The mechanism of folate transport in rabbit reticulocytes

Bobzien, William F.; Goldman, David E.

doi:10.1172/jci106970

Cited by 33 publications

(13 citation statements)

References 17 publications

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“…Uptake of 5-CH3-H4-folate was by erythrocytes, rather than other formed elements, because uptake did not change after addition or depletion of leukocytes and platelets, and was nearly identical in erythrocytes from normal individuals and in cells from patients with profound leukopenia, reticulocytopenia, and thrombocytopenia. Although the possibility must be considered that the observed uptake is the result of the few remaining reticulocytes (4,17), extrapolation of the linear relationship between uptake and reticulocyte count to zero reticulocytes predicts an uptake by mature erythrocytes comparable to our measured values. Thus, uptake in these studies is probably not significantly influenced by the small number of reticulocytes present.…”

Section: Discussionsupporting

confidence: 76%

“…Folate transport in mature human erythrocytes has not been extensively studied. We present evidence that mature erythrocytes transport-5-CH3-H4-folate by a carrier-mediated process similar to that found for folate and folate analogues in other normal and neoplastic cells (3)(4)(5)(6)(7)(8).…”

Section: Introductionsupporting

confidence: 64%

“…Uptake of 5-CH3-H4-folate by human erythrocytes increases after ATP depletion, thereby resembling Mtx uptake by rabbit reticulocytes (4) and L-1210 leukemia cells (19,27). However, in contrast to these experimental systems, wherein metabolic poisons apparently inhibit an energy-dependent efflux mechanism without altering influx (resulting in a net increase of uptake) (4, 19), we found efflux rate constants in control and F/CN-treated human erythrocytes were nearly identical.…”

Section: Discussionmentioning

confidence: 96%

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The Mechanism of 5-Methyltetrahydrofolate Transport by Human Erythrocytes

1978

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A B S T R A C T The mechanism involved inThus peripheral erythrocytes incorporate 5-methyltetrahydrofolate by a saturable, temperature-dependent, substrate-specific process which is influenced by counter-transport. This mechanism is qualitatively similar to the carrier-mediated transport of folate compounds previously described in other cell types. Therefore, human erythrocytes should be useful for detailed characterization of this membrane carrier system.

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Section: Discussionsupporting

confidence: 76%

Section: Introductionsupporting

confidence: 64%

Section: Discussionmentioning

confidence: 96%

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The Mechanism of 5-Methyltetrahydrofolate Transport by Human Erythrocytes

1978

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“…After centrifugation (750 ϫ g for 2 min) at 4°C, cells were resuspended in ice-cold HBS, washed twice in the same buffer, and processed for determination of intracellular radiolabel with normalization to dry weight (22). Intracellular water of AA8 and Pyr R100 cells was determined using the membrane-impermeable [carboxyl- 14 C]inulin as the extracellular marker as described elsewhere (24). Efflux measurements were performed by first loading cells with [ Measurement of Plasma Membrane Potential-We have employed the method of equilibrium distribution of the lipid-soluble cation TPP ϩ across the plasma membrane to determine the membrane potential of AA8 and Pyr R100 cells (25).…”

Section: R100mentioning

confidence: 99%

Loss of Folic Acid Exporter Function with Markedly Augmented Folate Accumulation in Lipophilic Antifolate-resistant Mammalian Cells

Assaraf¹,

Goldman²

1997

Journal of Biological Chemistry

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We previously described a 1,000-fold pyrimethamineresistant Chinese hamster ovary cell line (Pyr R100 ) which retains parental dihydrofolate reductase activity and methotrexate (MTX) sensitivity. This study characterizes the basis for the 14-fold decrease in folic acid and leucovorin concentrations required for clonogenic growth of Pyr R100 cells relative to parental AA8 cells. Under conditions in which folic acid reduction was blocked by trimetrexate, Pyr R100 cells displayed relative to parental AA8 cells a: 1) 17-and 5-fold increase in the net transport of folic acid and MTX, respectively; 2) 23-and 5-fold decrease in the efflux rate constant for folic acid and MTX, respectively; and 3) 2-fold increase in folic acid influx with no significant change in MTX influx. The markedly increased net folic acid transport in Pyr R100 cells could not be explained by cellular folic acid binding, mitochondrial sequestration, polyglutamylation, nor by a decreased membrane potential.The effect of energy deprivation on folic acid and MTX transport in both cell lines was quite different. Glucose and pyruvate deprivation nearly abolished the increase in net folic acid transport in Pyr R100 cells. In contrast, energy deprivation increased net MTX transport in AA8 cells, whereas no change was seen with Pyr R100 cells. Furthermore, while folic acid influx in Pyr R100 and AA8 cells was markedly reduced with energy deprivation, MTX influx was not affected. Provision of glucose and pyruvate to energy-deprived cells resulted in a rapid onset of MTX efflux from parental AA8 cells but not from Pyr R100 cells. Taken together these results indicate that the markedly enhanced net transport of folic acid and MTX in Pyr R100 cells is largely due to the complete loss of exit pump activity. Furthermore, the energy source that sustains the augmented levels of folic acid appears linked to the influx process and is distinct from the energy source that sustains MTX gradients under these conditions. We conclude that the loss of folic acid efflux is an efficient means of augmenting cellular uptake of folate cofactors and subsequent survival on picomolar folate concentrations. This constitutes the first demonstration of the loss of folic acid exporter activity in mammalian cells as a response to lipophilic antifolate selective pressure.

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“…Its storage appears to be facilitated by folic acid binding proteins (FABP) inside the hé patocyte [5,21], In other cells such as leu kocytes and reticulocytes the presence of a 1 Supported by a grant from CNR 80.01524.96.…”

mentioning

confidence: 99%

Evidence for a Folic Acid Binding Protein in Human Cell Membrane

Corrocher¹,

Pachor²,

Bambara³

et al. 1981

Acta Haematol

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Cell membranes were prepared by sucrose discontinuous gradient from human liver and human peripheral leukocytes and erythrocytes and from circulating leukocytes from patients with chronic granulocytic leukemia (CGL) and acute myeloblastic leukemia (AML). The membrane preparations from liver and from leukemic leukocytes were shown to bind tritiated folic acid. The membranes from normal leukocytes and erythrocytes did not show this binding capacity. The membrane preparation from liver and CGL leukocytes showed two peaks of binding eluting with proteins from Sephadex G-200. However, protein extracts of these membrane preparations showed only a single peak for labelled folic acid, eluting near but just after albumin. The binding capacity of the membranes for folic acid was partially inhibited by reduced folate analogues. It is concluded that the liver plasma cell membrane and the membranes of myeloblasts in AML and circulating leukocytes in CGL contain a binding protein for folic acid which may be concerned in the transport of folates into these cells.

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The mechanism of folate transport in rabbit reticulocytes

Cited by 33 publications

References 17 publications

The Mechanism of 5-Methyltetrahydrofolate Transport by Human Erythrocytes

The Mechanism of 5-Methyltetrahydrofolate Transport by Human Erythrocytes

Loss of Folic Acid Exporter Function with Markedly Augmented Folate Accumulation in Lipophilic Antifolate-resistant Mammalian Cells

Evidence for a Folic Acid Binding Protein in Human Cell Membrane

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