Moreover, the rat mesenteric
artery reportedly does not express functional NMDArs (51). (±)Ketamine racemate has been reported to inhibited NR1/NR2A and NR1/NR2B channels with IC50 values of 13.6 ± 8.5 and 17.6 ± 7.2 μM, respectively, whereas S(+)-ketamine inhibited NR1/NR2A and NR1/NR2B with IC50 values of 4.1 ± 2.5 and 3.0 ± 0.3 μM, respectively (52). The IC50 values of (+)MK801 and (−)MK801 for inhibiting channels with the NR1 subunit and various NR2 subunit complexes (NR1/NR2X) ranged LGK974 from 9–38 nM and from 32–354 nM, respectively. These IC50 values for inhibiting NMDArs are distinct from those for inhibiting Kv of RMASMCs. The pKa of MK801 is 8.37, and thus approximately 94% of MK801 exists in its protonated, positively charged form at pH 7.2 (the pH of the pipette solution). The results of this study showed that MK801 inhibition of Kv-channel currents was completely voltage-independent (Fig. 3), which suggests that the MK801-binding site of Kv channels is not affected by the sensing of the transmembrane potential, unlike in the case find more of the binding sites for open-pore blocking agents. In this study, we did not examine whether an extra-
or intra-cellular site is responsible for the MK801-Kv channel interaction, which warrants future investigation. As described above, MK801 is a potent NMDAr inhibitor. NMDAr is a glutamate receptor and glutamate is the brain’s primary excitatory neurotransmitter. NMDAr is an ionotropic receptor that, when activated, causes the influx of Ca2+ and other cations. MK801 blocks the NMDAr in a state- and voltage-dependent manner, because the PCP-binding sites in the NMDAr are accessible to MK801 only when the channel is open or activated. Therefore, the mechanism by which MK801 was determined
to inhibit the Kv channels of RMASMCs in this study differs considerably from the mechanism of MK801 inhibition of the NMDAr channel. Because we examined the effect of MK801 on native Kv-channel currents in RMASMCs in this study, the specific target of MK801 remains unknown. Multimeric heteromers of several Kv-channel subunits such as Kv1.1, Kv1.2, Kv1.5, and Kv2.1 have been reported to contribute to the native Kv-channel currents of vascular smooth Florfenicol muscle (53), (54) and (55). Furthermore, certain auxiliary Kv-channel beta subunits have been reported to contribute to the complexity and heterogeneity of native Kv currents (56) and (57). These Kv-channel subunits play critical roles in variety of excitable and non-excitable cells such as those in the cardiovascular system and in the CNS. Therefore, future studies could examine the effect of MK801 on specific Kv-channel subunits expressed in heterologous cell systems. As we stated above, we have observed that MK801 blocked the Kv1.5 expressed in CHO cells. The blockade of Kv1.5 by MK801 was very similar with that the present study.