Mechanical Effects of Dynamic Binding between Tau Proteins on Microtubules during Axonal Injury

The viscoelastic nature of axons plays a key role in their selective vulnerability to damage in traumatic brain injury (TBI). Experimental studies have shown that although axons can tolerate 100% strain under slow loading rates, even strain as small as 5% can rupture microtubules (MTs) during the fa...

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Veröffentlicht in:	Biophysical journal 2015-12, Vol.109 (11), p.2328-2337
Hauptverfasser:	Ahmadzadeh, Hossein, Smith, Douglas H., Shenoy, Vivek B.
Format:	Artikel
Sprache:	eng
Schlagworte:	Axons - pathology Binding sites Biomechanical Phenomena Brain Injuries - pathology Effects Elasticity Experiments Humans Kinetics Mechanical Phenomena Mechanical properties Microtubules - metabolism Molecular Machines, Motors and Nanoscale Biophysics Protein Binding Proteins Stress, Mechanical tau Proteins - metabolism Traumatic brain injury Viscosity
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creator	Ahmadzadeh, Hossein Smith, Douglas H. Shenoy, Vivek B.
description	The viscoelastic nature of axons plays a key role in their selective vulnerability to damage in traumatic brain injury (TBI). Experimental studies have shown that although axons can tolerate 100% strain under slow loading rates, even strain as small as 5% can rupture microtubules (MTs) during the fast loading velocities relevant to TBI. Here, we developed a computational model to examine rate-dependent behavior related to dynamic interactions between MTs and the MT-associated protein tau under varying strains and strain rates. In the model, inverted pairs of tau proteins can dynamically cross-link parallel MTs via the respective MT-binding domain of each tau. The model also incorporates realistic thermodynamic breaking and reformation of the bonds between the connected tau proteins as they respond to mechanical stretch. With simulated stretch of the axon, the model shows that despite the highly dynamic nature of binding and unbinding events, under fast loading rates relevant to TBI, large tensile forces can be transmitted to the MTs that can lead to mechanical rupture of the MT cylinder, in agreement with experimental observations and as inferred in human TBI. In contrast, at slow loading rates, the progressive breaking and reformation of the bonds between the tau proteins facilitate the extension of axons up to ∼100% strain without any microstructural damage. The model also predicts that under fast loading rates, individual MTs detach from MT bundles via sequential breaking of the tau-tau bonds. Finally, the model demonstrates that longer MTs are more susceptible to mechanical rupture, whereas short MTs are more prone to detachment from the MT bundle, leading to disintegration of the axonal MT ultrastructure. Notably, the predictions from the model are in excellent agreement with the findings of the recent in vitro mechanical testing of micropatterned neuronal cultures.
doi_str_mv	10.1016/j.bpj.2015.09.010
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With simulated stretch of the axon, the model shows that despite the highly dynamic nature of binding and unbinding events, under fast loading rates relevant to TBI, large tensile forces can be transmitted to the MTs that can lead to mechanical rupture of the MT cylinder, in agreement with experimental observations and as inferred in human TBI. In contrast, at slow loading rates, the progressive breaking and reformation of the bonds between the tau proteins facilitate the extension of axons up to ∼100% strain without any microstructural damage. The model also predicts that under fast loading rates, individual MTs detach from MT bundles via sequential breaking of the tau-tau bonds. Finally, the model demonstrates that longer MTs are more susceptible to mechanical rupture, whereas short MTs are more prone to detachment from the MT bundle, leading to disintegration of the axonal MT ultrastructure. 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Experimental studies have shown that although axons can tolerate 100% strain under slow loading rates, even strain as small as 5% can rupture microtubules (MTs) during the fast loading velocities relevant to TBI. Here, we developed a computational model to examine rate-dependent behavior related to dynamic interactions between MTs and the MT-associated protein tau under varying strains and strain rates. In the model, inverted pairs of tau proteins can dynamically cross-link parallel MTs via the respective MT-binding domain of each tau. The model also incorporates realistic thermodynamic breaking and reformation of the bonds between the connected tau proteins as they respond to mechanical stretch. 