MDR-1-overexpression in HT 29 colon cancer cells grown in SCID mice.

The multidrug-resistance 1 (MDR-1) P-glycoprotein (Pgp) is a transmembrane transporter system, which actively pumps cytotoxic drugs out of the cell. MDR-1 acquired in vitro differs from MDR-1 acquired in vivo, but has important consequences on the cellular phenotype and metastatic behavior. Here we report that the human colonic cancer cell line HT29 (MDR-1 negative) is more malignant than its MDR-1 overexpressing variant (HT29 MDR-1 positive). HT29 MDR-1 negative cells produce undifferentiated signet ring carcinomas when implanted subcutaneously into SCID mice, while HT29 MDR-1 positive cells form tumors with tubular structures, but without signet ring cells. Immunohistochemical proliferation marker analysis revealed that the MDR-1 positive cells proliferate much more slowly than the MDR-1 negative cells. MDR-1 overexpression results in a less differentiated phenotype at the cellular level (absence of mucin producing cells) but in a more differentiated phenotype at the tissue level (tubule formation). In addition, lectin binding patterns including that of Helix pomatia agglutinin (HPA), an indicator of metastatic potential, differed between the two cell lines. HT29 MDR-1 positive cells had less HPA binding sites than HT29 MDR-1 negative counterparts and metastasized less frequently in SCID mice. As slow proliferation, low degree of differentiation and multidrug-resistance is a hallmark of cancer stem cells and all were present in MDR-1 positive tumors, it is attractive to speculate that they represent a stem cell rich tumor. As shown by global gene expression analyses, genes involved, e.g. in cell adhesion, glycosylation and signal transduction, were deregulated in MDR-1 positive tumors compared to MDR-negative tumors. Overexpression of E-cadherin and carcinoembryonic antigen-related cell adhesion molecules 1 (CEACAM1) may provide clues to the mechanisms responsible for the reduced metastatic potential of MDR-1 overexpressing tumors. Since drug treatment shifted the cells towards a less metastatic phenotype in this in vivo model, it seems conceivable to achieve this using drug treatment also in a clinical situation.

The labile iron pool of hepatocytes in chronic and acute iron overload and chelator-induced iron deprivation.

BACKGROUND: The cytosolic labile iron pool (LIP) is a transitory, catalytically active compartment that has been implicated in cell iron homeostasis and in metal-induced cytotoxicity. AIMS: We attempted to define LIP levels in living hepatocytes derived from chronic overloaded rats and from normal hepatocytes either acutely loaded with iron or depleted by chelation. METHODS: LIP levels were measured in living rat hepatocytes derived from normal and iron-fed rats. RESULTS: Steady-state LIP levels in untreated hepatocytes ( approximately 0.2 microM) were raised by 1.8-fold following iron loading and were reduced by 0.66-fold by short-term chelation treatment. Changes in LIP were accompanied by the corresponding changes in iron-responsive protein (IRP) activity and ferritin levels, that, in rat hepatocytes isolated from chronically loaded animals, raised by approximately 19-fold. CONCLUSIONS: Whereas ferritin levels provide an index of long-term or cumulative iron loading, LIP measurements provide an "instantaneous" parameter of iron availability within hepatocytes. The latter was associated with the cell chelatable pool in cells derived from normal and iron-loaded animals, both of which showed similar accessibility to iron chelators.