A Cl(−) Cotransporter Selective for Nh(4) (+) over K(+) in Glial Cells of Bee Retina

There appears to be a flux of ammonium (NH(4) (+)/NH(3)) from neurons to glial cells in most nervous tissues. In bee retinal glial cells, NH(4) (+)/NH(3) uptake is at least partly by chloride-dependant transport of the ionic form NH(4) (+). Transmembrane transport of NH(4) (+) has been described previously on transporters on which NH(4) (+) replaces K(+), or, more rarely, Na(+) or H(+), but no transport system in animal cells has been shown to be selective for NH(4) (+) over these other ions. To see if the NH(4) (+)-Cl(−) cotransporter on bee retinal glial cells is selective for NH(4) (+) over K(+) we measured ammonium-induced changes in intracellular pH (pH(i)) in isolated bundles of glial cells using a fluorescent indicator. These changes in pH(i) result from transmembrane fluxes not only of NH(4) (+), but also of NH(3). To estimate transmembrane fluxes of NH(4) (+), it was necessary to measure several parameters. Intracellular pH buffering power was found to be 12 mM. Regulatory mechanisms tended to restore intracellular [H(+)] after its displacement with a time constant of 3 min. Membrane permeability to NH(3) was 13 μm s(−1). A numerical model was used to deduce the NH(4) (+) flux through the transporter that would account for the pH(i) changes induced by a 30-s application of ammonium. This flux saturated with increasing [NH(4) (+)](o); the relation was fitted with a Michaelis-Menten equation with K (m) ≈ 7 mM. The inhibition of NH(4) (+) flux by extracellular K(+) appeared to be competitive, with an apparent K (i) of ∼15 mM. A simple standard model of the transport process satisfactorily described the pH(i) changes caused by various experimental manipulations when the transporter bound NH(4) (+) with greater affinity than K(+). We conclude that this transporter is functionally selective for NH(4) (+) over K(+) and that the transporter molecule probably has a greater affinity for NH(4) (+) than for K(+).