Viabilidad de la generación de energía hidrocinética en Uruguay a partir de las mareas

El presente proyecto se propuso generar lineamientos y recomendaciones para el desarrollo de la energía hidrocinética en Uruguay a partir de las corrientes de marea. La zona estudiada para posibles aprovechamientos se limitó a las aguas territoriales uruguayas del Río de la Plata y el mar territorial uruguayo. Se plantearon los siguientes objetivos específicos: 1-Determinar las características principales de las corrientes de marea en las aguas territoriales uruguayas; en particular, llegar a una zonificación de los rangos de corrientes y descripción de las características principales de su dinámica. 2- Determinar las tecnologías existentes más adecuadas según la valoración del recurso. 3- Llegar a una zonificación del potencial energético, incluyendo recomendaciones y lineamientos específicos; para ello se contemplarían los condicionamientos tecnológicos, físicos y ambientales. Contenido del informe: En la Sección I se muestra una visión general sobre generación eléctrica a partir de energías marinas, con énfasis en la hidroeléctrica a partir de las corrientes de marea. En la Sección II se describen las tecnologías existentes (en distinto grado de desarrollo y madurez) para la captación de la energía hidrocinética, la conversión en eléctrica y su trasmisión. En la Sección III se detalla el proceso de modelación de las corrientes para la zona de estudio y los resultados en términos de velocidades disponibles, potencias posibles y energías anuales extraíbles en distintos sitios; se identifican las zonas de mayor potencial de generación. En la Sección IV se hace una somera relación de los impactos que produce esta modalidad de generación de energía eléctrica. En la Sección V se realizan recomendaciones y se proponen líneas de actuación a los efectos de incorporar esta fuente energética en la matriz de generación eléctrica uruguaya.Agencia Nacional de Investigación e Innovació

Drosophila KCNQ Channel Displays Evolutionarily Conserved Electrophysiology and Pharmacology with Mammalian KCNQ Channels

Of the five human KCNQ (Kv7) channels, KCNQ1 with auxiliary subunit KCNE1 mediates the native cardiac IKs current with mutations causing short and long QT cardiac arrhythmias. KCNQ4 mutations cause deafness. KCNQ2/3 channels form the native M-current controlling excitability of most neurons, with mutations causing benign neonatal febrile convulsions. Drosophila contains a single KCNQ (dKCNQ) that appears to serve alone the functions of all the duplicated mammalian neuronal and cardiac KCNQ channels sharing roughly 50–60% amino acid identity therefore offering a route to investigate these channels. Current information about the functional properties of dKCNQ is lacking therefore we have investigated these properties here. Using whole cell patch clamp electrophysiology we compare the biophysical and pharmacological properties of dKCNQ with the mammalian neuronal and cardiac KCNQ channels expressed in HEK cells. We show that Drosophila KCNQ (dKCNQ) is a slowly activating and slowly-deactivating K+ current open at sub-threshold potentials that has similar properties to neuronal KCNQ2/3 with some features of the cardiac KCNQ1/KCNE1 accompanied by conserved sensitivity to a number of clinically relevant KCNQ blockers (chromanol 293B, XE991, linopirdine) and opener (zinc pyrithione). We also investigate the molecular basis of the differential selectivity of KCNQ channels to the opener retigabine and show a single amino acid substitution (M217W) can confer sensitivity to dKCNQ. We show dKCNQ has similar electrophysiological and pharmacological properties as the mammalian KCNQ channels, allowing future study of physiological and pathological roles of KCNQ in Drosophila and whole organism screening for new modulators of KCNQ channelopathies

Affinity for phosphatidylinositol 4,5-bisphosphate determines muscarinic agonist sensitivity of Kv7 K+ channels

Kv7 K+-channel subunits differ in their apparent affinity for PIP2 and are differentially expressed in nerve, muscle, and epithelia in accord with their physiological roles in those tissues. To investigate how PIP2 affinity affects the response to physiological stimuli such as receptor stimulation, we exposed homomeric and heteromeric Kv7.2, 7.3, and 7.4 channels to a range of concentrations of the muscarinic receptor agonist oxotremorine-M (oxo-M) in a heterologous expression system. Activation of M1 receptors by oxo-M leads to PIP2 depletion through Gq and phospholipase C (PLC). Chinese hamster ovary cells were transiently transfected with Kv7 subunits and M1 receptors and studied under perforated-patch voltage clamp. For Kv7.2/7.3 heteromers, the EC50 for current suppression was 0.44 ± 0.08 µM, and the maximal inhibition (Inhibmax) was 74 ± 3% (n = 5–7). When tonic PIP2 abundance was increased by overexpression of PIP 5-kinase, the EC50 was shifted threefold to the right (1.2 ± 0.1 µM), but without a significant change in Inhibmax (73 ± 4%, n = 5). To investigate the muscarinic sensitivity of Kv7.3 homomers, we used the A315T pore mutant (Kv7.3T) that increases whole-cell currents by 30-fold without any change in apparent PIP2 affinity. Kv7.3T currents had a slightly right-shifted EC50 as compared with Kv7.2/7.3 heteromers (1.0 ± 0.8 µM) and a strongly reduced Inhibmax (39 ± 3%). In contrast, the dose–response curve of homomeric Kv7.4 channels was shifted considerably to the left (66 ± 8 nM), and Inhibmax was slightly increased (81 ± 6%, n = 3–4). We then studied several Kv7.2 mutants with altered apparent affinities for PIP2 by coexpressing them with Kv7.3T subunits to boost current amplitudes. For the lower affinity (Kv7.2 (R463Q)/Kv7.3T) or higher affinity (Kv7.2 (R463E)/Kv7.3T) channels, the EC50 and Inhibmax were similar to Kv7.4 or Kv7.3T homomers (0.12 ± 0.08 µM and 79 ± 6% [n = 3–4] and 0.58 ± 0.07 µM and 27 ± 3% [n = 3–4], respectively). The very low-affinity Kv7.2 (R452E, R459E, and R461E) triple mutant was also coexpressed with Kv7.3T. The resulting heteromer displayed a very low EC50 for inhibition (32 ± 8 nM) and a slightly increased Inhibmax (83 ± 3%, n = 3–4). We then constructed a cellular model that incorporates PLC activation by oxo-M, PIP2 hydrolysis, PIP2 binding to Kv7-channel subunits, and K+ current through Kv7 tetramers. We were able to fully reproduce our data and extract a consistent set of PIP2 affinities

KV7 Channel Expression and Function Within Rat Mesenteric Endothelial Cells.

