Nucleobase-ascorbate Transporter Research Articles

Evolution of substrate specificity in the Nucleobase-Ascorbate Transporter (NAT) protein family.

L-ascorbic acid (vitamin C) is an essential metabolite in animals and plants due to its role as an enzyme co-factor and antioxidant activity. In most eukaryotic organisms, L-ascorbate is biosynthesized enzymatically, but in several major groups, including the primate suborder Haplorhini, this ability is lost due to gene truncations in the gene coding for L-gulonolactone oxidase. Specific ascorbate transporters (SVCTs) have been characterized only in mammals and shown to be essential for life. These belong to an extensively studied transporter family, called Nucleobase-Ascorbate Transporters (NAT). The prototypic member of this family, and one of the most extensively studied eukaryotic transporters, is UapA, a uric acid-xanthine/H+ symporter in the fungus Aspergillus nidulans. Here, we investigate molecular aspects of NAT substrate specificity and address the evolution of ascorbate transporters apparently from ancestral nucleobase transporters. We present a phylogenetic analysis, identifying a distinct NAT clade that includes all known L-ascorbate transporters. This clade includes homologues only from vertebrates, and has no members in non-vertebrate or microbial eukaryotes, plants or prokaryotes. Additionally, we identify within the substrate-binding site of NATs a differentially conserved motif, which we propose is critical for nucleobase versus ascorbate recognition. This conclusion is supported by the amino acid composition of this motif in distinct phylogenetic clades and mutational analysis in the UapA transporter. Together with evidence obtained herein that UapA can recognize with extremely low affinity L-ascorbate, our results support that ascorbate-specific NATs evolved by optimization of a sub-function of ancestral nucleobase transporters.

The UraA and RutG transporters of Escherichia coli are members of the ubiquitous Nucleobase‐Cation Symporter‐2 (NCS2) family. Structure and function comparisons identify protein sequence differences that determine selectivity. Replacement of Phe73 with Ala in the UraA uracil‐specific permease allows binding of thymine with an affinity that is comparable to the broad‐specificity uracil/thymine permease RutG. For details, see the article by

The UraA and RutG transporters of <i>Escherichia coli</i> are members of the ubiquitous Nucleobase‐Cation Symporter‐2 (NCS2) family. Structure and function comparisons identify protein sequence differences that determine selectivity. Replacement of Phe73 with Ala in the UraA uracil‐specific permease allows binding of thymine with an affinity that is comparable to the broad‐specificity uracil/thymine permease RutG. For details, see the article by

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 (pyrimidine utilization) 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.

The solute transport profile of two Aza-guanine transporters from the Honey bee pathogen Paenibacillus larvae.

Two nucleobase transporters encoded in the genome of the Honey bee bacterial pathogen Paenibacillus larvae belong to the azaguanine-like transporters and are referred to as PlAzg1 and PlAzg2. PlAzg1 and 2 display significant amino acid sequence similarity, and share predicted secondary structures and functional sequence motifs with two Escherichia coli nucleobase cation symporter 2 (NCS2) members: adenine permease (EcAdeP) and guanine-hypoxanthine permease EcGhxP. However, similarity does not define function. Heterologous complementation and functional analysis using nucleobase transporter-deficient Saccharomyces cerevisiae strains revealed that PlAzg1 transports adenine, hypoxanthine, xanthine and uracil, while PlAzg2 transports adenine, guanine, hypoxanthine, xanthine, cytosine and uracil. Both PlAzg1 and 2 display high affinity for adenine with Km of 2.95±0.22 and 1.92±0.22 μM, respectively. These broad nucleobase transport profiles are in stark contrast to the narrow transport range observed for EcAdeP (adenine) and EcGhxP (guanine and hypoxanthine). PlAzg1 and 2 are similar to eukaryotic Azg-like transporters in that they share a broad solute transport profile, particularly the fungal Aspergillus nidulans AzgA (that transports adenine, guanine and hypoxanthine) and plant AzgA transporters from Arabidopsis thaliana and Zea mays (that collectively move adenine, guanine, hypoxanthine, xanthine, cytosine and uracil).

Conformational transitions of uracil transporter UraA from Escherichia coli: a molecular simulation study

The Escherichia coli uracil/H + symporter UraA, known as the representative nucleobase/cation symporter 2(NCS2) protein, gets involved in several crucial physiological processes for most living organisms on Earth, such as the uptake of nucleobases and transport of vitamin C. Some experiments proposed a working model to explain proton-coupling and uracil transporting process of UraA on the basis of the crystal structure of NCS2 protein, but the details of conformational changes remained unknown. Thus, in order to make clear conformational changes caused by the protonation and deprotonation process of some conserved proton-coupled residues, the molecular dynamics simulation was used to study the conformation of UraA complexes in different protonation states. The results demonstrated that the protonation of residue Glu241 and Glu290 resulted in the whole conformational transition from the inward-open to the outward-open state. It can be concluded that Glu290 was crucial in a network of hydrogen-bonds in the middle of the core domain involving another essential residue, mainly including tyr288 in TM8, Tyr342, Ser338 in TM12, and the network of hydrogen-bonds was the key to maintain the stability of conformation. Protonation of Glu290 affects the stability of network of H-bond and changed the domains TM3 TM10 TM12. Thus, Glu290 may play a vital role as a ‘proton trigger’ that affects spatial structural of amino and residues near substrate binding side leading to an outward-open conformation transition.

Substrate Specificity of the FurE Transporter Is Determined by Cytoplasmic Terminal Domain Interactions.

