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Georgia Tech Applied Physiology
==Georgia Tech Public Lecture Series==
'''College of Computing Nobel Laureate Talk'''
 
Michael Leavitt --- Stanford University
 
'''Birth & Future of Multi-scale Modeling of Macromolecules'''
 
*Mon, Nov 24, 2014
*Reception 4:30 pm
*Lecture 5:00 pm in Student Center Ballroom
 
 
 
 
 
'''Soft and Condensed Matter Biophysics'''
 
Joshua Weitz --- Georgia Inst. of Technology
 
[http://www.physics.gatech.edu/seminars-colloquia/series/soft-condensed-matter-and-biophysics/joshua-weitz-20141125 '''Mathematical Models of the Ebola Virus Disease Outbreak in West Africa: Principles, Predictions, and Control''']
 
*Tue, Nov 25, 2014
*3:00 pm in Klaus 1116
 
 
 
 
 
'''The Physics of Frankenstein'''
 
October 28, 2014 6:00 pm CULC 144
 
Prof. Flavio Fenton
 
School of Physics
Georgia Inst. of Technology
 
==Georgia Tech Applied Physiology==


Brown-bag seminar series
Brown-bag seminar series
February 22, 2013 12:00 pm  Room 1253, 555 14th St NW


Age-related changes in human skeletal muscle from the myosin molecule to the whole muscle
Age-related changes in human skeletal muscle from the myosin molecule to the whole muscle
Line 13: Line 52:


This seminar will focus on the effects of aging on human skeletal muscle and the use of a model system, Drosophila melanogaster (fruit fly), to help interpret the findings. Age-related skeletal muscle dysfunction and physical disability may be partially explained by alterations in the function of the myosin molecule. To test this possibility, skeletal muscle structure and function at the whole muscle, single fiber and molecular levels was measured in the knee extensors of young (21-35 years) and older (65-75 years) male and female volunteers matched for physical activity level. After adjusting for muscle size, older adults had similar isometric torque values compared to young, but had lower isokinetic power, primarily in females. At the molecular level, older adults, especially females, had slower myosin-actin cross-bridge kinetics (longer myosin attachment times and reduced rates of myosin force production), which may be explained by their reduced phosphorylation of the myosin regulatory light chain (RLC). The RLC phosphorylation decrease likely reduces cross-bridge formation by altering myosin’s orientation to actin, as found in Drosophila, an ideal system for examining muscle structure as measurements can be performed in living flies. Notably, cross-bridge kinetics in myosin heavy chain (MHC) IIA fibers correlated with whole muscle power output, indicating age-related changes at the molecular level decrease whole muscle dynamic performance in humans. A link between contractile and metabolic function was found as mitochondrial size was decreased in older adults, especially females, and was correlated to cross-bridge kinetics and whole muscle power output. These results are supported by Drosophila experiments that indicate mitochondria play a role in loss of flight ability with age. Collectively, our results show that age-related reductions in cross-bridge kinetics, most notable in females, represent a potential molecular mechanism underlying the development of physical disability with age. A possible future direction for this work is to evaluate rehabilitative interventions designed to increase cross-bridge kinetics, which may need to be sex-specific to address the unique cellular/molecular adaptations with age of males and females.
This seminar will focus on the effects of aging on human skeletal muscle and the use of a model system, Drosophila melanogaster (fruit fly), to help interpret the findings. Age-related skeletal muscle dysfunction and physical disability may be partially explained by alterations in the function of the myosin molecule. To test this possibility, skeletal muscle structure and function at the whole muscle, single fiber and molecular levels was measured in the knee extensors of young (21-35 years) and older (65-75 years) male and female volunteers matched for physical activity level. After adjusting for muscle size, older adults had similar isometric torque values compared to young, but had lower isokinetic power, primarily in females. At the molecular level, older adults, especially females, had slower myosin-actin cross-bridge kinetics (longer myosin attachment times and reduced rates of myosin force production), which may be explained by their reduced phosphorylation of the myosin regulatory light chain (RLC). The RLC phosphorylation decrease likely reduces cross-bridge formation by altering myosin’s orientation to actin, as found in Drosophila, an ideal system for examining muscle structure as measurements can be performed in living flies. Notably, cross-bridge kinetics in myosin heavy chain (MHC) IIA fibers correlated with whole muscle power output, indicating age-related changes at the molecular level decrease whole muscle dynamic performance in humans. A link between contractile and metabolic function was found as mitochondrial size was decreased in older adults, especially females, and was correlated to cross-bridge kinetics and whole muscle power output. These results are supported by Drosophila experiments that indicate mitochondria play a role in loss of flight ability with age. Collectively, our results show that age-related reductions in cross-bridge kinetics, most notable in females, represent a potential molecular mechanism underlying the development of physical disability with age. A possible future direction for this work is to evaluate rehabilitative interventions designed to increase cross-bridge kinetics, which may need to be sex-specific to address the unique cellular/molecular adaptations with age of males and females.
February 22, 2013 12:00 pm  Room 1253, 555 14th St NW

