Repression of ferritin expression modulates cell responsiveness to H-ras-induced growth.

We assessed the role of the cell labile iron pool in mediating oncogene-induced cell proliferation via repression of ferritin expression. When HEK-293 cells, engineered to inducibly express either active (+) or dominant-negative (-) forms of the H-ras oncogene, were treated with antisense nucleotides to ferritin subunits they displayed (a) decreased ferritin levels, (b) increased labile iron pool and either (c) faster growth in cells induced to express H-Ras (+) or (d) recovery from growth retardation in dominant-negative H-Ras-induced cells. Our studies support the view that the role of down-modulation of ferritin expression by some oncogene-evoked proliferation proceeds via expansion of the cellular labile iron pool.

Repression of the heavy ferritin chain increases the labile iron pool of human K562 cells.

The role of ferritin in the modulation of the labile iron pool was examined by repressing the heavy subunit of ferritin in K562 cells transfected with an antisense construct. Repression of the heavy ferritin subunit evoked an increase in the chemical levels and pro-oxidant activity of the labile iron pool and, in turn, caused a reduced expression of transferrin receptors and increased expression of the light ferritin subunit.

Repression of ferritin expression increases the labile iron pool, oxidative stress, and short-term growth of human erythroleukemia cells.

The role of ferritin expression on the labile iron pool of cells and its implications for the control of cell proliferation were assessed. Antisense oligodeoxynucleotides were used as tools for modulating the expression of heavy and light ferritin subunits of K562 cells. mRNA and protein levels of each subunit were markedly reduced by 2-day treatment with antisense probes against the respective subunit. Although the combined action of antisense probes against both subunits reduced their protein expression, antisense repression of one subunit led to an increased protein expression of the other. Antisense treatment led to a rise in the steady-state labile iron pool, a rise in the production of reactive oxygen species after pro-oxidative challenges and in protein oxidation, and the down-regulation of transferrin receptors. When compared to the repression of individual subunits, co-repression of each subunit evoked a more than additive increase in the labile iron pool and the extent of protein oxidation. These treatments had no detectable effects on the long-term growth of cells. However, repression of ferritin synthesis facilitated the renewal of growth and the proliferation of cells pre-arrested at the G(1)/S phase. Renewed cell growth was significantly less dependent on external iron supply when ferritin synthesis was repressed and its degradation inhibited by lysosomal antiproteases. This study provides experimental evidence that links the effect of ferritin repression on growth stimulation to the expansion of the labile iron pool.

Fluorescence analysis of the labile iron pool of mammalian cells.

The labile iron pool (LIP) of cells constitutes a cytosolic fraction of iron which is accessible to permeant chelators and contains the cells' metabolically and catalytically reactive iron. LIP is maintained by a balanced movement of iron from extra- and intracellular sources. We describe here an approach for tracing LIP levels in living cells based on the fluorescent probe calcein (CA). This probe binds Fe(II) rapidly, stoichiometrically, and reversibly while forming fluorescence-quenched CA-Fe complexes. Cells are loaded with CA via its acetomethoxy precursor CA-AM, attaining 1-10 microM intracellular concentrations and retaining full viability. LIP is defined here operationally as the sum of "free" and CA-bound iron of the cell. The method for assessing LIP is based on the measurement of: (a) the total intracellular concentration of CA in CA-loaded cells ([CA]1), which is estimated from fluorimetric measurements of CA in a given suspension of cells, the number of cells, and the cell volume; (b) the intracellular [CA-Fe], the concentration of [CA] bound to metals (> 95% iron), which is assessed from the relative rise in fluorescence (delta F) elicited by addition of highly permeant and high-affinity binding chelators such as salicyladehyde-isonicotinoyl-hydrazone (SIH) and the value of [CA]1; and (c) the "free" cell iron concentration [Fe(II)], which is computed from the experimentally determined values of CA-Fe(II)'s dissociation constant (Kd) in various cell lines grown in suspension (Kd = 0.22 +/- 0.01 microM). The value of cellular LIP is defined as the sum of [CA-Fe] and [Fe]. It is derived from the experimental determination of [CA]1 and [CA-Fe] and from calculation of [Fe] by application of the mass law equation using the Kd value of [CA-Fe]. The estimated values of LIP for resting erythroid and myeloid cells are in the range of 0.2-1.5 microM. The values varied commensurately with cell iron loads and iron chelator treatment. The method provides a simple, noninvasive tool for on-line monitoring of cytosolic iron under normal and abnormal conditions of cell iron supply and for assessing the dynamics of intracellular iron in living cells.