Fluorescence labeling and computational analysis of the strut of myosin's 50 kDa cleft.

In order to understand the structural changes in myosin S1, fluorescence polarization and computational dynamics simulations were used. Dynamics simulations on the S1 motor domain indicated that significant flexibility was present throughout the molecular model. The constrained opening versus closin...

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Main Author: Gawalapu, Ravi Kumar
Other Authors: Root, Douglas D.
Format: Others
Language:English
Published: University of North Texas 2007
Subjects:
Online Access:https://digital.library.unt.edu/ark:/67531/metadc3974/
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spelling ndltd-unt.edu-info-ark-67531-metadc39742017-03-17T08:35:58Z Fluorescence labeling and computational analysis of the strut of myosin's 50 kDa cleft. Gawalapu, Ravi Kumar Strut fluorescence label Myosin. Muscle proteins. In order to understand the structural changes in myosin S1, fluorescence polarization and computational dynamics simulations were used. Dynamics simulations on the S1 motor domain indicated that significant flexibility was present throughout the molecular model. The constrained opening versus closing of the 50 kDa cleft appeared to induce opposite directions of movement in the lever arm. A sequence called the "strut" which traverses the 50 kDa cleft and may play an important role in positioning the actomyosin binding interface during actin binding is thought to be intimately linked to distant structural changes in the myosin's nucleotide cleft and neck regions. To study the dynamics of the strut region, a method of fluorescent labeling of the strut was discovered using the dye CY3. CY3 served as a hydrophobic tag for purification by hydrophobic interaction chromatography which enabled the separation of labeled and unlabeled species of S1 including a fraction labeled specifically at the strut sequence. The high specificity of labeling was verified by proteolytic digestions, gel electrophoresis, and mass spectroscopy. Analysis of the labeled S1 by collisional quenching, fluorescence polarization, and actin-activated ATPase activity were consistent with predictions from structural models of the probe's location. Although the fluorescent intensity of the CY3 was insensitive to actin binding, its fluorescence polarization was notably affected. Intriguingly, the mobility of the probe increases upon S1 binding to actin suggesting that the CY3 becomes displaced from interactions with the surface of S1 and is consistent with a structural change in the strut due to cleft motions. Labeling the strut reduced the affinity of S1 for actin but did not prevent actin-activated ATPase activity which makes it a potentially useful probe of the actomyosin interface. The different conformations of myosin S1 indicated that the strut is not as flexible as several other key regions of myosin as determined by the application of force constraints to elastic portions of the myosin structure. University of North Texas Root, Douglas D. Pirtle, Robert M. Chapman, Kent D. Padilla, Pamela Cundari, Thomas R. 2007-08 Thesis or Dissertation Text oclc: 191868802 https://digital.library.unt.edu/ark:/67531/metadc3974/ ark: ark:/67531/metadc3974 English Public Copyright Gawalapu, Ravi Kumar Copyright is held by the author, unless otherwise noted. All rights reserved.
collection NDLTD
language English
format Others
sources NDLTD
topic Strut
fluorescence
label
Myosin.
Muscle proteins.
spellingShingle Strut
fluorescence
label
Myosin.
Muscle proteins.
Gawalapu, Ravi Kumar
Fluorescence labeling and computational analysis of the strut of myosin's 50 kDa cleft.
description In order to understand the structural changes in myosin S1, fluorescence polarization and computational dynamics simulations were used. Dynamics simulations on the S1 motor domain indicated that significant flexibility was present throughout the molecular model. The constrained opening versus closing of the 50 kDa cleft appeared to induce opposite directions of movement in the lever arm. A sequence called the "strut" which traverses the 50 kDa cleft and may play an important role in positioning the actomyosin binding interface during actin binding is thought to be intimately linked to distant structural changes in the myosin's nucleotide cleft and neck regions. To study the dynamics of the strut region, a method of fluorescent labeling of the strut was discovered using the dye CY3. CY3 served as a hydrophobic tag for purification by hydrophobic interaction chromatography which enabled the separation of labeled and unlabeled species of S1 including a fraction labeled specifically at the strut sequence. The high specificity of labeling was verified by proteolytic digestions, gel electrophoresis, and mass spectroscopy. Analysis of the labeled S1 by collisional quenching, fluorescence polarization, and actin-activated ATPase activity were consistent with predictions from structural models of the probe's location. Although the fluorescent intensity of the CY3 was insensitive to actin binding, its fluorescence polarization was notably affected. Intriguingly, the mobility of the probe increases upon S1 binding to actin suggesting that the CY3 becomes displaced from interactions with the surface of S1 and is consistent with a structural change in the strut due to cleft motions. Labeling the strut reduced the affinity of S1 for actin but did not prevent actin-activated ATPase activity which makes it a potentially useful probe of the actomyosin interface. The different conformations of myosin S1 indicated that the strut is not as flexible as several other key regions of myosin as determined by the application of force constraints to elastic portions of the myosin structure.
author2 Root, Douglas D.
author_facet Root, Douglas D.
Gawalapu, Ravi Kumar
author Gawalapu, Ravi Kumar
author_sort Gawalapu, Ravi Kumar
title Fluorescence labeling and computational analysis of the strut of myosin's 50 kDa cleft.
title_short Fluorescence labeling and computational analysis of the strut of myosin's 50 kDa cleft.
title_full Fluorescence labeling and computational analysis of the strut of myosin's 50 kDa cleft.
title_fullStr Fluorescence labeling and computational analysis of the strut of myosin's 50 kDa cleft.
title_full_unstemmed Fluorescence labeling and computational analysis of the strut of myosin's 50 kDa cleft.
title_sort fluorescence labeling and computational analysis of the strut of myosin's 50 kda cleft.
publisher University of North Texas
publishDate 2007
url https://digital.library.unt.edu/ark:/67531/metadc3974/
work_keys_str_mv AT gawalapuravikumar fluorescencelabelingandcomputationalanalysisofthestrutofmyosins50kdacleft
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