A novel method to study the electrodynamic behavior of actin filaments. Evidence for cable-like properties of actin.

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A novel method to study the electrodynamic behavior of actin filaments. Evidence for cable-like properties of actin.

E C Lin and H F Cantiello

Renal Unit, Massachusetts General Hospital East, Charlestown 02129.

ABSTRACT

Actin, one of the most abundant intracellular proteins, formslong linear polyelectrolytic polymers in solution. A novel techniqueto handle single actin filaments in solution was developed thatallows the study of ionic currents elicited along the surfaceof electrically stimulated actin filaments. Electrical currentswere observed about the polymer's surface under both high (100mM KCl) and low (1 mM KCl) ionic strength conditions. The dataare consistent with a dynamic behavior of the counterionic cloudsurrounding the actin filaments that support ionic movementsalong their longitudinal axis upon electrical stimulation. Counterionicwaves were highly nonlinear in nature and remained long afterthe electrical stimulation of the actin filaments ceased. Inthis report therefore, we demonstrate that actin filaments canfunction as biological "electrical wires" and can thus be conceptualizedas nonlinear inhomogeneous transmission lines. This abilityof actin filaments to conduct electrical signals may have importantimplications in the coupling of intracellular signals.

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