Hypotonicity-induced anion fluxes in cells expressing the multidrug-resistance-associated protein, MRP.

Anion transport in human multidrug-resistant large cell lung tumour cells (COR-L23/R) which overexpress the multidrug-resistance-associated protein (MRP) has been compared with that in cells of the parent line (COR-L23/P). Whole-cell patch-clamp recordings reveal variability between individual cells in basal anion conductance and in anion conductance increases following exposure to hypotonic media. The increase of stimulated over basal conductance is significantly larger for resistant cells than for parent cells. The chloride channel blocker, diisothiocyanatostilbene-2-2'-disulphonic acid (DIDS), rapidly and reversibly inhibits the increase in outward but not inward conductance when applied externally at 10(-4) M during recording, but it is without effect when introduced into the cells via the patch pipette. Preincubation with DIDS greatly reduces both inward and outward conductance. 125I- efflux has been used to measure anion movement in cell populations. Basal efflux is similar in the two cell lines, but following a hypotonic challenge, the increase in rate constant for efflux from COR-L23/R cells is at least double that from COR-L23/P cells. This increase in efflux is greatly reduced by incubation with DIDS at 10(-4) M. Replacement of external chloride by gluconate does not affect efflux, thus excluding the possible involvement of DIDS-sensitive chloride exchange. Results from both techniques suggest that DIDS-sensitive, hypotonicity-induced anion channel activity is augmented in COR-L23/R multidrug-resistant variant cells which overexpress MRP. This augmentation may be caused by MRP itself or by other genes coexpressed with MRP.