercise training (ET) could counteract the ovariectomy-induced effect on muscular autophagy has remained elusive. This study examined muscular autophagy in ovariectomized (OVX) rats following 8 weeks of swimming ET. Here, 40 6-month-old female Sprague-Dawley rats were randomly divided into five groups: sham-operated control (Sham), OVX control (OVX), OVX with 60-min ET (OVX-60ET), 90-min ET (OVX-90ET), and 120-min ET (OVX-120ET) for 6 days/week. According to the results of Western blotting, the expression levels of autophagy-related proteins in the OVX gastrocnemius muscle, including mammalian target of rapamycin, uncoordinated 51-like kinase 1, Beclin-1, autophagy-related gene (Atg-7), and microtubule-associated protein light chains 3 were significantly decreased (all P < 0.05), while there was an elevation on the p62 level. ET appreciably mitigated the OVX-induced negative effects on muscle quality and the autophagy pathway, which seemed to be dependent on ET volume. The most optimal outcomes were observed in the OVX-90ET group. The OVX-120 group had an adversely augmented catabolic process associated with gastrocnemius muscle atrophy. In conclusion, the expression levels of autophagy proteins are decreased in OVX rats, which can be appreciably mitigated following 8 weeks of swimming ET.Item Regulation of Carotid Baroreflex Resetting During Arm Exercise(1999-06-01) Querry, Ross G.; Peter B. Raven; Patricia Gwirtz; Michael SmithQuerry, Ross G., Regulation of Carotid Baroreflex Resetting during Arm Exercise. Doctor of Philosophy (Biomedical Sciences), June 1999, 100 pp., 4 tables, 12 figures, bibliography, 56 titles. Cardiovascular responses to exercise are modulated by the integration of the central nervous system and afferent information from arterial baroreflexes and working skeletal muscle. Investigations have shown that during exercise, the carotid baroreflex (CBR) is reset in proportion to the exercise intensity. The role of the central nervous system contribution to the CBR resetting has not been elucidated. Investigations of CBR function in the animal model consistently report CBR variables such as maximal gain that are different than those reported in humans. These discrepancies may be due in part to methodological limitations in the neck pressure/neck suction (NP-NS) technique used to investigate the isolated CBR function in humans. To accurately examine the internal stimulus from the NP-NS maneuver, subjects were instrumented with a percutaneous catheter to record tissue pressure at the carotid sinus during five-second and rapid pulse NP-NS protocols. Carotid baroreflex function curves were analyzed with and without transmission correction of the carotid sinus pressure (CSP). Results indicated that positive pressure was more fully transmitted (~83%) than negative pressure (~65%) during the five-second-pulse, but not the rapid pulse protocol. Correction of the CSP in either protocol resulted in significant increases in CBR maximal gain and threshold and a reduced saturation pressure. These methodological refinements were then utilized to investigate the role of central command on CBR function during exercise. Subjects performed static and rhythmic handgrip exercise before and after regional anesthesia. Carotid baroreflex curves were analyzed at rest and during exercise before and after blockade at the same absolute workload. Muscle weakness from the blockade required an increased effort to maintain control tension. Heart rate, arterial pressure and perceived exertion during exercise were increased following blockade. During control exercise the CBR function curves were reset upward and rightward compared to rest with a further parallel shift during exercise with blockade. The operating point of the CBR was reset along with the centering point, but did not show the divergence toward the threshold pressure that had been previously described during dynamic exercise. The results support the proposal that central command was a primary mechanism for the resetting of the carotid baroreflex during exercise, but may not be the primary mechanism in the resetting of the operating point of the reflex.