Connections Between Connexins, Calcium, and Cataracts in the Lens

doi:10.1085/jgp.200409121

Published online Sep 27 2004. doi:10.1085/jgp.200409121
The Rockefeller University Press, 0022-1295 $8.00
JGP, Volume 124, Number 4, 289-300

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Connections Between Connexins, Calcium, and Cataracts in the Lens

Junyuan Gao¹, Xiurong Sun¹, Francisco J. Martinez-Wittinghan¹, Xiaohua Gong², Thomas W. White¹, and Richard T. Mathias¹

¹ Department of Physiology and Biophysics, State University of New York at Stony Brook, Stony Brook, NY 11794
² School of Optometry, University of California at Berkeley, Berkeley, CA 94720

Address correspondence to Richard T. Mathias, Department of Physiology and Biophysics, SUNY Health Sciences Center, BST-6, Room 175, Stony Brook, NY 11794-8661. Fax: (631) 444-3432; email: richard.mathias{at}stonybrook.edu

There is a good deal of evidence that the lens generates aninternal micro circulatory system, which brings metabolites,like glucose, and antioxidants, like ascorbate, into the lensalong the extracellular spaces between cells. Calcium also oughtto be carried into the lens by this system. If so, the onlypath for Ca²⁺ to get out of the lens is to move down its electrochemicalgradient into fiber cells, and then move by electrodiffusionfrom cell to cell through gap junctions to surface cells, whereCa-ATPase activity and Na/Ca exchange can transport it backinto the aqueous or vitreous humors. The purpose of the presentstudy was to test this calcium circulation hypothesis by studyingcalcium homeostasis in connexin (Cx46) knockout and (Cx46 forCx50) knockin mouse lenses, which have different degrees ofgap junction coupling. To measure intracellular calcium, FURA2was injected into fiber cells, and the gradient in calcium concentrationfrom center to surface was mapped in each type of lens. In wild-typelenses the coupling conductance of the mature fibers was $~$ 0.5S/cm² of cell to cell contact, and the best fit to the calciumconcentration data varied from 700 nM in the center to 300 nMat the surface. In the knockin lenses, the coupling conductancewas $~$ 1.0 S/cm² and calcium varied from $~$ 500 nM at the center to300 nM at the surface. Thus, when the coupling conductance doubled,the concentration gradient halved, as predicted by the model.In knockout lenses, the coupling conductance was zero, hencethe efflux path was knocked out and calcium accumulated to $~$ 2µM in central fibers. Knockout lenses also had a densecentral cataract that extended from the center to about halfthe radius. Others have previously shown that this cataractinvolves activation of a calcium-dependent protease, Lp82. Wecan now expand on this finding to provide a hypothesis on eachstep that leads to cataract formation: knockout of Cx46 causesloss of coupling of mature fiber cells; the efflux path forcalcium is therefore blocked; calcium accumulates in the centralcells; at concentrations above $~$ 1 µM (from the center toabout half way out of a 3-wk-old lens) Lp82 is activated; Lp82cleaves cytoplasmic proteins (crystallins) in central cells;and the cleaved proteins aggregate and scatter light.

Key Words: connexin knockout • connexin knockin • intracellular calcium • gap junctions • coupling conductance

Abbreviations used in this paper: DF, differentiating fibers;KI, knockin; KO, knockout; MF, mature fibers; WT, wild type.

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