Sequential development of intercellular junctions in bioengineered human corneas.

We have carried out a sequential study of intercellular junction formation and differentiation on human corneal substitutes consisting of an artificial corneal stroma and a corneal epithelium, developed by tissue engineering. To generate these artificial human corneas, we developed a corneal stroma substitute, using fibrin and agarose scaffolds with human keratocytes immersed within, then cultured the human corneal epithelium on top. Electron microscopy and immunofluorescence analyses revealed that artificial corneas with one or two epithelial cell layers did not show any formation of intercellular junctions. In contrast, several types of cell-cell junction, especially desmosomes, were found in multilayered mature corneal substitutes. Concomitantly, the expression of genes encoding for plakoglobin 3 (PKG3), desmoglein 3 (DSG3) and desmoplakin (DSP), zonula occludens 1 (ZO-1) and 2 (ZO-2) and connexin 37 (Cx37) was higher in multilayered artificial corneas than in immature artificial corneas, as shown by both microarray and immunofluorescence. Although expression of ZO-1, ZO-2 and Cx37 proteins was homogeneous, PKG3, DSG3 and DSP expression was restricted to the most apical cell layers in artificial corneas submerged in culture medium at all times, whereas expression was higher in intermediate cell layers, similar to normal human control corneas, when corneal substitutes are submitted to air-liquid culture techniques. These results suggest that cultured corneal substitutes submitted to air-liquid culture technique tend to form a well-developed epithelium that is very similar to the epithelium of human native corneas, suggesting that these artificial corneas could eventually be used for clinical or in vitro purposes.

Volumetric and ionic regulation during the in vitro development of a corneal endothelial barrier.

Corneal endothelium is responsible for generating an ion flux between the corneal stroma and the anterior chamber of the eye that is necessary for the cornea to remain transparent. However, the ion transport regulatory mechanisms that develop during the formation of the endothelial barrier are not known. In this study, we determined the influence of cell confluence on cell volume and intracellular ionic content on the corneal endothelial cells of rabbits. Our results demonstrate that non-confluent endothelial cells display a hypertrophic volume increase, with higher intracellular contents of potassium and chlorine than those of confluent cells. In contrast, when cells reach confluence and the endothelial barrier forms, cell volume decreases and the intracellular contents of potassium and chlorine decrease. Our genetic analysis showed a higher expression of CFTR and CA2 genes in non-confluent cells, and of the gene KCNC3 in confluent cells. These results suggest that the normal ionic current that keeps the corneal stroma dehydrated and transparent is regulated by cell-cell contacts and endothelial cell confluence, and could explain why the loss of corneal endothelial cells is often associated with corneal edema and even blindness.

Evaluation of the viability of cultured corneal endothelial cells by quantitative electron probe X-ray microanalysis.

Construction of artificial organs and tissues by tissue engineering is strongly dependent on the availability of viable cells. For that reason, the viability and the physiological status of cells kept in culture must be evaluated before the cells can be used for clinical purposes. In this work, we determined the viability of isolated rabbit corneal endothelial cells by trypan blue staining and quantitative electron probe X-ray microanalysis. Our results showed that the ionic content of potassium in cultured corneal endothelial cells tended to rise initially, but significantly decreased in cells in the fifth (and final) subculture, especially in comparison to cells in the fourth subculture (P < 0.001). However, the concentration of sulfur was higher in the fifth subculture than in the fourth subculture (P < 0.001), with a nonsignificant increase in sodium in the fifth subculture (P = 0.031). These data imply a remarkable decrease in the K/Na ratio from the fourth to the fifth subculture. Our microanalytical results, along with the morphological differences between cells in the last two subcultures, are compatible with an early phase of the preapoptotic process in the fifth subculture, and suggest that cells of the first four subcultures would be better candidates for tissue engineering.