Regulation of a potassium-selective current in rabbit corneal epithelium by cyclic GMP,carbachol and diltiazem

Summary The effects of cyclic GMP (cGMP), carbachol and diltiazem on a potassium-selective, delayed-rectifier current in freshly dissociated rabbit corneal epithelial cells were studied using a modified perforated-patch-clamp technique. The current was stimulated by both 500 m cGMP (2.3–4.5-fold, mean = 2.9) and 250 nm carbachol, a muscarinic agonist (1.12–7.04-fold, mean = 3.8), and the stimulated current was totally blocked by diltiazem (10 m). The effects of cGMP appeared to be, at least in part, different from those of carbachol as they required the presence of external calcium. Single-channel data suggest that cGMP and carbachol activate the potassium current by increasing the open probability of the channel via a second-messenger system and that the action of diltiazem is probably through a direct blocking effect on the open channel.We are grateful to Erika Wohlfiel for secretarial help, Helen Hendrickson for cell preparation, and Joan Rae for software development. The work was supported by NIH grants EY06005 and EY03282 and an unrestricted award from Research to Prevent Blindness.     

Effects of Ag+ on ion transport by the corneal epithelium of the rabbit

Summary Exposure of thein vitro rabbit corneal epithelium to Ag⁺ by the addition of AgNO₃ (10^–7–10^–5)m) to the apical surface or by the use of imperfectly chlorided Ag/AgCl half-cells in Ussing-style membrane chambers, greatly increases short-circuit current and transepithelial potential. The early phase (the first 30 min) of the short-circuit current stimulation by Ag⁺ is linearly dependent on tear-side sodium concentration, is largely a result of a tenfold increase in net Na⁺ uptake and is incompletely inhibited by ouabain, suggesting that Ag⁺ increases cation (primarily Na⁺) conductance of the apical membrane. This mechanism for the Ag⁺ effect is supported by microelectrode experiments, wherein Ag⁺ depolarizes specifically the apical barrier potential and increases apical barrier conductance. A later phase in the effect (0.5–3 hr) is characterized by a gradual increase in³⁶Cl^– and¹⁴C-mannitol unidirectional fluxes, by a decline in epithelial resting potential and short-circuit current, by complete ouabain inhibition and by fit to saturation kinetics with respect to Na⁺ concentration in the bathing media. This pahse of the effect apparently reflects a nonselective opening of the paracellular pathway in the epithelium and is rate-limited by Na⁺ pump activity at the basolateral membrane. Both phases are associated with swelling of the corneal stroma and may be rapidly reversed using thiol agents (reduced glutathione and dithiothreitol). The results suggest that Ag⁺ may be useful in the study of cation transport by epithelia and the work provides basic physiological information that is pertinent to the prophylactic use of AgNO₃ in clinical ophthalmology.     

Effect of Ssc protein mutations on the outer membrane permeability barrier function in Salmonella typhimurium: a study using ssc mutant alleles made by site-directed mutagenesis

We have previously discovered and characterized a novel essential enterobacterial protein, the Ssc protein of Salmonella typhimurium and found that the mutation Val291----Met in this protein inhibits bacterial growth at 42 degrees C and the function of its outer membrane permeability barrier at 37 degrees C [7]. In the present paper we prepared, by site-directed mutagenesis, a series of novel plasmid-encoded Ssc mutant proteins and tested their ability to compensate the loss of wild-type Ssc. The mutant proteins Met288----Lys and Gly289----Asp completely lacked this ability, and accordingly, were very defective. Ssc mutants Met288----Leu, Met290----Lys, and Met292----Lys were partially defective. Mutants Met290----Leu and Met292----Leu were non-defective as were also four randomly made mutant proteins with mutations outside the 288-292 region. The S. typhimurium derivative which contained both the chromosomally encoded Ssc Val291----Met and the plasmid-encoded Ssc Gly289----Asp had an outer membrane defect more severe than that caused by SscMet291 only. The mutant Ssc proteins had very little, if any, effect on the outer membrane function in the presence of wild-type Ssc. Even though the function of Ssc is not yet known, our results indicate that region 288-292 is important and that SscAsp289 is thus far the most defective mutant Ssc.