Substrate selectivity of YgfU, a uric acid transporter from Escherichia coli

The ubiquitous nucleobase-ascorbate transporter (NAT/NCS2) family includes more than 2,000 members, but only 15 have been characterized experimentally. Escherichia coli has 10 members, of which the uracil permease UraA and the xanthine permeases XanQ and XanP are functionally known. Of the remaining members, YgfU is closely related in sequence and genomic locus with XanQ. We analyzed YgfU and showed that it is a proton-gradient dependent, low-affinity (K(m) 0.5 mM), and high-capacity transporter for uric acid. It also shows a low capacity for transport of xanthine at 37 °C but not at 25 °C. Based on the set of positions delineated as important from our previous Cys-scanning analysis of permease XanQ, we subjected YgfU to rationally designed site-directed mutagenesis. The results show that the conserved His-37 (TM1), Glu-270 (TM8), Asp-298 (TM9), and Gln-318 and Asn-319 (TM10) are functionally irreplaceable, and Thr-100 (TM3) is essential for the uric acid selectivity because its replacement with Ala allows efficient uptake of xanthine. The key role of these residues is corroborated by the conservation pattern and homology modeling on the recently described x-ray structure of permease UraA. In addition, site-specific replacements at TM8 (S271A, M274D, V282S) impair expression in the membrane, and V320N (TM10) inactivates the permease, whereas R327G (TM10) or S426N (TM14) reduces the affinity for uric acid (4-fold increased K(m)). Our study shows that comprehensive analysis of structure-function relationships in a newly characterized transporter can be accomplished with relatively few site-directed replacements, based on the knowledge available from Cys-scanning mutagenesis of a prototypic homolog.     

The role of transmembrane segment TM3 in the xanthine permease XanQ of Escherichia coli

The xanthine permease XanQ of Escherichia coli is used as a study prototype for function-structure analysis of the ubiquitous nucleobase-ascorbate transporter (NAT/NCS2) family. Our previous mutagenesis study of polar residues of XanQ has shown that Asn-93 at the middle of putative TM3 is a determinant of substrate affinity and specificity. To study the role of TM3 in detail we employed Cys-scanning mutagenesis. Using a functional mutant devoid of Cys residues (C-less), each amino acid residue in sequence 79-107 (YGIVGSGLLSIQSVNFSFVTVMIALGSSM) including TM3 (underlined) and flanking sequences was replaced individually with Cys. Of 29 single-Cys mutants, 20 accumulate xanthine to 40-110% of the steady state observed with C-less, six (S88C, F94C, A102C, G104C, S106C) accumulate to low levels (10-30%) and three (G83C, G85C, N93C) are inactive. Extensive mutagenesis reveals that Gly-83 and, to a lesser extent, Gly-85, are crucial for expression in the membrane. Replacements of Asn-93 disrupt affinity (Thr) or permit recognition of 8-methylxanthine which is not a wild-type ligand (Ala, Ser, Asp) and utilization of uric acid which is not a wild-type substrate (Ala, Ser). Replacements of Phe-94 impair affinity for 2-thio and 6-thioxanthine (Tyr) or 3-methylxanthine (Ile). Single-Cys mutants S84C, L86C, L87C, and S95C are highly sensitive to inactivation by N-ethylmaleimide. Our data reveal that key residues of TM3 cluster in two conserved sequence motifs, (83)GSGLL(87) and (93)NFS(95), and highlight the importance of Asn-93 and Phe-94 in substrate recognition and specificity; these findings are supported by structural modeling on the recently described x-ray structure of the uracil-transporting homolog UraA.     

