Kevin F Webb1, Paul J Donaldson. 1. Department of Physiology, School of Medical Sciences, University of Auckland, Auckland, New Zealand.
Abstract
PURPOSE: To test the hypothesis that lens fiber cells use different combinations of transport proteins to mediate Cl influx and efflux in order to regulate their steady state volume. METHODS: Cells were isolated from rat lenses by enzymatic dissociation in the presence of Gd(3+), and short and long fiber cells were assigned to peripheral efflux and deeper influx zones, respectively. Electrical properties were of isolated cells, and whole lenses were analyzed by using whole-cell patch clamping and intracellular microelectrodes, respectively, before and after exposure to hyposmotic challenge and/or the addition of [(dihydronindenyl)oxy] alkanoic acid (DIOA). RESULTS: Cells from the influx zone were dominated by an outwardly rectifying Cl(-) conductance, and exposure to hyposmotic challenge increased this conductance. Cells isolated from the efflux zone were dominated by K(+) conductance(s) with only a minimal contribution from the Cl(-) conductance. Exposure of cells that exhibited a minimal baseline Cl(-) conductance to hyposmotic challenge caused swelling and a transient increase in Cl(-) current. In other cells that initially lacked a Cl(-) conductance, hyposmotic challenge caused swelling, but no increase in outward current. However, the subsequent addition of DIOA exacerbated swelling and activated a Cl(-) current. Under isosmotic conditions, addition of DIOA also induced cell swelling and the transient activation of a Cl(-) current. In whole lenses, exposure to hyposmotic challenge increased the contribution of an anion conductance to the membrane potential. CONCLUSIONS: In peripheral cells, Cl(-) efflux is primarily mediated by potassium chloride cotransporters (KCCs) and its activity can be upregulated by hyposmotic challenge. In addition, these cells also contain a Cl(-) channel that exhibits a variable baseline activity level and that can be recruited to effect regulatory volume decrease if the KCC transporters are inhibited.
PURPOSE: To test the hypothesis that lens fiber cells use different combinations of transport proteins to mediate Cl influx and efflux in order to regulate their steady state volume. METHODS: Cells were isolated from rat lenses by enzymatic dissociation in the presence of Gd(3+), and short and long fiber cells were assigned to peripheral efflux and deeper influx zones, respectively. Electrical properties were of isolated cells, and whole lenses were analyzed by using whole-cell patch clamping and intracellular microelectrodes, respectively, before and after exposure to hyposmotic challenge and/or the addition of [(dihydronindenyl)oxy] alkanoic acid (DIOA). RESULTS: Cells from the influx zone were dominated by an outwardly rectifying Cl(-) conductance, and exposure to hyposmotic challenge increased this conductance. Cells isolated from the efflux zone were dominated by K(+) conductance(s) with only a minimal contribution from the Cl(-) conductance. Exposure of cells that exhibited a minimal baseline Cl(-) conductance to hyposmotic challenge caused swelling and a transient increase in Cl(-) current. In other cells that initially lacked a Cl(-) conductance, hyposmotic challenge caused swelling, but no increase in outward current. However, the subsequent addition of DIOA exacerbated swelling and activated a Cl(-) current. Under isosmotic conditions, addition of DIOA also induced cell swelling and the transient activation of a Cl(-) current. In whole lenses, exposure to hyposmotic challenge increased the contribution of an anion conductance to the membrane potential. CONCLUSIONS: In peripheral cells, Cl(-) efflux is primarily mediated by potassium chloride cotransporters (KCCs) and its activity can be upregulated by hyposmotic challenge. In addition, these cells also contain a Cl(-) channel that exhibits a variable baseline activity level and that can be recruited to effect regulatory volume decrease if the KCC transporters are inhibited.