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A Confirmation for the Positive Electric Charge of Bio-Molecular Motors through Utilizing a Novel Nano-Technology Approach In Vitro

Molecular motors are microtubule-based proteins which contribute to many cell functions, such as intracellular transportation and cell division. The details of the nature of the mutual interactions between motors and microtubules still needs to be extensively explored. However, electrostatic interac...

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Autores principales: Feizabadi, Mitra Shojania, Alejilat, Ramiz S., Duffy, Alexis B., Breslin, Jane C., Akintola, Ibukunoluwa I.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2020
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7404192/
https://www.ncbi.nlm.nih.gov/pubmed/32668620
http://dx.doi.org/10.3390/ijms21144935
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author Feizabadi, Mitra Shojania
Alejilat, Ramiz S.
Duffy, Alexis B.
Breslin, Jane C.
Akintola, Ibukunoluwa I.
author_facet Feizabadi, Mitra Shojania
Alejilat, Ramiz S.
Duffy, Alexis B.
Breslin, Jane C.
Akintola, Ibukunoluwa I.
author_sort Feizabadi, Mitra Shojania
collection PubMed
description Molecular motors are microtubule-based proteins which contribute to many cell functions, such as intracellular transportation and cell division. The details of the nature of the mutual interactions between motors and microtubules still needs to be extensively explored. However, electrostatic interaction is known as one of the key factors making motor-microtubule association possible. The association rate of molecular motors to microtubules is a way to observe and evaluate the charge of the bio-motors in vivo. Growing evidence indicates that microtubules with distinct structural compositions in terms of beta tubulin isotypes carry different charges. Therefore, the electrostatic-driven association rate of motors–microtubules, which is a base for identifying the charge of motors, can be more likely influenced. Here, we present a novel method to experimentally confirm the charge of molecular motors in vitro. The offered nanotechnology-based approach can validate the charge of motors in the absence of any cellular components through the observation and analysis of the changes that biomolecular motors can cause on the dynamic of charged microspheres inside a uniform electric field produced by a microscope slide-based nanocapacitor. This new in vitro experimental method is significant as it minimizes the intracellular factors that may interfere the electric charge that molecular motors carry.
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spelling pubmed-74041922020-08-11 A Confirmation for the Positive Electric Charge of Bio-Molecular Motors through Utilizing a Novel Nano-Technology Approach In Vitro Feizabadi, Mitra Shojania Alejilat, Ramiz S. Duffy, Alexis B. Breslin, Jane C. Akintola, Ibukunoluwa I. Int J Mol Sci Article Molecular motors are microtubule-based proteins which contribute to many cell functions, such as intracellular transportation and cell division. The details of the nature of the mutual interactions between motors and microtubules still needs to be extensively explored. However, electrostatic interaction is known as one of the key factors making motor-microtubule association possible. The association rate of molecular motors to microtubules is a way to observe and evaluate the charge of the bio-motors in vivo. Growing evidence indicates that microtubules with distinct structural compositions in terms of beta tubulin isotypes carry different charges. Therefore, the electrostatic-driven association rate of motors–microtubules, which is a base for identifying the charge of motors, can be more likely influenced. Here, we present a novel method to experimentally confirm the charge of molecular motors in vitro. The offered nanotechnology-based approach can validate the charge of motors in the absence of any cellular components through the observation and analysis of the changes that biomolecular motors can cause on the dynamic of charged microspheres inside a uniform electric field produced by a microscope slide-based nanocapacitor. This new in vitro experimental method is significant as it minimizes the intracellular factors that may interfere the electric charge that molecular motors carry. MDPI 2020-07-13 /pmc/articles/PMC7404192/ /pubmed/32668620 http://dx.doi.org/10.3390/ijms21144935 Text en © 2020 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Feizabadi, Mitra Shojania
Alejilat, Ramiz S.
Duffy, Alexis B.
Breslin, Jane C.
Akintola, Ibukunoluwa I.
A Confirmation for the Positive Electric Charge of Bio-Molecular Motors through Utilizing a Novel Nano-Technology Approach In Vitro
title A Confirmation for the Positive Electric Charge of Bio-Molecular Motors through Utilizing a Novel Nano-Technology Approach In Vitro
title_full A Confirmation for the Positive Electric Charge of Bio-Molecular Motors through Utilizing a Novel Nano-Technology Approach In Vitro
title_fullStr A Confirmation for the Positive Electric Charge of Bio-Molecular Motors through Utilizing a Novel Nano-Technology Approach In Vitro
title_full_unstemmed A Confirmation for the Positive Electric Charge of Bio-Molecular Motors through Utilizing a Novel Nano-Technology Approach In Vitro
title_short A Confirmation for the Positive Electric Charge of Bio-Molecular Motors through Utilizing a Novel Nano-Technology Approach In Vitro
title_sort confirmation for the positive electric charge of bio-molecular motors through utilizing a novel nano-technology approach in vitro
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7404192/
https://www.ncbi.nlm.nih.gov/pubmed/32668620
http://dx.doi.org/10.3390/ijms21144935
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