Identification of New Specificity Determinants in Bacterial Purine Nucleobase Transporters based on an Ancestral Sequence Reconstruction Approach

The relation of sequence with specificity in membrane transporters is challenging to explore. Most relevant studies until now rely on comparisons of present-day homologs. In this work, we study a set of closely related transporters by employing an evolutionary, ancestral-reconstruction approach and reveal unexpected new specificity determinants. We analyze a monophyletic group represented by the xanthine-specific XanQ of Escherichia coli in the Nucleobase-Ascorbate Transporter/Nucleobase-Cation Symporter-2 (NAT/NCS2) family. We reconstructed AncXanQ, the putative common ancestor of this clade, expressed it in E. coli K-12, and found that, in contrast to XanQ, it encodes a high-affinity permease for both xanthine and guanine, which also recognizes adenine, hypoxanthine, and a range of analogs. AncXanQ conserves all binding-site residues of XanQ and differs substantially in only five intramembrane residues outside the binding site. We subjected both homologs to rationally designed mutagenesis and present evidence that these five residues are linked with the specificity change. In particular, we reveal Ser377 of XanQ (Gly in AncXanQ) as a major determinant. Replacement of this Ser with Gly enlarges the specificity of XanQ towards an AncXanQ-phenotype. The ortholog from Neisseria meningitidis retaining Gly at this position is also a xanthine/guanine transporter with extended substrate profile like AncXanQ. Molecular Dynamics shows that the S377G replacement tilts transmembrane helix 12 resulting in rearrangement of Phe376 relative to Phe94 in the XanQ binding pocket. This effect may rationalize the enlarged specificity. On the other hand, the specificity effect of S377G can be masked by G27S or other mutations through epistatic interactions.     

Cloning and functional characterization of two bacterial members of the NAT/NCS2 family in Escherichia coli

The coding potential of the genome of E. coli K-12 includes YgfO and YicE, two members of the evolutionarily conserved NAT/NCS2 transporter family that are highly homologous to each other (45% residue identity) and closely related to UapA of Aspergillus nidulans, a most extensively studied microbial member of this family. YgfO and yicE were cloned from the genome, over-expressed extrachromosomally and assayed for uptake of [(3)H]xanthine and other nucleobases, in E. coli K-12, under conditions of negligible activity of the corresponding endogenous systems. Alternative, essentially equivalent functional versions of YgfO and YicE were engineered by C-terminal tagging with an epitope from the E. coli lactose permease and a biotin-acceptor domain from Klebsiella pneumoniae. Both YgfO and YicE were shown to be present in the plasma membrane of E. coli and function as specific, high-affinity transporters for xanthine (K(m) 4.2-4.6 microM for YgfO, or 2.9-3.8 microM for YicE), in a proton motive force-dependent manner; they display no detectable transport of uracil, hypoxanthine, or uric acid at external concentrations of up to 0.1 mM. Both YgfO and YicE are inefficient in recognizing uric acid or xanthine analogues modified at position 8 of the purine ring (8-methylxanthine, 8-azaxanthine, oxypurinol, allopurinol), which distinguishes them from their fungal homologues UapA and Xut1.     

Insight on specificity of uracil permeases of the NAT/NCS2 family from analysis of the transporter encoded in the pyrimidine utilization operon of Escherichia coli

The uracil permease UraA of Escherichia coli is a structurally known prototype for the ubiquitous Nucleobase‐Ascorbate Transporter (NAT) or Nucleobase‐Cation Symporter‐2 (NCS2) family and represents a well‐defined subgroup of bacterial homologs that remain functionally unstudied. Here, we analyze four of these homologs, including RutG of E. coli which shares 35% identity with UraA and is encoded in the catabolic rut (pyr imidine ut ilization) operon. Using amplified expression in E. coli K‐12, we show that RutG is a high‐affinity permease for uracil, thymine and, at low efficiency, xanthine and recognizes also 5‐fluorouracil and oxypurinol. In contrast, UraA and the homologs from Acinetobacter calcoaceticus and Aeromonas veronii are permeases specific for uracil and 5‐fluorouracil. Molecular docking indicates that thymine is hindered from binding to UraA by a highly conserved Phe residue which is absent in RutG. Site‐directed replacement of this Phe with Ala in the three uracil‐specific homologs allows high‐affinity recognition and/or transport of thymine, emulating the RutG profile. Furthermore, all RutG orthologs from enterobacteria retain an Ala at this position, implying that they can use both uracil and thymine and, possibly, xanthine as substrates and provide the bacterial cell with a range of catabolizable nucleobases.     

