Follicle-like structures formed by intestinal cell lines derived from the HT29-D4 adenocarcinoma cell line: morphological and functional characterization.

When cultured in high glucose containing medium, the human colon carcinoma cell line HT29-D4 and a clone derived by transfection with the MDR1 cDNA (MDR31) form multilayers of unorganized cells which are not polarized and are linked by desmosomes. Within these multilayers appear spontaneously large multicellular follicle-like-structures (FLS) where polarized cells linked by tight junctional complexes surround a lumen. Electron microscopy showed that some FLS display well developed brush borders with densely packed microvilli. Others have irregularly oriented microvilli of various lengths or are even completely devoid of apical differentiation. The lumen contains a variable amount of amorphous osmiophilic material. The apical surface of FLS forming cells express dipeptidylpeptidase IV, carcinoembryonic antigen, the mucin MUC1 and for the transfected cells the gp-170 protein. The organic anion fluorescein is transported from the cell to the lumen of FLS. Rhodamine 123, a substrate of the gp-170 ABC transporter is also concentrated in the lumen formed by MDR31 cells. Verapamil and cyclosporine A inhibited this last transport. Cyclic AMP stimulates the formation of these structures since treatment of post-confluent multilayers dramatically increased the number of FLS in HT29-D4 and MDR31 cell cultures within 24 h. The spontaneous formation of these morphologically and functionally polarized structures appeared at random and might respond to the coincidence of fluctuating parameters of the regulatory pathways (cAMP, Ca2+).

Multidrug-resistant phenotype influences the differentiation of a human colon carcinoma cell line.

The human colon carcinoma cell line HT29-D4, which constitutively expresses a very low level of the MDR1 gene product, was made multidrug resistant by transfection with a human MDR1 cDNA from the pHaMDR1/A expression vector and selection by colchicine. Resistant clones were 3- to 15-fold resistant to colchicine and were cross-resistant to doxorubicin (3- to 4-fold). MDR1 gene expression was associated with the expression of functional P-glycoprotein (gp-170); the function was reversed by verapamil and cyclosporin A. HT29-D4 cells are able to differentiate in vitro by replacement of glucose by galactose in the culture medium and also to release the carcinoembryonic antigen (CEA). Under these culture conditions, MDR1 mRNA and gp-170 were always expressed and the protein remained functional. Upon galactose treatment, resistant clones were less differentiated since they showed a heterogeneous monolayer organization accompanied by heterogeneous staining of cell-surface CEA and a high decrease (60-90%) of CEA release.

Metabolism of carbamazepine by CYP3A6: a model for in vitro drug interactions studies.

Carbamazepine (CBZ) is widely used in the treatment of epilepsy. The drug is principally metabolized by CYPs to 10, 11-epoxy carbamazepine (CBZ-E) but this metabolite more toxic than the parent drug, does possess anticonvulsant properties. In humans, CYP3A4, CYP2C8 and CYP1A2 have been shown to be implicated in CBZ biotransformation. Our purpose was to establish an experimental model to determine the interaction of CBZ with other antiepileptic drugs. We first identified the CYP isoforms that metabolized CBZ in rabbit. We used liver microsomes from rabbit treated with various compounds known to induce principally some CYPs subfamilies. Having tested all the compounds we demonstrated that only the animals treated with CYP3A inducers were able to metabolize CBZ strongly. The CBZ biotransformation was inhibited by anti CYP3A antibodies. All the CYP3A subfamily substrates specifically decrease CBZ-E formation. In our experiment we did not observe any inhibition with CYP2C substrate. These data provide evidence that in rabbit the CYP3A subfamily is primarily involved in CBZ metabolism. Using this model we investigated the interaction of CBZ with phenobarbital, phenytoin, ethosuccimide, primidone, progabide, vigabatrin and lamotrigine.

Follicle-like structure and polarized monolayer: role of the extracellular matrix on thyroid cell organization in primary culture.

The thyroid follicle, the morphofunctional unit of thyroid gland, is a spheroidal structure formed by a monolayer of polarized cells surrounding a closed cavity in which thyroglobulin accumulates. Newly isolated porcine thyroid cells reorganize into two types of structures which differ by the orientation of cell polarity: in follicle-like structures, obtained in the presence of TSH, the apical pole delineates a closed cavity and cells express most parameters characteristic of thyroid function; in inside-out follicles the apical pole is oriented towards the culture medium and cells do not express properly the thyroid function. The organization of newly formed follicles can be modified by stimulation of cell migration or by interaction of their apical poles with a new cell environment. Seeded on a hard surface (glass, plastic), cells of follicle-like structures or inside-out follicles formed in suspension migrate giving a monolayer. On the contrary, cells organized into a monolayer treated with hexamethylene bisacetamide, reorganize into follicle-like structures. Inside-out structures reorganize upon interaction of their apical poles with collagen I gel, a coherent matrix, or with a reconstituted basement membrane (RBM), a soft matrix. Overlaid with collagen I, monolayers reorganize into follicles. Embedded in collagen I or in RBM, inside-out follicles reorient their polarity giving functional follicles. On the RBM surface, cells pull on the gel and embed themselves in the soft matrix gel, finally reorienting their polarity to inside-in polarity. When comparing thyroid cells with other epithelial cell types (mammary cells, Sertoli cells), it appears that the obtention in culture of follicle-like structures, i.e. closed inside-in polarized cell organization, is the best way to express in culture both morphology and function of any specific epithelial tissue, the polarized monolayer in porous bottom culture chamber coming just behind.

Evidence for a tissue-specific induction of cutaneous CYP2E1 by dexamethasone.

We studied in mouse the effect of topical application of dexamethasone or salicylic acid, on CYP2E1 and CYP3A expression (proteins and/or mRNA) in liver and skin. Dexamethasone was also administered by intraperitoneal injection. Topical application or intraperitoneal injection of dexamethasone increased cutaneous CYP2E1 (8 and 4-fold respectively) whereas the hepatic level of this isoform showed a slight decrease and hepatic CYP3A expression was increased (3-fold). Cutaneous CYP2E1 was increased (3-fold) after topical treatment by salicylic acid. This compound had no effect on hepatic CYP3A and CYP2E1 expression. Cutaneous CYP3A (protein and mRNA) was not detectable in all groups (control or treated animals). Dexamethasone and salicylic acid increased cutaneous CYP2E1 mRNA level (2.5 and 1.4-fold respectively). In conclusion, dexamethasone and salicylic acid induced cutaneous CYP2E1 protein and mRNA level. Cutaneous CYP2E1 induction by dexamethasone is a tissue-specific process.