Impact of Overexpression of the Reduced Folate Carrier (RFC1), an Anion Exchanger, on Concentrative Transport in Murine L1210 Leukemia Cells

Rongbao Zhao,Richard Seither,Kevin E Brigle,Iraida G Sharina,Pi J Wang,I David Goldman

doi:10.1074/jbc.272.34.21207

Rongbao Zhao, Richard Seither + Show 4 more

Open Access

https://doi.org/10.1074/jbc.272.34.21207

Copy DOI

Abstract

Transport of reduced folates in murine leukemia cells is mediated by the bidirectional reduced folate carrier (RFC1) and independent unidirectional exit pumps. RFC1 has been proposed to be intrinsically equilibrating, generating transmembrane gradients by exchange with inorganic and organic anions. This paper defines the role of high level carrier expression, through transfection with RFC1 cDNA, on concentrative transport of the folate analog, methotrexate (MTX) in murine L1210 leukemia cells. RFC1 was expressed in the MTXrA line, which lacks a functional endogenous carrier to obtain the MTXrA-R16 clonal derivative. Influx was increased approximately 9-fold in MTXrA-R16 cells without a change in Km. The efflux rate constant was increased by a factor of 5.1 relative to L1210 cells, and this resulted in only a 2.1-fold increase in the steady-state level of free intracellular MTX, [MTX]i, when [MTX]e was 1 microM. The concentrative advantage for RFC1 (the ratio of [MTX]i in MTXrA-R16 to L1210 cells) increased from 1.8 at 0.1 microM MTX to 3.8 at an [MTX]e level of 30 microM. Augmented transport in MTXrA-R16 cells was accompanied by a 2-fold increase in accumulation of MTX polyglutamate derivatives and a approximately 50% decrease in the EC50 for 5-formyltetrahydrofolate and folic acid and the MTX IC50 relative to L1210 cells. These alterations paralleled changes in [MTX]i and not the much larger change in influx at low [MTX]e levels, consistent with the critical role that free intracellular folates and drug play in meeting cellular needs for folates and as a determinant of antifolate activity, respectively. The data indicate that RFC1 produces a large and near symmetrical increase in the bidirectional fluxes of MTX resulting in only a small increase in the transmembrane chemical gradient at low extracellular folate levels. Hence, increased expression of RFC1, alone, may not be an efficient adaptive response to folate deprivation, and other factors may come into play to account for the marked increases in concentrative folate transport which occur when cells are subjected to low folate-selective pressure.

Highlights

The membrane transport of folates and antifolates in L1210 murine leukemia cells is mediated by several distinct processes
This paper focuses, for the first time, on the role that RFC1 plays in concentrative transport within the context of a highly quantitative analysis of the transport properties of an L1210 murine leukemia cell line, MTXrA-R16, which expresses a high level of RFC1
Impact of RFC1 Transfection on the Net Transport and Bidirectional Fluxes of MTX in MTXrA-R16 Cells—Fig. 1 is an analysis of the level of endogenous and transfected RFC1 mRNA in the cell lines probed with the full-length murine RFC1 cDNA (21)

Summary

Introduction

The membrane transport of folates and antifolates in L1210 murine leukemia cells is mediated by several distinct processes. This paper focuses, for the first time, on the role that RFC1 plays in concentrative transport within the context of a highly quantitative analysis of the transport properties of an L1210 murine leukemia cell line, MTXrA-R16, which expresses a high level of RFC1. This line was derived from MTXrA in which endogenous carrier is present at the cell surface but is not functional because of a point mutation in RFC1 (21, 23). The properties of MTX transport in RFC1-transfected cells are analyzed within the context of what has been reported in cell lines in which carrier-mediated transport is enhanced under conditions of low folate-selective pressure (24 –26)

Methods

Results

Conclusion