Specificity profile of NAT/NCS2 purine transporters in Sinorhizobium (Ensifer) meliloti

Sinorhizobium (Ensifer) meliloti is a model example of a soil alpha-proteobacterium which induces the formation of nitrogen-fixing symbiotic nodules on the legume roots. In contrast to all other rhizobacterial species, S. meliloti contains multiple homologs of nucleobase transporter genes that belong to NAT/NCS2 family (Nucleobase-Ascorbate Transporter/Nucleobase-Cation Symporter-2). We analyzed functionally all (six) relevant homologs of S. meliloti 1,021 using Escherichia coli K-12 as a host and found that five of them are high-affinity transporters for xanthine (SmLL9), uric acid (SmLL8, SmLL9, SmX28), adenine (SmVC3, SmYE1), guanine (SmVC3), or hypoxanthine (SmVC3). Detailed analysis of substrate profiles showed that two of these transporters display enlarged specificity (SmLL9, SmVC3). SmLL9 is closely related in sequence with the xanthine-specific XanQ of E. coli. We subjected SmLL9 to rationally designed site-directed mutagenesis and found that the role of key binding-site residues of XanQ is conserved in SmLL9, whereas a single amino-acid change (S93N) converts the xanthine/uric-acid transporter SmLL9 to a xanthine-preferring variant, due to disruption of an essential hydrogen bond with the C8 oxygen of uric acid. The results highlight the presence of several different purine nucleobase transporters in S. meliloti and imply that the purine transport might be important in the nodule symbiosis involving S. meliloti.     

Cloning and functional characterization of two bacterial members of the NAT/NCS2 family in Escherichia coli

The coding potential of the genome of E. coli K-12 includes YgfO and YicE, two members of the evolutionarily conserved NAT/NCS2 transporter family that are highly homologous to each other (45% residue identity) and closely related to UapA of Aspergillus nidulans, a most extensively studied microbial member of this family. YgfO and yicE were cloned from the genome, over-expressed extrachromosomally and assayed for uptake of [³H]xanthine and other nucleobases, in E. coli K-12, under conditions of negligible activity of the corresponding endogenous systems. Alternative, essentially equivalent functional versions of YgfO and YicE were engineered by C-terminal tagging with an epitope from the E. coli lactose permease and a biotin-acceptor domain from Klebsiella pneumoniae. Both YgfO and YicE were shown to be present in the plasma membrane of E. coli and function as specific, high-affinity transporters for xanthine (K_m 4.2–4.6 µM for YgfO, or 2.9–3.8 µM for YicE), in a proton motive force-dependent manner; they display no detectable transport of uracil, hypoxanthine, or uric acid at external concentrations of up to 0.1 mM. Both YgfO and YicE are inefficient in recognizing uric acid or xanthine analogues modified at position 8 of the purine ring (8-methylxanthine, 8-azaxanthine, oxypurinol, allopurinol), which distinguishes them from their fungal homologues UapA and Xut1.     

Amino acid residues N450 and Q449 are critical for the uptake capacity and specificity of UapA,a prototype of a nucleobase-ascorbate transporter family

Specific carrier-mediated transport of purine and pyrimidine nucleobases across cell membranes is a basic biological process in both prokaryotes and eukaryotes. Recent in silico analysis has shown that the Aspergillus nidulans (UapA, UapC) and bacterial (PbuX, UraA, PyrP) nucleobase transporters, and a group of mammalian L-ascorbic acid transporters (SVCT1 and SVCT2), constitute a unique protein family which includes putative homologues from archea, bacteria, plants and metazoans. The construction and functional analysis of chimeric purine transporters (UapA-U apC) and UapA-specific missense mutations in A. nidulans has previously shown that the region including amino acid residues 378-446 in UapA is critical for purine recognition and transport. Here, we extend our studies on UapA structure-function relationships by studying missense mutations constructed within a `signature' sequence motif [(F/Y/S)X(Q/E/P)N XGXXXXT(K/R/G)] which is conserved in the putative functional region of all members of the nucleobase/ascorbate transporter family. Residues Q449 and N450 were found to be critical for purine recognition and transport. The results suggest that these residues might directly or indirectly be involved in specific interactions with the purine ring. In particular, interaction of residue 449 with C-2 groups of purines might act as a critical molecular filter involved in the selection of transported substrates. The present and previous mutagenic analyses in UapA suggest that specific polar or charged amino acid residues on either side of an amphipathic a-helical transmembrane segment are critical for purine binding and transport.     

