Calcium-gated K+ channels of the KCa1.1- and KCa3.1-type couple intracellular Ca2+ signals to membrane hyperpolarization in mesenchymal stromal cells from the human adipose tissue.

Electrogenesis in mesenchymal stromal cells (MSCs) remains poorly understood. Little is known about ion channels active in resting MSCs and activated upon MSC stimulation, particularly, by agonists mobilizing Ca2+ in the MSC cytoplasm. A variety of Ca2+-gated ion channels may couple Ca2+ signals to polarization of the plasma membrane. Here, we studied MSCs from the human adipose tissue and found that in cells responsive to ATP and adenosine with Ca2+ transients or exhibiting spontaneous Ca2+ oscillations, Ca2+ bursts were associated with hyperpolarization mediated by Ca2+-gated K+ channels. The expression analysis revealed transcripts for KCNMA1 and KCNN4 genes encoding for Ca2+-activated K+ channels of large (KCa1.1) and intermediate (KCa3.1) conductance, respectively. Moreover, transcripts for the Ca2+-gated cation channel TRPM4 and anion channels Ano1, Ano2, and bestrophin-1, bestrophin-3, and bestrophin-4 were revealed. In all assayed MSCs, a rise in cytosolic Ca2+ stimulated K+ currents that were inhibited with iberiotoxin. This suggested that KCa1.1 channels are invariably expressed in MSCs. In ATP- and adenosine-responsive cells, iberiotoxin and TRAM-34 diminished electrical responses, implicating both KCa1.1 and KCa3.1 channels in coupling agonist-dependent Ca2+ signals to membrane voltage. Functional tests pointed at the existence of two separate MSC subpopulations exhibiting Ca2+-gated anion currents that were mediated by Ano2-like and bestrophin-like anion channels, respectively. Evidence for detectable activity of Ano1 and TRPM4 was not obtained. Thus, KCa1.1 channels are likely to represent the dominant type of Ca2+-activated K+ channels in MSCs, which can serve in concert with KCa3.1 channels as effectors downstream of G-protein-coupled receptor (GPCR)-mediated Ca2+ signaling.