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Notably, the predictions from the model are in excellent agreement with the findings of the recent in vitro mechanical testing of micropatterned neuronal cultures.</description><subject>Axons - pathology</subject><subject>Binding sites</subject><subject>Biomechanical Phenomena</subject><subject>Brain Injuries - pathology</subject><subject>Effects</subject><subject>Elasticity</subject><subject>Experiments</subject><subject>Humans</subject><subject>Kinetics</subject><subject>Mechanical Phenomena</subject><subject>Mechanical properties</subject><subject>Microtubules - metabolism</subject><subject>Molecular Machines, Motors and Nanoscale Biophysics</subject><subject>Protein Binding</subject><subject>Proteins</subject><subject>Stress, Mechanical</subject><subject>tau Proteins - metabolism</subject><subject>Traumatic brain injury</subject><subject>Viscosity</subject><issn>0006-3495</issn><issn>1542-0086</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2015</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNp9kU1v1DAQhi1ERZfCD-CCInHhknQcf8QRElIpBSq1gkM5W44zbh1lncVOCvvv8bKloj1wskZ-5tXMPIS8olBRoPJ4qLrNUNVARQVtBRSekBUVvC4BlHxKVgAgS8ZbcUiepzQA0FoAfUYOaymZbDlfEX2J9sYEb81YnDmHdk7F5IqP22DW3hYffOh9uC46nH8ihuLKLMW3OM3oQ-ZCceltrpZuGTEV_RJ37MmvKeS08zAscfuCHDgzJnx59x6R75_Ork6_lBdfP5-fnlyUljftXOZZVNPbhjFme9XWrXS14h0oYzqJSgpmWxAKKWuZc51xSoEBJqSlVhrj2BF5v8_dLN0ae4thjmbUm-jXJm71ZLx--BP8jb6ebjWXjVA1ywFv7wLi9GPBNOu1TxbH0QSclqRpw7kUSgBk9M0jdJiWmHf-Q-UdOFUiU3RP5QulFNHdD0NB7_TpQWd9eqdPQ6uzvtzz-t8t7jv--srAuz2A-Za3HqNO1mOw2PuY3el-8v-J_w2EpquE</recordid><startdate>20151201</startdate><enddate>20151201</enddate><creator>Ahmadzadeh, Hossein</creator><creator>Smith, Douglas H.</creator><creator>Shenoy, Vivek B.</creator><general>Elsevier Inc</general><general>Biophysical Society</general><general>The Biophysical Society</general><scope>6I.</scope><scope>AAFTH</scope><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7QO</scope><scope>7QP</scope><scope>7TK</scope><scope>7TM</scope><scope>7U9</scope><scope>8FD</scope><scope>FR3</scope><scope>H94</scope><scope>K9.</scope><scope>P64</scope><scope>7X8</scope><scope>5PM</scope></search><sort><creationdate>20151201</creationdate><title>Mechanical Effects of Dynamic Binding between Tau Proteins on Microtubules during Axonal Injury</title><author>Ahmadzadeh, Hossein ; 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Experimental studies have shown that although axons can tolerate 100% strain under slow loading rates, even strain as small as 5% can rupture microtubules (MTs) during the fast loading velocities relevant to TBI. Here, we developed a computational model to examine rate-dependent behavior related to dynamic interactions between MTs and the MT-associated protein tau under varying strains and strain rates. In the model, inverted pairs of tau proteins can dynamically cross-link parallel MTs via the respective MT-binding domain of each tau. The model also incorporates realistic thermodynamic breaking and reformation of the bonds between the connected tau proteins as they respond to mechanical stretch. With simulated stretch of the axon, the model shows that despite the highly dynamic nature of binding and unbinding events, under fast loading rates relevant to TBI, large tensile forces can be transmitted to the MTs that can lead to mechanical rupture of the MT cylinder, in agreement with experimental observations and as inferred in human TBI. In contrast, at slow loading rates, the progressive breaking and reformation of the bonds between the tau proteins facilitate the extension of axons up to ∼100% strain without any microstructural damage. The model also predicts that under fast loading rates, individual MTs detach from MT bundles via sequential breaking of the tau-tau bonds. Finally, the model demonstrates that longer MTs are more susceptible to mechanical rupture, whereas short MTs are more prone to detachment from the MT bundle, leading to disintegration of the axonal MT ultrastructure. 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subjects	Axons - pathology Binding sites Biomechanical Phenomena Brain Injuries - pathology Effects Elasticity Experiments Humans Kinetics Mechanical Phenomena Mechanical properties Microtubules - metabolism Molecular Machines, Motors and Nanoscale Biophysics Protein Binding Proteins Stress, Mechanical tau Proteins - metabolism Traumatic brain injury Viscosity
title	Mechanical Effects of Dynamic Binding between Tau Proteins on Microtubules during Axonal Injury
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