Amino acid residues N450 and Q449 are critical for the uptake capacity and specificity of UapA, a prototype of a nucleobase-ascorbate transporter family

Specific carrier-mediated transport of purine and pyrimidine nucleobases across cell membranes is a basic biological process in both prokaryotes and eukaryotes. Recent in silico analysis has shown that the Aspergillus nidulans (UapA, UapC) and bacterial (PbuX, UraA, PyrP) nucleobase transporters, and a group of mammalian L-ascorbic acid transporters (SVCT1 and SVCT2), constitute a unique protein family which includes putative homologues from archea, bacteria, plants and metazoans. The construction and functional analysis of chimeric purine transporters (UapA-UapC) and UapA-specific missense mutations in A. nidulans has previously shown that the region including amino acid residues 378-446 in UapA is critical for purine recognition and transport. Here, we extend our studies on UapA structure-function relationships by studying missense mutations constructed within a 'signature' sequence motif [(F/Y/S)X(Q/E/P)NXGXXXXT(K/R/G)] which is conserved in the putative functional region of all members of the nucleobase/ascorbate transporter family. Residues Q449 and N450 were found to be critical for purine recognition and transport. The results suggest that these residues might directly or indirectly be involved in specific interactions with the purine ring. In particular, interaction of residue 449 with C-2 groups of purines might act as a critical molecular filter involved in the selection of transported substrates. The present and previous mutagenic analyses in UapA suggest that specific polar or charged amino acid residues on either side of an amphipathic alpha-helical transmembrane segment are critical for purine binding and transport.     

Biochemical characterization and structure–function relationship of two plant NCS2 proteins,the nucleobase transporters NAT3 and NAT12 from Arabidopsis thaliana

Nucleobase ascorbate transporters (NATs), also known as Nucleobase:Cation-Symporter 2 (NCS2) proteins, belong to an evolutionary widespread family of transport proteins with members in nearly all domains of life. We present the biochemical characterization of two NAT proteins, NAT3 and NAT12 from Arabidopsis thaliana after their heterologous expression in Escherichia coli UraA knockout mutants. Both proteins were shown to transport adenine, guanine and uracil with high affinities. The apparent K_M values were determined with 10.12 μM, 4.85 μM and 19.95 μM, respectively for NAT3 and 1.74 μM, 2.44 μM and 29.83 μM, respectively for NAT12. Competition studies with the three substrates suggest hypoxanthine as a further substrate of both transporters. Furthermore, the transport of nucleobases was markedly inhibited by low concentrations of a proton uncoupler indicating that NAT3 and NAT12 act as proton–nucleobase symporters. Transient expression studies of NAT-GFP fusion constructs revealed a localization of both proteins in the plasma membrane. Based on the structural information of the uracil permease UraA from E. coli, a three-dimensional experimentally validated homology model of NAT12 was created. The NAT12 structural model is composed of 14 TM segments and divided into two inverted repeats of TM1–7 and TM8–14. Docking studies and mutational analyses identified residues involved in NAT12 nucleobase binding including Ser-247, Phe-248, Asp-461, Thr-507 and Thr-508. This is the first study to provide insight into the structure–function of plant NAT proteins, which reveals differences from the other members of the NCS2 protein family.     

