Chronic wound state exacerbated by oxidative stress in Pax6+/- aniridia-related keratopathy.

Heterozygosity for the transcription factor PAX6 causes eye disease in humans, characterized by corneal opacity. The molecular aetiology of such disease was investigated using a Pax6+/- mouse model. We found that the barrier function of uninjured Pax6+/- corneas was compromised and that Ca2+-PKC/PLC-ERK/p38 signalling pathways were abnormally activated, mimicking a 'wounded' epithelial state. Using proteomic analysis and direct assay for oxidized proteins, Pax6+/- corneas were found to be susceptible to oxidative stress and they exhibited a wound-healing delay which could be rescued by providing reducing agents such as glutathione. Pax6 protein was oxidized and excluded from the nucleus of stressed corneal epithelial cells, with concomitant loss of corneal epithelial markers and expression of fibroblast/myofibroblast markers. We suggest a chronic wound model for Pax6-related corneal diseases, in which oxidative stress underlies a positive feedback mechanism by depleting nuclear Pax6, delaying wound healing, and activating cell signalling pathways that lead to metaplasia of the corneal epithelium. The study mechanistically links a relatively minor dosage deficiency of a transcription factor with potentially catastrophic degenerative corneal disease.

Use of co-loaded Fluo-3 and Fura Red fluorescent indicators for studying the cytosolic Ca(2+)concentrations distribution in living plant tissue.

A method for visualisation of cytosolic [Ca(2+)] distribution was applied to living plant tissue. A mixture of the fluorescent probes Fluo-3 and Fura Red was used. The emitted fluorescence was scanned simultaneously in two channels with a laser-scanning confocal microscope and rationing was performed. The homogeneity of the Fluo-3/Fura Red concentration ratio throughout the tissue after AM-ester loading was proven. In vitro calibration permitted conversion of Fluo-3/Fura Red fluorescence ratios to [Ca(2+)] values. Apparent K(D)of 286 nM, R(min)of 0.43 and R(max)of 18 were calculated. The in vivo determination of extreme ratio values was performed by permeabilizing the plasmalemma for Ca(2+)with a ionophore and manipulating the extracellular [Ca(2+)]. The resultant R(minv)of 1.33 and R(maxv)of 2.69 for vegetative apices, and R(mini)of 1.26 and R(maxi)of 3.45 for apices induced to flowering, suggested incomplete equalization of extra- and intracellular Ca(2+)levels in these experiments. In Chenopodium rubrum, the cytosolic [Ca(2+)] patterns of apical tissue obtained using Fluo-3 and Fura Red were significantly different between vegetative apices and apices after photoperiodic flower induction. This methodological approach may also be helpful for studying cytosolic [Ca(2+)] distribution in other living plant tissues.