Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0086543 (cataract)
 29,165 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Microelectrode studies of fresh human and rabbit lens epithelia revealed stable membrane potentials [VR (human) = -36 mV; VR (rabbit) = -45 mV] and low input resistances [Ri (human) = 10 M omega; Ri (rabbit) = 20 M omega]. Coupling studies, using two voltage microelectrodes, demonstrated that the low input resistance of the fresh epithelial tissue was due to electrotonic coupling, which was found to be extremely labile and sensitive to perfusion of the apical (fibrefacing) surface of the epithelium. The intercellular coupling could be stabilized by raising the calcium concentration of the perfusate. Studies performed on confluent monolayers of cultured human lens epithelial (HLE) cells demonstrated a membrane potential (VR = -33 mV) and input resistance (Ri = 29 M omega) similar to their fresh counterparts. The intercellular coupling of these cells was found to be much more robust. Ultrastructural studies revealed that the apical junction of cultured HLE cells was less complex than that found in fresh tissue, the latter exhibiting multiple interdigitations and folds. The cultured monolayer was dissociated into single cells by a variety of methods and the membrane properties of individual cells were studied. Single cells were found to have a lower membrane potential (-20 to -25 mV) and an input resistance in the range 110-170 M omega, depending on the method of dissociation. Channel blocking and ion replacement studies revealed significant conductance pathways for potassium, sodium and chloride and a cell-attached patch clamp investigation revealed three distinct channel types. Of the two channels with inward currents at the resting potential, one, with a conductance of 25 pS, is identified as a non-selective cation channel, and the other, with a conductance of 14 pS and reversal potential of - 14 mV, is a possible candidate for a chloride channel but has yet to be characterized. A third channel with an outward current at the resting potential is identified as a potassium channel with a conductance of 49 pS. A link between epithelial uncoupling and certain types of cataract is proposed.
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PMID:Fresh and cultured human lens epithelial cells: an electrophysiological study of cell coupling and membrane properties. 284 35

The purpose of this study was to investigate volume regulation in the lens and its involvement in lens opacification (cataract) and the role of chloride channels in these processes. Single, isolated lens fiber cells from the lens were whole cell patch clamped. When exposed to hypotonic solution, and outwardly rectifying whole-cell current was activated. The current increased from 1.0 to 32.6 pA/pF, reversed at the chloride reversal potential (Ec1 = O mV), and was blocked by the chloride channel blockers 5, nitro-2-(3-phenylpropylamino) benzoate (NPPB) and tamoxifen. Replacing all but 5mM of the external chloride with gluconate caused the reversal potential to shift +33 mV, consistent with a CL- current with a gluconate/chloride permeability ratio of 0.26. When the whole lens of the eye was exposed to hypotonic solution, there was an initial increase in anterior-posterior diameter (5-8 min), representing lens swelling of 6.5%. This was followed by a decrease in volume to a new steady state value that lasted for up to 2 h. In the longer term (> or = 2h), the lenses began to swell again. The simultaneous exposure to hypotonic solution and tamoxifen or NPPB caused swelling and prevented this volume regulation. Lenses incubated in hypotonic solution and hypotonic solution containing tamoxifen becane ipaque after a 2-h incubation period. We conclude that the lens is able to volume regulate. It possesses volume-activated Cl- channels, the inhibition of which results in inhibition of volume regulation, lens swelling and opacification. Our data suggest the long-term prophylactic use of tamoxifen may make the patient more susceptible to cataract.
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PMID:Volume regulation in the bovine lens and cataract. The involvement of chloride channels. 861 51

Until recently, the investigation of membrane ion transport mechanisms and their relationship with cataract formation has mainly focused on sodium, potassium and calcium. The specific role of chloride in solute transport within the lens has been given little attention. Rather, chloride was considered as simply the counterion to sodium. The purpose of this review is to emphasize the importance of chloride and its involvement in the membrane ion transport systems within the lens. We summarize the general physiological and chemical properties of the chloride ion in the lens, with reference to the regional ion fluxes generated by its special anatomical and electrical structure. We also present our current knowledge of the principal ion transport mechanisms associated with chloride, with particular emphasis on Cl- channels, and discuss their possible physiological significance. Maintenance of a constant cell volume is an evolutionarily ancient homeostatic process and we present some important findings associated with volume regulatory mechanisms in the whole lens and in single lens cells. Finally, we review and discuss the link between cataract formation and chloride channel dysfunction.
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PMID:The role of chloride in the lens of the eye. 912 39