Functional Identification of the Hypoxanthine/Guanine Transporters YjcD and YgfQ and the Adenine Transporters PurP and YicO of Escherichia coli K-12

The evolutionarily broad family nucleobase-cation symporter-2 (NCS2) encompasses transporters that are conserved in binding site architecture but diverse in substrate selectivity. Putative purine transporters of this family fall into one of two homology clusters: COG2233, represented by well studied xanthine and/or uric acid permeases, and COG2252, consisting of transporters for adenine, guanine, and/or hypoxanthine that remain unknown with respect to structure-function relationships. We analyzed the COG2252 genes of Escherichia coli K-12 with homology modeling, functional overexpression, and mutagenesis and showed that they encode high affinity permeases for the uptake of adenine (PurP and YicO) or guanine and hypoxanthine (YjcD and YgfQ). The two pairs of paralogs differ clearly in their substrate and ligand preferences. Of 25 putative inhibitors tested, PurP and YicO recognize with low micromolar affinity N⁶-benzoyladenine, 2,6-diaminopurine, and purine, whereas YjcD and YgfQ recognize 1-methylguanine, 8-azaguanine, 6-thioguanine, and 6-mercaptopurine and do not recognize any of the PurP ligands. Furthermore, the permeases PurP and YjcD were subjected to site-directed mutagenesis at highly conserved sites of transmembrane segments 1, 3, 8, 9, and 10, which have been studied also in COG2233 homologs. Residues irreplaceable for uptake activity or crucial for substrate selectivity were found at positions occupied by similar role amino acids in the Escherichia coli xanthine- and uric acid-transporting homologs (XanQ and UacT, respectively) and predicted to be at or around the binding site. Our results support the contention that the distantly related transporters of COG2233 and COG2252 use topologically similar side chain determinants to dictate their function and the distinct purine selectivity profiles.     

Cysteine-scanning analysis of putative helix XII in the YgfO xanthine permease: ILE-432 and ASN-430 are important

Transmembrane helix XII of UapA, the major fungal homolog of the nucleobase-ascorbate transporter (NAT/NCS2) family, has been proposed to contain an aromatic residue acting as a purine-selectivity filter, distinct from the binding site. To analyze the role of helix XII more systematically, we employed Cys-scanning mutagenesis of the Escherichia coli xanthine-specific homolog YgfO. Using a functional mutant devoid of Cys residues (C-less), each amino acid residue in sequence 419ILPASIYVLVENPICAGGLTAILLNIILPGGY450 (the putative helix XII is underlined) was replaced individually with Cys. Of the 32 single-Cys mutants, 25 accumulate xanthine to 80-130% of the steady state observed with C-less YgfO, six (P421C, S423C, I424C, Y425C, L427C, G436C) accumulate to low levels (15-40%), and I432C is inactive. Immunoblot analysis shows that P421C and I432C display low expression in the membrane. Extensive mutagenesis reveals that replacement of Ile-432 with equally or more bulky side chains abolishes active transport without affecting expression, whereas replacement with smaller side chains allows activity but impairs affinity for the analogues 1-methyl and 6-thioxanthine. Only three of the single-Cys mutants of helix XII (V426C, N430C, and N443C) are sensitive to inactivation by N-ethylmaleimide. N430C is highly sensitive, with an IC50 of 10 microm, and is completely protected against inactivation in the presence of 2-thioxanthine, a high affinity substrate analogue. Other xanthine analogues are poorly bound by N430C, whereas replacement of Asn-430 with Thr inactivates the permease. The findings suggest that Ile-432 and Asn-430 of helix XII are crucial for purine uptake and affinity, and Asn-430 is probably at the vicinity of the binding site.     

