FC025: Physiological Role of KV Channel in Ureter Smooth Muscle Cell Investigated Quantitatively by Electrophysiological Modeling

Abstract

Abstract BACKGROUND AND AIMS Spontaneous peristaltic contraction disorder of the ureter smooth muscle (USM) is an important etiology of congenital giant ureter, congenital ureteropelvic junction deformity and non-obstructive hydronephrosis [1]. The USM cell action potential (AP) plays a key role in commencing USM contraction by allowing influx of Ca2+ from the extra cellular space [2]. Therefore, an in-depth quantitative investigation of the USM cell AP generation will assist in developing better pharmacological therapies for the USM abnormal contraction. The purpose of this in-silico study is to unfold the physiological role of Kv channel in modulating the USM AP generation. METHOD The model consists voltage- dependent Na+ currents (INa), hyperpolarization-activated cyclic nucleotide- gated current (Ih), voltage- dependent Ca2+ currents (ICa), Ca2+ dependent potassium channel (IBKCa) and voltage-dependent potassium channels (IKv) as the components of active electrophysiological characteristics [3]. All ion channels are represented by the Hodgkin–Huxley formalism. The maximum conductance of the is varied to investigate the physiological role of the Kv channel in modulating the USM AP generation. RESULTS The whole cell IKv current is generated by applying the voltage clamp protocol, where the membrane potential is stepped from a holding potential of –80 mV–60 mV for a duration of 500 ms. The half activation potential, half inactivation potential, activation slope factor and inactivation slope factors are: 43 mV, –76.1 mV, 15.4 mV and 6.5 mV, respectively, to fit the Boltzmann function equation. The model reveals that fast activation and inactivation properties are the essential feature of IKv for the USM cell. The resting membrane potential (RMP) is set at –50 mV. The AP was induced in the whole cell model by applying an external stimulus current (10–30 pA), as a brief square pulse of 500 ms duration. It is demonstrated that IKv opposes the Ca2+ current during the first 50 ms of the AP duration and then inactivated. It doesn't contribute to the repolarizing phase of the AP. CONCLUSION The plateau phase of the USM AP shows that the total AP duration much longer than that in other smooth muscle cells. It strongly supports the phenomenon is due to the activation of Ca2+-dependent K+ channel and inactivation of L-type Ca2+ channel. In ureter cells, the IKv does not contribute significantly to the repolarization of the AP, but it may regulate membrane excitability by opposing Ca2+ current activated around the threshold of the AP. Therefore, the agonist and antagonist of the IKv might be useful partially as new pharmacological targets for the USM abnormal contraction.