Cultured cells from renal cortex of hibernators and nonhibernators. Regulation of cell K+ at low temperature

Cells were grown as primary monolayer cultures from kidney cortex of guinea pigs (nonhibernators), hamsters and ground squirrels (both hibernating species). When plates of cells were placed at 5 °C, cells of guinea pigs lost 37% of their K⁺ in 2 h and those of the hibernator lost about 10%.Uptake of ⁴²K into the cells exhibited a simple, single exponential time course at both temperatures. Unidirectional efflux of K⁺ was equal to K⁺ influx in all cultures at 37 °C and, within limits of error, in hibernator cells at 5 °C. Efflux was 3- to 5-fold greater than influx in guinea pig cells at 5 °C.After 2 h in the cold the ouabain-sensitive K⁺ influx remaining (7–15% of that at 37 °C) was about the same in the cells of the 3 species. Cells from active hamsters and from hibernating ground squirrels, however, exhibited significantly greater pump activity after 45 min in the cold (19 and 14%, respectively). The stimulation of K⁺ influx by increasing K⁺]_o did not show an increase in K_m⁺ at 5 °C in cells of guinea pigs and ground squirrels. Lowering K⁺]_c and/or raising Na⁺]_c by treatment in low- and high-K⁺ media caused only slight stimulation of K⁺ influx, except in cells of ground squirrels at 5 °C in which the stimulation was at least 11-times greater than at 37 °C or in cells of guinea pigs at either temperature.This altered kinetic response of K⁺ transport to cytoplasmic ion stimulation with cooling accounted for about one-third of the improved regulation of K⁺ at 5 °C in ground squirrel cells; the other two-thirds was attributable to a greater decrease in K⁺ leak with cooling. The inhibition of active transport by cold in all 3 species was much less severe than that previously seen in any (Na⁺ + K⁺)-ATPase of mammalian cells.