Specific interdomain synergy in the UapA transporter determines its unique specificity for uric acid among NAT carriers

UapA, a uric acid-xanthine permease of Aspergillus nidulans, has been used as a prototype to study structure-function relationships in the ubiquitous nucleobase-ascorbate transporter (NAT) family. Using novel genetic screens, rational mutational design, chimeric NAT molecules, and extensive transport kinetic analyses, we show that dynamic synergy between three distinct domains, transmembrane segment (TMS)1, the TMS8-9 loop, and TMS12, defines the function and specificity of UapA. The TMS8-9 loop includes four residues absolutely essential for substrate binding and transport (Glu356, Asp388, Gln408, and Asn409), whereas TMS1 and TMS12 seem to control, through steric hindrance or electrostatic repulsion, the differential access of purines to the TMS8-9 domain. Thus, UapA specificity is determined directly by the specific interactions of a given substrate with the TMS8-9 loop and indirectly by interactions of this loop with TMS1 and TMS12. We finally show that intramolecular synergy among UapA domains is highly specific and propose that it forms the basis for the evolution of the unique specificity of UapA for uric acid, a property not present in other NAT members.     

Identification of the Substrate Recognition and Transport Pathway in a Eukaryotic Member of the Nucleobase-Ascorbate Transporter (NAT) Family

Using the crystal structure of the uracil transporter UraA of Escherichia coli, we constructed a 3D model of the Aspergillus nidulans uric acid-xanthine/H(+) symporter UapA, which is a prototype member of the Nucleobase-Ascorbate Transporter (NAT) family. The model consists of 14 transmembrane segments (TMSs) divided into a core and a gate domain, the later being distinctly different from that of UraA. By implementing Molecular Mechanics (MM) simulations and quantitative structure-activity relationship (SAR) approaches, we propose a model for the xanthine-UapA complex where the substrate binding site is formed by the polar side chains of residues E356 (TMS8) and Q408 (TMS10) and the backbones of A407 (TMS10) and F155 (TMS3). In addition, our model shows several polar interactions between TMS1-TMS10, TMS1-TMS3, TMS8-TMS10, which seem critical for UapA transport activity. Using extensive docking calculations we identify a cytoplasm-facing substrate trajectory (D360, A363, G411, T416, R417, V463 and A469) connecting the proposed substrate binding site with the cytoplasm, as well as, a possible outward-facing gate leading towards the substrate major binding site. Most importantly, re-evaluation of the plethora of available and analysis of a number of herein constructed UapA mutations strongly supports the UapA structural model. Furthermore, modeling and docking approaches with mammalian NAT homologues provided a molecular rationale on how specificity in this family of carriers might be determined, and further support the importance of selectivity gates acting independently from the major central substrate binding site.     

Cysteine-scanning analysis of the nucleobase-ascorbate transporter signature motif in YgfO permease of Escherichia coli: Gln-324 and Asn-325 are essential, and Ile-329-Val-339 form an alpha-helix

The nucleobase-ascorbate transporter (NAT) signature motif is a conserved sequence motif of the ubiquitous NAT/NCS2 family implicated in defining the function and selectivity of purine translocation pathway in the major fungal homolog UapA. To analyze the role of NAT motif more systematically, we employed Cys-scanning mutagenesis of the Escherichia coli xanthine-specific homolog YgfO. Using a functional mutant devoid of Cys residues (C-less), each amino acid residue in sequence (315)GSIPITTFAQNNGVIQMTGVASRYVG(340) (motif underlined) was replaced individually with Cys. Of the 26 single-Cys mutants, 16 accumulate xanthine to > or =50% of the steady state observed with C-less YgfO, 4 accumulate to low levels (10-25% of C-less), F322C, N325C, and N326C accumulate marginally (5-8% of C-less), and P318C, Q324C, and G340C are inactive. When transferred to wild type, F322C(wt) and N326C(wt) are highly active, but P318G(wt), Q324C(wt), N325C(wt), and G340C(wt) are inactive, and G340A(wt) displays low activity. Immunoblot analysis shows that replacements at Pro-318 or Gly-340 are associated with low or negligible expression in the membrane. More extensive mutagenesis reveals that Gln-324 is critical for high affinity uptake and ligand recognition, and Asn-325 is irreplaceable for active xanthine transport, whereas Thr-332 and Gly-333 are important determinants of ligand specificity. All single-Cys mutants react with N-ethylmaleimide, but regarding sensitivity to inactivation, they fall to three regions; positions 315-322 are insensitive to N-ethylmaleimide, with IC(50) values > or =0.4 mM, positions 323-329 are highly sensitive, with IC(50) values of 15-80 microM, and sensitivity of positions 330-340 follows a periodicity, with mutants sensitive to inactivation clustering on one face of an alpha-helix.     

