Abstract
Mammals express seven transporters from the SLC1 (solute carrier 1) gene family, including five acidic amino acid transporters (EAAT1–5) and two neutral amino acid transporters (ASCT1–2). In contrast, insects of the order Diptera possess only two SLC1 genes. In this work we show that in the mosquito Culex quinquefasciatus, a carrier of West Nile virus, one of its two SLC1 EAAT-like genes encodes a transporter that displays an unusual selectivity for dicarboxylic acids over acidic amino acids. In eukaryotes, dicarboxylic acid uptake has been previously thought to be mediated exclusively by transporters outside the SLC1 family. The dicarboxylate selectivity was found to be associated with two residues in transmembrane domain 8, near the presumed substrate binding site. These residues appear to be conserved in all eukaryotic SLC1 transporters (Asp444 and Thr448, human EAAT3 numbering) with the exception of this novel C. quinquefasciatus transporter and an ortholog from the yellow fever mosquito Aedes aegypti, in which they are changed to Asn and Ala. In the prokaryotic EAAT-like SLC1 transporter DctA, a dicarboxylate transporter which was lost in the lineage leading to eukaryotes, the corresponding TMD8 residues are Ser and Ala. Functional analysis of engineered mutant mosquito and human transporters expressed in Xenopus laevis oocytes provide support for a model defining interactions of charged and polar transporter residues in TMD8 with α-amino acids and ions. Together with the phylogenetic evidence, the functional data suggest that a novel route of dicarboxylic acid uptake evolved in these mosquitos by mutations in an ancestral glutamate transporter gene.
Highlights
SLC1 transporter genes can be divided into two broad functional subclasses made up of five acidic amino acid transporters (EAAT1–5) and two neutral amino acid transporters (ASCT1–2)[1,2,3,4]
The other SLC1 genes in Culex (XP_001842239) and Aedes (XP_001656354) appear to be orthologs with predicted gene products sharing 78% identity. We noted that these latter predicted transporters contained an Asn residue at a position in TMD8 (N428) that is otherwise stringently conserved as Asp in the SLC1 gene family (D444, human EAAT3 numbering; Fig. 1A, Fig. S1)
These structural differences and the functional data described below led us to designate the second pair of orthologous transporters from A. aegypti and C. quinquefasciatus as AeaDCT and CuqDCT respectively
Summary
SLC1 (solute carrier family 1) transporter genes can be divided into two broad functional subclasses made up of five acidic (or excitatory) amino acid transporters (EAAT1–5) and two neutral amino acid transporters (ASCT1–2)[1,2,3,4]. One functionally critical structural feature is transmembrane region 8 (TMD8), which forms part of the substrate binding domain [5] This domain contains several conserved charged residues, including D440, D444, R447, and D455 (human EAAT3 numbering). These residues appear to play critical roles because individual mutations of any of them lead to severe disruptions in glutamate transport [10,11,12,13]. While these polar and charged TMD8 residues tend to be highly conserved in the SLC1 family, extensive gene duplication may have reduced selective pressure against mutation, and allowed an expanded functional repertoire of these transporters to evolve. Neutralizing mutations of the R447 residue in TMD8 change the transporter’s selectivity from acidic to neutral amino acids, and in the mammalian SLC1 neutral amino acid transporter subfamilies
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