Elevator Mechanism of Alternating Access in theEscherichia coliConcentrative Nucleoside Transporter NupC

Abstract

AbstractMembers of the concentrative nucleoside transporter (CNT) family of proteins mediate uptake of nucleosides into cells driven by a cation gradient, which then enter salvage pathways for nucleic acid synthesis. In humans, they also transport hydrophilic anticancer and antiviral nucleoside analogue drugs into cells and tissues where they exert their pharmacological effects.Escherichia coliCNT NupC (400 residues) is pyrimidine-specific and driven by a proton gradient. We have used computational, biochemical, and biophysical methods to characterize evolutionary relationships, conservation of residues, structural domains, transmembrane helices, and residues involved in nucleoside binding and/or transport activity in NupC compared with those of sodium-drivenVibrio cholerae CNT (vcCNT) and human CNTs (hCNT1−3). As in the crystal structure of vcCNT, NupC appears to contain eight transmembrane-spanning α-helices. Wild-type NupC and single-cysteine-containing mutants were tested for transport activity in energizedE. coliwhole cells and for binding of nucleosides in non-energized native inner membranes using novel cross-polarization magic-angle spinning solid-state nuclear magnetic resonance methods. Wild-type NupC had an apparent affinity of initial rate transport (Kmapp) for [14C]uridine of 22.2 ± 3.7μM and an apparent binding affinity (Kdapp) for [1′-13C]uridine of 1.8−2.6 mM. Mutant S142C retained transport and binding affinities similar to those of the wild type. Mutants G146C and E149C had no transport activity but retained varying degrees of partial binding activity with affinities decreasing in the following order: wild type > S142C > G146C > E149C. Results were explained with respect to a homology model of NupC based on the structure of vcCNT and a hypothetical elevator-type mechanism of alternating access membrane transport in NupC.