Purine Substrate Recognition by the Nucleobase-Ascorbate Transporter Signature Motif in the YgfO Xanthine Permease: ASN-325 BINDS AND ALA-323 SENSES SUBSTRATE*

The nucleobase-ascorbate transporter (NAT) signature motif is a conserved 11-amino acid sequence of the ubiquitous NAT/NCS2 family, essential for function and selectivity of both a bacterial (YgfO) and a fungal (UapA) purine-transporting homolog. We examined the role of NAT motif in more detail, using Cys-scanning and site-directed alkylation analysis of the YgfO xanthine permease of Escherichia coli. Analysis of single-Cys mutants in the sequence 315–339 for sensitivity to inactivation by 2-sulfonatoethyl methanethiosulfonate (MTSES⁻) and N-ethylmaleimide (NEM) showed a similar pattern: highly sensitive mutants clustering at the motif sequence (323–329) and a short α-helical face downstream (332, 333, 336). In the presence of substrate, N325C is protected from alkylation with either MTSES⁻ or NEM, whereas sensitivity of A323C to inactivation by NEM is enhanced, shifting IC₅₀ from 34 to 14 μm. Alkylation or sensitivity of the other mutants is unaffected by substrate; the lack of an effect on Q324C is attributed to gross inability of this mutant for high affinity binding. Site-directed mutants G333R and S336N at the α-helical face downstream the motif display specific changes in ligand recognition relative to wild type; G333R allows binding of 7-methyl and 8-methylxanthine, whereas S336N disrupts affinity for 6-thioxanthine. Finally, all assayable motif-mutants are highly accessible to MTSES⁻ from the periplasmic side. The data suggest that the NAT motif region lines the solvent- and substrate-accessible inner cavity, Asn-325 is at the binding site, Ala-323 responds to binding with a specific conformational shift, and Gly-333 and Ser-336 form part of the purine permeation pathway.     

Modelling,substrate docking and mutational analysis identify residues essential for function and specificity of the major fungal purine transporter AzgA

The AzgA purine/H⁺ symporter of Aspergillus nidulans is the founding member of a functionally and phylogenetically distinct transporter family present in fungi, bacteria and plants. Here a valid AzgA topological model is built based on the crystal structure of the Escherichia coli uracil transporter UraA, a member of the nucleobase‐ascorbate transporter (NAT/NCS2) family. The model consists of 14 transmembrane, mostly α‐helical, segments (TMSs) and cytoplasmic N‐ and C‐tails. A distinct compact core of 8 TMSs, made of two intertwined inverted repeats (TMSs 1–4 and 8–11), is topologically distinct from a flexible domain (TMSs 5–7 and 12–14). A putative substrate binding cavity is visible between the core and the gate domains. Substrate docking, molecular dynamics and mutational analysis identified several residues critical for purine binding and/or transport in TMS3, TMS8 and TMS10. Among these, Asn131 (TMS3), Asp339 (TMS8) and Glu394 (TMS10) are proposed to directly interact with substrates, while Asp342 (TMS8) might be involved in subsequent substrate translocation, through H⁺ binding and symport. Thus, AzgA and other NAT transporters use topologically similar TMSs and amino acid residues for substrate binding and transport, which in turn implies that AzgA‐like proteins constitute a distant subgroup of the ubiquitous NAT family.     

Substitution F569S converts UapA, a specific uric acid-xanthine transporter, into a broad specificity transporter for purine-related solutes.

