Dronedarone blockage of the tumor-related Kv10.1 channel: a comparison with amiodarone.

Kv10.1 (Eag1, or KCNH1) is a human potassium-selective channel associated with tumor development. In this work, we study the interaction of the drug dronedarone with Kv10.1. Dronedarone presents two chemical modifications aimed to lessen side effects produced by its parent molecule, the antiarrhythmic amiodarone. Hence, our observations are discussed within the framework of a previously reported interaction of amiodarone with Kv10.1. Additionally, we show new data regarding the interaction of amiodarone with the channels. We found that, unexpectedly, the effect of dronedarone on Kv10.1 differs both quantitatively and qualitatively to that of amiodarone. Among other observations, we found that dronedarone seems to be an open-pore blocker, in contrast to the reported behavior of amiodarone, which seems to inhibit from both open and closed states. Additionally, herein we provide evidence showing that, in spite of their chemical similarity, these molecules inhibit the K+ conductance by binding to non-overlapping, independent (non-allosterically related) sites. Also, we show that, while amiodarone inhibits the Cole-Moore shift, dronedarone is unable to inhibit this voltage-dependent characteristic of Kv10.1.

Correction to: Inhibition of the K+ conductance and Cole-Moore shift of the oncogenic Kv10.1 channel by amiodarone.

The original publication of this article contained multiple technical errors that occurred during its production and printing. These errors included sentences and paragraphs with parts missing. The Publisher regrets these mistakes.

Inhibition of the K+ conductance and Cole-Moore shift of the oncogenic Kv10.1 channel by amiodarone.

The ectopic overexpression of the voltage-dependent Eag1 (Kv10.1) K+ channel is associated with the cancerous phenotype in about 70% of human cancers and tumor cell lines. Recent reports showed that, compared with the canonical Shaker-related Kv family, Kv10.1 presents unique structural and functional properties. Herein, we report the interaction of the class III anti-arrhythmic compound amiodarone with Kv10.1. Using whole-cell patch clamp, we found that amiodarone inhibits Kv10.1 channel conductance with nanomolar affinity. Additionally, and interestingly, we also report that amiodarone inhibits the characteristic Cole-Moore shift of Eag1 channels. Our observations are interpreted considering the structural-functional characteristics of these channels. We conclude that amiodarone possibly binds with high affinity to the voltage sensor module, altering the gating of Kv10.1.

Study of permeation and blocker binding in TMEM16A calcium-activated chloride channels.

We studied the effects of mutations of positively charged amino acid residues in the pore of X. tropicalis TMEM16A calcium-activated chloride channels: K613E, K628E, K630E; R646E and R761E. The activation and deactivation kinetics were not affected, and only K613E showed a lower current density. K628E and R761E affect anion selectivity without affecting Na(+) permeation, whereas K613E, R646E and the double mutant K613E + R646E affect anion selectivity and permeability to Na(+). Furthermore, altered blockade by the chloride channel blockers anthracene-9-carboxylic acid (A-9-C), 4, 4'-Diisothiocyano-2,2'-stilbenedisulfonic acid (DIDS) and T16inh-A01 was observed. These results suggest the existence of 2 binding sites for anions within the pore at electrical distances of 0.3 and 0.5. These sites are also relevant for anion permeation and blockade.

TMEM16A alternative splicing isoforms in Xenopus tropicalis: distribution and functional properties.

Oocytes of Xenopus tropicalis elicit a Ca(2+)-dependent outwardly rectifying, low-activating current (ICl,Ca) that is inhibited by Cl(-) channel blockers. When inactivated, ICl,Ca shows an exponentially decaying tail current that is related to currents generated by TMEM16A ion channels. Accordingly, RT-PCR revealed the expression of five alternatively spliced isoforms of TMEM16A in oocytes, which, after expression in HEK-293 cells, gave rise to fully functional Cl(-) channels. Upon hyperpolarization to -80 mV a transient current was observed only in isoforms that carry the exon 1d, coding for two potentially phosphorylatable Threonine residues. The identified isoforms are differentially expressed in several tissues of the frog. Thus, it appears that X. tropicalis oocytes express TMEM16A that gives rise to a Ca(2+)-dependent Cl(-) current, which is different from the previously reported voltage-dependent outwardly rectifying Cl(-) current.

Anion permeation in calcium-activated chloride channels formed by TMEM16A from Xenopus tropicalis.

Calcium-activated chloride channels (CaCC) formed by anoctamin1/TMEM16A subunits are ubiquitously expressed, and these channels are known to prevent polyspermy in amphibian oocytes. Here, we describe a TMEM16A clone isolated from Xenopus tropicalis oocytes (xtTMEM16A) and how the anion permeation properties are modified in single-site mutants of the ion pore. The anion permeability sequence was SCN(-) > I(-) > Br(-) > Cl(-) > gluconate (relative permeabilities 5.6:3.0:2.1:1:0.2, respectively). Dose-response curves indicated that the voltage-dependent half-maximal concentration for Ca(2+) activation (K d of the Hill equation at +100 mV) was 120 nM in normal external Cl(-), whereas it was displaced leftward to 75 nM Ca(2+), when I(-) replaced Cl(-). The I(-):Cl(-) mole fraction (MF) of the external solution was varied in order to gain insight into the permeation mechanism of the pore. No anomaly in MF behavior was observed for conductance, but it was observed for current reversal potential, which deviated from the prediction of the Goldman-Hodgkin-Katz equation. Mutations of positively charged amino acids in the pore, R646 and R761, to glutamate resulted in reduction of the relative permeability to I(-). Data from the wild type and mutants could be well fitted by a three-barrier, two-site permeation model. This suggests a multi-ion pore with at least two binding sites for anions, with R646 mole fraction closer to the extracellular membrane surface--being important for the stability of both sites--and R761--located deeper within the membrane--mainly affecting the innermost binding site. Considerations of xtTMEM16A putative pore region topology are discussed in the light of two alternative topological models of the protein.

Amyloid ß oligomers decrease hippocampal spontaneous network activity in an age-dependent manner.

Soluble amyloid beta (Abeta) oligomers might trigger early cognitive impairment in Alzheimer's Disease (AD) through the impairment of proper neuronal network function. We have recently shown that the short sequence Abeta(25-35) affects the spontaneous activity in hippocampal slices, when was added to the bath, at high nanomolar concentrations. In the present study, we aimed to characterize the effects of the oligomerized full length sequence Abeta(1-42) on the spontaneous network activity in the CA1 hippocampal area testing whether such effects are age dependent. By performing extracellular field recordings of spontaneous network activity of hippocampal slices, we found that an oligomerized solution of Abeta(1-42) (osAbeta) potently inhibit, in a dose-dependent manner, the spontaneous hippocampal network activity with an IC(50) of 0.4 +/- 3.2 nM and a maximal effect reached around 10 nM. While spontaneous hippocampal network activity is unaffected by age, the sensitivity of spontaneous hippocampal network activity to osAbeta (10 nM) appears to be increased in slices from older animals. Moreover, to see a significant reduction in spontaneous network activity in slices from animals in their second week of life 100nM osAbeta was needed. The osAbeta-induced reduction in hippocampal network activity is accompanied by a presynaptic reduction in both spontaneous and miniature synaptic potentials. Finally, we demonstrated that the effect produced by osAbeta on spontaneous network activity was specific, reversible and unrelated with cell death. In conclusion, our data show that osAbeta alters hippocampal network activity at concentrations commonly observed in AD patients and that such effect of osAbeta increase with age.