An inhibitor of K+ channels modulates human endometrial tumor-initiating cells.

Background: Many potassium ion (K+) channels function as oncogenes to sustain growth of solid tumors, but their role in cancer progression is not well understood. Emerging evidence suggests that the early progenitor cancer cell subpopulation, termed tumor initiating cells (TIC), are critical to cancer progression.

Results: A non-selective antagonist of multiple types of K+ channels, tetraethylammonium (TEA), was found to suppress colony formation in endometrial cancer cells via inhibition of putative TIC.

Effects of bevacizumab in mouse model of endometrial cancer: Defining the molecular basis for resistance.

Endometrial cancer is the most frequent gynecologic cancer in women. Long-term outcomes for patients with advanced stage or recurrent disease are poor. Targeted molecular therapy against the vascular endothelial growth factor (VEGF) and its receptors constitute a new therapeutic option for these patients.

Disruption of the maxi-K-caveolin-1 interaction alters current expression in human myometrial cells.

Background: One determinant of the total K+ myometrial smooth muscle cell (MSMC) current is the large conductance, calcium- and voltage-activated potassium channel (maxi-K channel). This channel provides a repolarizing current in response to excitatory stimuli, most notably in response to increases in the levels of intracellular Ca2+, and blocking the channel by pharmacological means induces the depolarization of MSMCs and also enhances contraction strength. In MSMCs, maxi-K channels can reside in the caveolae, where they associate with the scaffolding protein caveolin-1 (cav-1).

Nardilysin convertase regulates the function of the maxi-K channel isoform mK44 in human myometrium.

In smooth muscle, large-conductance Ca(2+)- and voltage-activated K(+) channels from the gene KCNMA (maxi-K channels) generate isoforms with disparate responses to contractile stimuli. We previously showed that the human myometrium expresses high levels of the splice variant of the maxi-K channel containing a 44-amino acid insertion (mK44). The studies presented here demonstrate that nardilysin convertase, a Zn(2+)-dependent metalloprotease of the insulinase family, regulates the plasma membrane expression of mK44 and its response to increases in intracellular Ca(2+).

Acid-sensing ion channels interact with and inhibit BK K+ channels.

Acid-sensing ion channels (ASICs) are neuronal non-voltage-gated cation channels that are activated when extracellular pH falls. They contribute to sensory function and nociception in the peripheral nervous system, and in the brain they contribute to synaptic plasticity and fear responses. Some of the physiologic consequences of disrupting ASIC genes in mice suggested that ASIC channels might modulate neuronal function by mechanisms in addition to their H(+)-evoked opening.

Potassium channels and uterine function.

Ion channels are effector proteins that mediate uterine excitability throughout gestation. This review will focus primarily on the role of potassium channels in regulating myometrial tone in pregnancy and labor contractions. During gestation, potassium channels maintain the uterus in a state of quiescence by contributing to the resting membrane potential and counteracting contractile stimuli.

RhoA activation contributes to sex differences in vascular contractions.

Objective: Studies have suggested that sex differences in endothelial function in part account for the lower incidence of cardiovascular disease in premenopausal women compared with men. Less is known about the role of smooth muscle. We hypothesized that signaling mechanisms that regulate calcium sensitivity in vascular muscle also play a role in determining sex differences in contractile function.

Translocation of an endoproteolytically cleaved maxi-K channel isoform: mechanisms to induce human myometrial cell repolarization.

Large conductance Ca(2+)- and voltage-activated K+ (maxi-K) channels modulate human myometrial smooth muscle cell (hMSMC) excitability; however, the role of individual alternatively spliced isoforms remains unclear. We have previously shown that the transcript of a human maxi-K channel isoform (mK44) is expressed predominantly in myometrial and aortic smooth muscle and forms a functional channel in heterologous expression systems. The mK44 isoform contains unique consensus motifs for both endoproteolytic cleavage and N-myristoylation, although the function of these post-translational modifications is unknown.

Estradiol binding to maxi-K channels induces their down-regulation via proteasomal degradation.

Estrogens exert their biological action via both genomic and non-genomic mechanisms. Proteins different from classical estradiol receptors are believed to mediate the latter effects. Here we demonstrate that the maxi-K channel functions as an estrogen-binding protein in transfected HEK293 cells.

Detection and implications of potassium channel alterations.

Potassium channel dysfunction plays a role in the pathogenesis of a number of vascular diseases including pulmonary and systemic hypertension, diabetes, and complications of atherosclerosis. Two types of K+ channels that are known to be prevalent and contribute significantly to the repolarization of vascular smooth muscle cell (SMC) membranes are the high-conductance Ca(2+)- and voltage-activated K+ (BKCa) channels, and the voltage-gated K+ (KV) channels. Alterations in either BKCa or KV channel function can have dramatic effects on vascular tone.

Myometrial maxi-K channel beta1 subunit modulation during pregnancy and after 17beta-estradiol stimulation.

Myometrial maxi-K channels are modulated by beta subunits. We aimed to determine whether beta subunits are modulated to affect uterine excitability during gestation. RNase protection analyses revealed that mouse beta1 subunit transcripts are regulated during gestation with peak expression at day 14 of pregnancy.

Molecular diversity of vascular potassium channel isoforms.

1. One essential role for potassium channels in vascular smooth muscle is to buffer cell excitation and counteract vasoconstrictive influences. Several molecular mechanisms regulate potassium channel function.