Background and Purpose: Arterial diameter is dictated by the contractile state of the vascular smooth muscle cells (VSMCs), which is modulated by direct and indirect inputs from endothelial cells (ECs). Modulators of KCNQ-encoded kV7 channels have considerable impact on arterial diameter and these channels are known to be expressed in VSMCs but not yet defined in ECs. However, expression of kV7 channels in ECs would add an extra level of vascular control. This study aims to characterize the expression and function of KV7 channels within rat mesenteric artery ECs. Experimental Approach: In rat mesenteric artery, KCNQ transcript and KV7 channel protein expression were determined via RT-qPCR, immunocytochemistry, immunohistochemistry and immunoelectron microscopy. Wire myography was used to determine vascular reactivity. Key Results: KCNQ transcript was identified in isolated ECs and VSMCs. KV7.1, KV7.4 and KV7.5 protein expression was determined in both isolated EC and VSMC and in whole vessels. Removal of ECs attenuated vasorelaxation to two structurally different KV7.2-5 activators S-1 and ML213. KIR2 blockers ML133, and BaCl2 also attenuated S-1 or ML213-mediated vasorelaxation in an endothelium-dependent process. KV7 inhibition attenuated receptor-dependent nitric oxide (NO)-mediated vasorelaxation to carbachol, but had no impact on relaxation to the NO donor, SNP. Conclusion and Implications: In rat mesenteric artery ECs, KV7.4 and KV7.5 channels are expressed, functionally interact with endothelial KIR2.x channels and contribute to endogenous eNOS-mediated relaxation. This study identifies KV7 channels as novel functional channels within rat mesenteric ECs and suggests that these channels are involved in NO release from the endothelium of these vessels

Synergistic interplay of Gβγ and phosphatidylinositol 4,5-bisphosphate dictates Kv7.4 channel activity.

Kv7.4 channels are key determinants of arterial contractility and cochlear mechanosensation that, like all Kv7 channels, have an obligatory requirement for phosphatidylinositol 4,5-bisphosphate (PIP2). βγ G proteins (Gβγ) have been identified as novel positive regulators of Kv7.4. The present study ascertained whether Gβγ increased Kv7.4 open probability through an increased sensitivity to PIP2. In HEK cells stably expressing Kv7.4, PIP2 or Gβγ increased open probability in a concentration dependent manner. Depleting PIP2 prevented any Gβγ-mediated stimulation whilst an array of Gβγ inhibitors prohibited any PIP2-induced current enhancement. A combination of PIP2 and Gβγ at sub-efficacious concentrations increased channel open probability considerably. The stimulatory effects of three Kv7.2-7.5 channel activators were also lost by PIP2 depletion or Gβγ inhibitors. This study alters substantially our understanding of the fundamental processes that dictate Kv7.4 activity, revealing a more complex and subtle paradigm where the reliance on local phosphoinositide is dictated by interaction with Gβγ

Refinement of the Binding Site and Mode of Action of the Anticonvulsant Retigabine on KCNQ K Channels

Lange W, Geißendörfer J, Schenzer A, et al. Refinement of the Binding Site and Mode of Action of the Anticonvulsant Retigabine on KCNQ K Channels. Molecular Pharmacology. 2009;75(2):272-280.The discovery of retigabine has provided access to alternative anticonvulsant compounds with a novel mode of action. Acting as potassium channel opener, retigabine exclusively activates neuronal KCNQ-type K+ channels, mainly by shifting the voltage-dependence of channel activation to hyperpolarizing potentials. So far, only parts of the retigabine-binding site have been described, including Trp-265 and Gly-340 (according to KCNQ3 numbering) within transmembrane segments S5 and S6, respectively. Using a refined chimeric strategy, we additionally identified a Leu-314 within the pore region of KCNQ3 as crucial for the retigabine effect. Both Trp-265 and Leu-314 are likely to interact with the retigabine molecule, representing the upper and lower margins of the putative binding site. Guided by a structural model of KCNQ3, which was constructed based on the Kv1.2 crystal structure, further residues affecting retigabine-binding could be proposed and were experimentally verified as mediators for the action of the compound. These results strongly suggest that, besides Trp-265 and Leu-314, it is highly likely that another S5 residue, Leu-272, which is conserved in all KCNQ subunits, contributes to the binding site in KCNQ3. More importantly, Leu-338, extending from S6 of the neighboring subunit is also apparently involved in lining the hydrophobic binding pocket for the drug. This pocket, which is formed at the interface of two adjacent subunits, may be present only in the open state of the channel, consistent with the idea that retigabine stabilizes an open-channel conformation

Molecular Determinants of KCNQ (Kv7) K+ Channel Sensitivity to the Anticonvulsant Retigabine

Schenzer A, Friedrich T, Pusch M, et al. Molecular Determinants of KCNQ (Kv7) K+ Channel Sensitivity to the Anticonvulsant Retigabine. Journal of Neuroscience. 2005;25(20):5051-5060