Noelia Scarinci scite author profile

Microtubules (MTs) are long cylindrical structures of the cytoskeleton that control cell division, intracellular transport, and the shape of cells. MTs also form bundles, which are particularly prominent in neurons, where they help define axons and dendrites. MTs are bio-electrochemical transistors that form nonlinear electrical transmission lines. However, the electrical properties of most MT structures remain largely unknown. Here we show that bundles of brain MTs spontaneously generate electrical oscillations and bursts of electrical activity similar to action potentials. Under intracellular-like conditions, voltage-clamped MT bundles displayed electrical oscillations with a prominent fundamental frequency at 39 Hz that progressed through various periodic regimes. The electrical oscillations represented, in average, a 258% change in the ionic conductance of the MT structures. Interestingly, voltage-clamped membrane-permeabilized neurites of cultured mouse hippocampal neurons were also capable of both, generating electrical oscillations, and conducting the electrical signals along the length of the structure. Our findings indicate that electrical oscillations are an intrinsic property of brain MT bundles, which may have important implications in the control of various neuronal functions, including the gating and regulation of cytoskeleton-regulated excitable ion channels and electrical activity that may aid and extend to higher brain functions such as memory and consciousness.

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External Ca 2+ regulates polycystin-2 (TRPP2) cation currents in LLC-PK1 renal epithelial cells

Dai

Perez

Soria

et al. 2017

Experimental Cell Research

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Two-Dimensional Brain Microtubule Structures Behave as Memristive Devices

Cantero

Perez

Scarinci

et al. 2019

Sci Rep

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Microtubules (MTs) are cytoskeletal structures that play a central role in a variety of cell functions including cell division and cargo transfer. MTs are also nonlinear electrical transmission lines that produce and conduct electrical oscillations elicited by changes in either electric field and/or ionic gradients. The oscillatory behavior of MTs requires a voltage-sensitive gating mechanism to enable the electrodiffusional ionic movement through the MT wall. Here we explored the electrical response of non-oscillating rat brain MT sheets to square voltage steps. To ascertain the nature of the possible gating mechanism, the electrical response of non-oscillating rat brain MT sheets (2D arrays of MTs) to square pulses was analyzed under voltage-clamping conditions. A complex voltage-dependent nonlinear charge movement was observed, which represented the summation of two events. The first contribution was a small, saturating, voltage-dependent capacitance with a maximum charge displacement in the range of 4 fC/μm 2 . A second, major contribution was a non-saturating voltage-dependent charge transfer, consistent with the properties of a multistep memristive device. The memristive capabilities of MTs could drive oscillatory behavior, and enable voltage-driven neuromorphic circuits and architectures within neurons.

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Polycystin-2 (TRPP2) Regulates Primary Cilium Length in LLC-PK1 Renal Epithelial Cells

Perez

Scarinci

Cantiello

et al. 2020

Preprint

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Polycystin-2-regulates primary cilium length 2 Significance StatementPolycystin-2 (PC2, TRPP2) is a Ca 2+ permeable non-selective cation channel causing the autosomal dominant polycystic kidney disease (ADPKD). The importance of intact cilia and of fully functional polycystins in the onset of ADPKD cyst formation, point to yet unknown signaling mechanisms occurring within this organelle. We determined that the extracellular Ca 2+ concentration, PC2 channel blockers, and PKD2 gene silencing, all contribute to the length of primary cilia in wild type LLC-PK1 renal epithelial cells. The data indicate that proper regulation of PC2 function in the primary cilium may be essential in the onset of mechanisms that trigger cyst formation in ADPKD. AbstractPolycystin-2 (PC2, TRPP2) is a Ca 2+ permeable non-selective cation channel whose dysfunction generates autosomal dominant polycystic kidney disease (ADPKD). PC2 is present in different cell locations, including the primary cilium of renal epithelial cells. Little is known, however, as to whether PC2 contributes to the structure of the primary cilium. Here, we explored the effect(s) of external Ca 2+ , PC2 channel blockers, and PKD2 gene silencing on the length of primary cilia in wild type LLC-PK1 renal epithelial cells. To identify primary cilia and measure their length, confluent cell monolayers were fixed and immuno-labeled with an anti-acetylated -tubulin antibody.Although primary cilia length measurements did not follow a Normal distribution, data were normalized by Box-Cox transformation rendering statistical difference under all experimental conditions. Cells exposed to high external Ca 2+ (6.2 mM) decreased a 13.5% (p < 0.001) primary cilia length as compared to controls (1.2 mM Ca 2+ ). In contrast, the PC2 inhibitors amiloride (200 M) and LiCl (10 mM), both increased primary ciliary length by 33.2% (p < 0.001), and 17.4% (p < 0.001), respectively. PKD2 gene silencing by siRNA also elicited a statistically significant, 10.3% (p < 0.001) increase in primary cilia length, as compared to their respective scrambled RNA transfected cells. The data indicate that maneuvers that either regulate PC2 function or gene Polycystin-2-regulates primary cilium length 3 expression, modify the length of primary cilia in renal epithelial cells. Proper regulation of PC2 function in the primary cilium may be essential in the onset of mechanisms that trigger cyst formation in ADPKD.

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Lipid bilayer-atomic force microscopy combined platform records simultaneous electrical and topological changes of the TRP channel polycystin-2 (TRPP2)

et al. 2018

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Ion channels are transmembrane proteins that mediate ion transport across biological membranes. Ion channel function is traditionally characterized by electrical parameters acquired with techniques such as patch-clamping and reconstitution in lipid bilayer membranes (BLM) that provide relevant information such as ionic conductance, selectivity, and gating properties. High resolution structural information of ion channels however, requires independent technologies, of which atomic force microscopy (AFM) is the only one that provides topological features of single functional channel proteins in their native environments. To date practically no data exist on direct correlations between electrical features and topological parameters from functional single channel complexes. Here, we report the design and construction of a BLM reconstitution microchamber that supports the simultaneous recording of electrical currents and AFM imaging from single channel complexes. As proof-of-principle, we tested the technique on polycystin-2 (PC2, TRPP2), a TRP channel family member from which we had previously elucidated its tetrameric topology by AFM imaging, and single channel currents by the BLM technique. The experimental setup provided direct structural-functional correlates from PC2 single channel complexes that disclosed novel topological changes between the closed and open sub-conductance states of the functional channel, namely, an inverse correlation between conductance and height of the channel. Unexpectedly, we also disclosed intrinsic PC2 mechanosensitivity in response to external forces. The platform provides a suitable means of accessing topological information to correlate with ion channel electrical parameters essential to understand the physiology of these transmembrane proteins.

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Noelia Scarinci

Bundles of Brain Microtubules Generate Electrical Oscillations

External Ca 2+ regulates polycystin-2 (TRPP2) cation currents in LLC-PK1 renal epithelial cells

Two-Dimensional Brain Microtubule Structures Behave as Memristive Devices

Polycystin-2 (TRPP2) Regulates Primary Cilium Length in LLC-PK1 Renal Epithelial Cells

Lipid bilayer-atomic force microscopy combined platform records simultaneous electrical and topological changes of the TRP channel polycystin-2 (TRPP2)

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