MECHANISM OF DEXTRAN TRANSPORT ACROSS RABBIT INTESTINAL TISSUE AND A HUMAN COLON CELL-LINE (CACO-2)

The in vitro permeabilities of C-14 labeled dextrans (10, 40, and 70 kD) were calculated from mass transport across Peyer's patches and non-patch tissues derived from rabbit jejunum, and a human colon cell line (Caco-2) grown as a monolayer on polycarbonate filters. Size distribution of dextrans did not change upon transport as judged from size exclusion chromatography. Permeabilities decreased in a size-dependent manner. Ranking of permeabilities for dextran 10 and 40 kD were: Caco-2 > non-patch tissue > Peyer's patches; while dextran 70 kD demonstrated no difference among the barriers. Tissue resistance, expressed as 1/(permeability . tissue thickness) was virtually the same in Peyer's patches and non-patch tissue, suggesting that tissue thickness and not interaction determines the difference in permeability. ATP depletion with ouabain, Na+-azide and 2-deoxy-D-glucose, and low temperature (4 degrees C) did not result in reduced permeabilities suggesting passive transport. The results suggest that the investigated intestinal barriers transport dextrans in a similar fashion independent of their source. However, comparison of the ratios dextran 10 kD/mannitol and PEG 900/mannitol between rabbit tissue and Caco-2 monolayers suggests Caco-2 monolayers may serve as a model to study absorption potential of potentially harmful compounds in coeliac disease, gastroenteritis, and colon carcinoma.