UapA, a highly specific uric acid-xanthine transporter in Aspergillus nidulans, is a member of a large family of nucleobase-ascorbate transporters conserved in all domains of life. We have investigated structure-function relationships in UapA, by studying chimeric transporters and missense mutations, and showed that specific polar or charged amino acid residues (E412, E414, Q449, N450, T457) on either side of an amphipathic alpha-helical transmembrane segment (TMS10) are critical for purine binding and transport. Here, the mutant Q449E, having no uric acid-xanthine transport activity at 25 degrees C, was used to isolate second-site revertants that restore function. Seven of them were found to have acquired the capacity to transport novel substrates (hypoxanthine and adenine) in addition to uric acid and xanthine. All seven revertants were found to carry the mutation F569S within the last transmembrane segment (TMS14) of UapA. Further kinetic analysis of a selected suppressor showed that UapA-Q449E/F569S transports with high affinity (K(M) values of 4-10 microM) xanthine, hypoxanthine and uracil. Uptake competition experiments suggested that UapA-Q449E/F569S also binds guanine, 6-thioguanine, adenosine or ascorbic acid. A strain carrying mutation F569S by itself conserves high-capacity, high-affinity (K(M) values of 1.5-15 microM), transport activity for purine-uracil transport. Compared to UapA-Q449E/F569S, UapA-F569S has a distinct capacity to bind several nucleobase-related compounds and different kinetic parameters of transport. These results show that molecular determinants external to the central functional domain (L9-TMS10-L10) are critical for the uptake specificity and transport kinetics of UapA.     

Comparative substrate recognition by bacterial and fungal purine transporters of the NAT/NCS2 family

We compared the interactions of purines and purine analogues with representative fungal and bacterial members of the widespread Nucleobase-Ascorbate Transporter (NAT) family. These are: UapA, a well-studied xanthine-uric acid transporter of A. nidulans, Xut1, a novel transporter from C. albicans, described for the first time in this work, and YgfO, a recently characterized xanthine transporter from E. coli. Using transport inhibition experiments with 64 different purines and purine-related analogues, we describe a kinetic approach to build models on how NAT proteins interact with their substrates. UapA, Xut1 and YgfO appear to bind several substrates via interactions with both the pyrimidine and imidazol rings. Fungal homologues interact with the pyrimidine ring of xanthine and xanthine analogues via H-bonds, principally with N1-H and =O6, and to a lower extent with =O2. The E. coli homologue interacts principally with N3-H and =O2, and less strongly with N1-H and =O6. The basic interaction with the imidazol ring appears to be via a H-bond with N9. Interestingly, while all three homologues recognize xanthines with similar high affinities, interaction with uric acid or/and oxypurinol is transporter-specific. UapA recognizes uric acid with high affinity, principally via three H-bonds with =O2, =O6 and =O8. Xut1 has a 13-fold reduced affinity for uric acid, based on a different set of interactions involving =O8, and probably H atoms from positions N1, N3, N7 or N9. YgfO does not recognize uric acid at all. Both Xut1 and UapA recognize oxypurinol, but use different interactions reflected in a nearly 26-fold difference in their affinities for this drug, while YgfO interacts with this analogue very inefficiently.     

Mutational analysis and modeling reveal functionally critical residues in transmembrane segments 1 and 3 of the UapA transporter

Earlier, we identified mutations in the first transmembrane segment (TMS1) of UapA, a uric acid-xanthine transporter in Aspergillus nidulans, that affect its turnover and subcellular localization. Here, we use one of these mutations (H86D) and a novel mutation (I74D) as well as genetic suppressors of them, to show that TMS1 is a key domain for proper folding, trafficking and turnover. Kinetic analysis of mutants further revealed that partial misfolding and deficient trafficking of UapA does not affect its affinity for xanthine transport, but reduces that of uric acid and confers a degree of promiscuity towards the binding of other purines. This result strengthens the idea that subtle interactions among domains not directly involved in substrate binding refine the selectivity of UapA. Characterization of second-site suppressors of H86D revealed a genetic interaction of TMS1 with TMS3, the latter segment shown for the first time to be important for UapA function. Systematic mutational analysis of polar and conserved residues in TMS3 showed that Ser154 is crucial for UapA transport activity. Our results are in agreement with a topological model of UapA built on the recently published structure of UraA, a bacterial homolog of UapA.