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Investigation of the electrical properties of microtubule ensembles under cell-like conditions

dc.contributor.authorAarat, Kalra P.
dc.contributor.authorPatel, Sahil D.
dc.contributor.authorBhuiyan, Asadullah
dc.contributor.authorPreto, Jordane
dc.contributor.authorScheuer, Kyle G.
dc.contributor.authorMohammed, Usman
dc.contributor.authorLewis, John D.
dc.contributor.authorRezania, Vahid
dc.contributor.authorShankar, Karthik
dc.contributor.authorTuszynski, Jack A.
dc.date.accessioned2021-06-18
dc.date.accessioned2022-05-31T01:44:00Z
dc.date.available2022-05-31T01:44:00Z
dc.date.issued2020
dc.description.abstractMicrotubules (MTs) are cylindrical polymers composed of the heterodimers of protein α, β- tubulin that play a variety of well-recognised intracellular roles, such as maintaining the shape and rigidity of the cell, aiding in positioning and stabilisation of the mitotic spindle for allowing chromosomal segregation, acting as ‘rails’ for macromolecular transport and forming cilia and flagella for cell movement. Since the tubulin dimer possesses a high negative electric charge of ~23e and a large intrinsic high dipole moment of approximately 1750 D [1,2], MTs have been implicated in electrically-mediated biological roles [3,4,5,6]. They have been modelled as nanowires capable of enhancing ionic transport [7,8], and simulated to receive and attenuate electrical oscillations [4,9,10,11]. In solution, MTs have been shown to align with applied electric fields [2,12,13,14,15,16]. Recently, MTs have also been modelled as the primary cellular targets for low-intensity (1–2 V), intermediate-frequency (100–300 kHz) electric fields termed TTFields (tumour-treating electric fields) that inhibit cancer cell proliferation, in particular glioma [17,18,19]. Indeed, MTs have been reported to decrease buffer solution resistance [12,13], leading to a conductance peak at frequencies close to the TTField regime [20]. While these studies show that MTs are highly sensitive to external electric fields, answers to the questions ‘How do MTs effect a solution’s capacitance?’ and ‘What is the capacitance of a single MT?’ are still elusive and crucial to the determination of the dielectric properties of living cells. The tubulin concentration in mammalian cells varies in the micromolar range (~10–25 μM) [21,22]. In vitro, polymerizing tubulin at such high concentrations can lead to the formation of entangled networks, confounding quantification of the individual MT response to electric fields. Electro-rotation, di-electrophoresis and impedance spectroscopy are thus performed using low concentrations of tubulin, in the nanomolar regime, to enable robust observation of individual MTs.
dc.format.extent4.92MB
dc.format.mimetypePDF
dc.identifier.citationKalra, A. P., Patel, S. D., Bhuiyan, A. F., Preto, J., Scheuer, K. G., Rezania, V., . . . Tuszynski, J. A. (2020). Investigation of the electrical properties of microtubule ensembles under cell-like conditions, Nanomaterials, 10(2), 265. https://doi.org/10.3390/nano10020265
dc.identifier.doihttps://doi.org/10.3390/nano10020265
dc.identifier.urihttps://hdl.handle.net/20.500.14078/2353
dc.languageEnglish
dc.language.isoen
dc.rightsAttribution (CC BY)
dc.rights.urihttps://creativecommons.org/licenses/by/4.0/
dc.subjectmicrotubules
dc.subjectbioelectricity
dc.subjectbionanowires
dc.subjectneuronal charge storage
dc.subjectimpedance spectroscopy
dc.subjectcytoskeleton
dc.titleInvestigation of the electrical properties of microtubule ensembles under cell-like conditionsen
dc.typeArticle
dspace.entity.type

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