Separate pathways for cellular uptake of ferric and ferrous iron.

Separate pathways for transport of nontransferrin ferric and ferrous iron into tissue cultured cells were demonstrated. Neither the ferric nor ferrous pathway was shared with either zinc or copper. Manganese shared the ferrous pathway but had no effect on cellular uptake of ferric iron. We postulate that ferric iron was transported into cells via beta(3)-integrin and mobilferrin (IMP), whereas ferrous iron uptake was facilitated by divalent metal transporter-1 (DMT-1; Nramp-2). These conclusions were documented by competitive inhibition studies, utilization of a beta(3)-integrin antibody that blocked uptake of ferric but not ferrous iron, development of an anti-DMT-1 antibody that blocked ferrous iron and manganese uptake but not ferric iron, transfection of DMT-1 DNA into tissue culture cells that showed enhanced uptake of ferrous iron and manganese but neither ferric iron nor zinc, hepatic metal concentrations in mk mice showing decreased iron and manganese but not zinc or copper, and data showing that the addition of reducing agents to tissue culture media altered iron binding to proteins of the IMP and DMT-1 pathways. Although these experiments show ferric and ferrous iron can enter cells via different pathways, they do not indicate which pathway is dominant in humans.

Human neuroblastoma I-type cells are malignant neural crest stem cells.

Human neuroblastoma I-type cells isolated from cell lines in vitro are morphologically intermediate between neuroblastic (N) cells, with properties of embryonic sympathoblasts, and substrate-adherent (S) cells having properties of embryonic Schwann/glial/melanocytic cells of the neural crest. I cells have biochemical features of both N and S cells. We propose that the I-type cell represents a malignant neural crest stem cell. The strongest evidence in support of this hypothesis is that: (a) I cells can generate progeny that have neuronal properties, i.e., are committed neuroblasts, or properties of nonneuronal, embryonic neural crest-derived cells; and (b) I-type cells can generate multipotent I-type progeny, indicating their capacity for self-renewal, a feature of stem cells. We report here that I-type cells, derived from four different human neuroblastoma cell lines and experimentally induced to differentiate, give rise to cells with distinct N or S cell phenotypes, indicative of I cell multipotentiality. Experiments with a large panel of I-type subclones, isolated from clonal I-type BE(2)-C cells and exposed to retinoic acid to induce neuronal differentiation or 5-bromo-2'-deoxyuridine to obtain S-type cells, demonstrated that differentiation occurs via induction and selection and not by selection of spontaneously arising variants. The differentiation phenotype was stable. We conclude that human neuroblastoma I-type cells are multipotent embryonic precursor cells of the peripheral nervous system, capable of either neuronal or nonneuronal neural crest cell differentiation.