State-dependent blocking mechanism of Kv 1.3 channels by the antimycobacterial drug clofazimine.

BACKGROUND AND PURPOSE: Kv 1.3 potassium channels are promising pharmaceutical targets for treating immune diseases as they modulate Ca(2+) signalling in T cells by regulating the membrane potential and with it the driving force for Ca(2+) influx. The antimycobacterial drug clofazimine has been demonstrated to attenuate antigen-induced Ca(2+) oscillations, suppress cytokine release and prevent skin graft rejection by inhibiting Kv 1.3 channels with high potency and selectivity. EXPERIMENTAL APPROACH: We used patch-clamp methodology to investigate clofazimine's mechanism of action in Kv 1.3 channels expressed in HEK293 cells. KEY RESULTS: Clofazimine blocked Kv 1.3 channels by involving two discrete mechanisms, both of which contribute to effective suppression of channels: (i) a use-dependent open-channel block during long depolarizations, resulting in accelerated K(+) current inactivation and (ii) a block of closed deactivated channels after channels were opened by brief depolarizations. Both modes of block were use-dependent and state-dependent in that they clearly required prior channel opening. The clofazimine-sensitive closed-deactivated state of the channel was distinct from the resting closed state because channels at hyperpolarized voltages were not inhibited by clofazimine. Neither were channels in the C-type inactivated state significantly affected. Kv 1.3 channels carrying the H399T mutation and lacking C-type inactivation were insensitive to clofazimine block of the closed-deactivated state, but retained their susceptibility to open-channel block. CONCLUSIONS AND IMPLICATIONS: Given the prominent role of Kv 1.3 in shaping Ca(2+) oscillations, the use-dependent and state-dependent block of Kv 1.3 channels by clofazimine offers therapeutic potential for selective immunosuppression in the context of autoimmune diseases in which Kv 1.3-expressing T cells play a significant role.

pH Dependent but not P-gp Dependent Bidirectional Transport Study of S-propranolol: The Importance of Passive Diffusion.

PURPOSE: Recent controversial publications, citing studies purporting to show that P-gp mediates the transport of propranolol, proposed that passive biological membrane transport is negligible. Based on the BDDCS, the extensively metabolized-highly permeable-highly soluble BDDCS class 1 drug, propranolol, shows a high passive permeability at concentrations unrestricted by solubility that can overwhelm any potential transporter effects. Here we reinvestigate the effects of passive diffusion and carrier-mediated transport on S-propranolol. METHODS: Bidirectional permeability and inhibition of efflux transport studies were carried out in MDCK, MDCK-MDR1 and Caco-2 cell lines at different concentrations. Transcellular permeability studies were conducted at different apical pHs in the rat jejunum Ussing chamber model and PAMPA system. RESULTS: S-propranolol exhibited efflux ratios lower than 1 in MDCK, MDCK-MDR1 and Caco-2 cells. No significant differences of Papp, B->A in the presence and absence of the efflux inhibitor GG918 were observed. However, an efflux ratio of 3.63 was found at apical pH 6.5 with significant decrease in Papp, A->B and increase in Papp, B->A compared to apical pH 7.4 in Caco-2 cell lines. The pH dependent permeability was confirmed in the Ussing chamber model. S-propranolol flux was unchanged during inhibition by verapamil and rifampin. Furthermore, pH dependent permeability was also observed in the PAMPA system. CONCLUSIONS: S-propranolol does not exhibit active transport as proposed previously. The "false" positive efflux ratio can be explained by the pH partition theory. As expected, passive diffusion, but not active transport, plays the primary role in the permeability of the BDDCS class 1 drug propranolol.