Latest revision as of 11:53, 21 November 2014

Georgia Tech Public Lecture Series

College of Computing Nobel Laureate Talk

Michael Leavitt --- Stanford University

Birth & Future of Multi-scale Modeling of Macromolecules

  • Mon, Nov 24, 2014
  • Reception 4:30 pm
  • Lecture 5:00 pm in Student Center Ballroom



Soft and Condensed Matter Biophysics

Joshua Weitz --- Georgia Inst. of Technology

Mathematical Models of the Ebola Virus Disease Outbreak in West Africa: Principles, Predictions, and Control

  • Tue, Nov 25, 2014
  • 3:00 pm in Klaus 1116



The Physics of Frankenstein

October 28, 2014 6:00 pm CULC 144

Prof. Flavio Fenton

School of Physics Georgia Inst. of Technology

Georgia Tech Applied Physiology

Brown-bag seminar series

February 22, 2013 12:00 pm Room 1253, 555 14th St NW

Age-related changes in human skeletal muscle from the myosin molecule to the whole muscle

Mark S. Miller, Ph.D.

Department of Molecular Physiology and Biophysics University of Vermont


This seminar will focus on the effects of aging on human skeletal muscle and the use of a model system, Drosophila melanogaster (fruit fly), to help interpret the findings. Age-related skeletal muscle dysfunction and physical disability may be partially explained by alterations in the function of the myosin molecule. To test this possibility, skeletal muscle structure and function at the whole muscle, single fiber and molecular levels was measured in the knee extensors of young (21-35 years) and older (65-75 years) male and female volunteers matched for physical activity level. After adjusting for muscle size, older adults had similar isometric torque values compared to young, but had lower isokinetic power, primarily in females. At the molecular level, older adults, especially females, had slower myosin-actin cross-bridge kinetics (longer myosin attachment times and reduced rates of myosin force production), which may be explained by their reduced phosphorylation of the myosin regulatory light chain (RLC). The RLC phosphorylation decrease likely reduces cross-bridge formation by altering myosin’s orientation to actin, as found in Drosophila, an ideal system for examining muscle structure as measurements can be performed in living flies. Notably, cross-bridge kinetics in myosin heavy chain (MHC) IIA fibers correlated with whole muscle power output, indicating age-related changes at the molecular level decrease whole muscle dynamic performance in humans. A link between contractile and metabolic function was found as mitochondrial size was decreased in older adults, especially females, and was correlated to cross-bridge kinetics and whole muscle power output. These results are supported by Drosophila experiments that indicate mitochondria play a role in loss of flight ability with age. Collectively, our results show that age-related reductions in cross-bridge kinetics, most notable in females, represent a potential molecular mechanism underlying the development of physical disability with age. A possible future direction for this work is to evaluate rehabilitative interventions designed to increase cross-bridge kinetics, which may need to be sex-specific to address the unique cellular/molecular adaptations with age of males and females.