FurE, a member of the Nucleobase Cation Symporter 1 transporter family in Aspergillus nidulans, is specific for allantoin, uric acid (UA), uracil, and related analogs. Herein, we show that C- or N-terminally-truncated FurE transporters (FurE-ΔC or FurE-ΔΝ) present increased protein stability, but also an inability for UA transport. To better understand the role of cytoplasmic terminal regions, we characterized genetic suppressors that restore FurE-ΔC-mediated UA transport. Suppressors map in the periphery of the substrate-binding site [Thr133 in transmembrane segment (TMS)3 and Val343 in TMS8], an outward-facing gate (Ser296 in TMS7, Ile371 in TMS9, and Tyr392 and Leu394 in TMS10), or in flexible loops (Asp26 in LN, Gly222 in L5, and Asn308 in L7). Selected suppressors were also shown to restore the wild-type specificity of FurE-ΔΝ, suggesting that both C- and/or N-terminal domains are involved in intramolecular dynamics critical for substrate selection. A direct, substrate-sensitive interaction of C- and/or N-terminal domains was supported by bimolecular fluorescence complementation assays. To our knowledge, this is the first case where not only the function, but also the specificity, of a eukaryotic transporter is regulated by its terminal cytoplasmic regions.

Dimeric structure of the uracil:proton symporter UraA provides mechanistic insights into the SLC4/23/26 transporters

The Escherichia coli uracil:proton symporter UraA is a prototypical member of the nucleobase/ascorbate transporter (NAT) or nucleobase/cation symporter 2 (NCS2) family, which corresponds to the human solute carrier family SLC23. UraA consists of 14 transmembrane segments (TMs) that are organized into two distinct domains, the core domain and the gate domain, a structural fold that is also shared by the SLC4 and SLC26 transporters. Here we present the crystal structure of UraA bound to uracil in an occluded state at 2.5 Å resolution. Structural comparison with the previously reported inward-open UraA reveals pronounced relative motions between the core domain and the gate domain as well as intra-domain rearrangement of the gate domain. The occluded UraA forms a dimer in the structure wherein the gate domains are sandwiched by two core domains. In vitro and in vivo biochemical characterizations show that UraA is at equilibrium between dimer and monomer in all tested detergent micelles, while dimer formation is necessary for the transport activity. Structural comparison between the dimeric UraA and the recently reported inward-facing dimeric UapA provides important insight into the transport mechanism of SLC23 transporters.

Putative orotate transporter of Cryptococcus neoformans, Oat1, is a member of the NCS1/PRT transporter super family and its loss causes attenuation of virulence.

It is well known that 5-fluoroorotic acid (5-FOA)-resistant mutants isolated from wild-type Cryptococcus neoformans are exclusively either ura3 or ura5 mutants. Unexpectedly, many of the 5-FOA-resistant mutants isolated in our selective regime were Ura+. We identified CNM00460 as the gene responsible for these mutations. Cnm00460 belongs to the nucleobase cation symporter 1/purine-related transporter (NCS1/PRT) super family of fungal transporters, representative members of which are uracil transporter, uridine transporter and allantoin transporter of Saccharomyces cerevisiae. Since the CNM00460 gene turned out to be involved in utilization of orotic acid, most probably as transporter, we designated this gene Orotic Acid Transporter 1 (OAT1). This is the first report of orotic acid transporter in this family. C. neoformans has four members of the NCS1/PRT family, including Cnm00460, Cnm02550, Cnj00690, and Cnn02280. Since the cnm02550∆ strain showed resistance to 5-fluorouridine, we concluded that CNM02550 encodes uridine permease and designated it URidine Permease 1 (URP1). We found that oat1 mutants were sensitive to 5-FOA in the medium containing proline as nitrogen source. A mutation in the GAT1 gene, a positive transcriptional regulator of genes under the control of nitrogen metabolite repression, in the genetic background of oat1 conferred the phenotype of weak resistance to 5-FOA even in the medium using proline as nitrogen source. Thus, we proposed the existence of another orotic acid utilization system (tentatively designated OAT2) whose expression is under the control of nitrogen metabolite repression at least in part. We found that the OAT1 gene is necessary for full pathogenic activity of C. neoformans var. neoformans.

Transporter oligomerization: form and function.

Transporters are integral membrane proteins with central roles in the efficient movement of molecules across biological membranes. Many transporters exist as oligomers in the membrane. Depending on the individual transport protein, oligomerization can have roles in membrane trafficking, function, regulation and turnover. For example, our recent studies on UapA, a nucleobase ascorbate transporter, from Aspergillus nidulans, have revealed both that dimerization of this protein is essential for correct trafficking to the membrane and the structural basis of how one UapA protomer can affect the function of the closely associated adjacent protomer. Here, we review the roles of oligomerization in many particularly well-studied transporters and transporter families.

Eugenol confers resistance to Tomato yellow leaf curl virus (TYLCV) by regulating the expression of SlPer1 in tomato plants

Tomato yellow leaf curl virus (TYLCV) is one of the most devastating plant diseases, and poses a significant agricultural concern because of the lack of an efficient control method. Eugenol is a plant-derived natural compound that has been widely used as a food additive and in medicine. In the present study, we demonstrated the potential of eugenol to enhance the resistance of tomato plants to TYLCV. The anti-TYLCV efficiency of eugenol was significantly higher than that of moroxydine hydrochloride (MH), a widely used commercial antiviral agent. Eugenol application stimulated the production of endogenous nitric oxide (NO) and salicylic acid (SA) in tomato plants. The full-length cDNA of SlPer1, which has been suggested to be a host R gene specific to TYLCV, was isolated from tomato plants. A sequence analysis suggested that SlPer1 might be a nucleobase-ascorbate transporter (NAT) belonging to the permease family. The transcript levels of SlPer1 increased markedly in response to treatment with eugenol or TYLCV inoculation. The results of this study also showed that SlPer1 expression was strongly induced by SA, MeJA (jasmonic acid methyl ester), and NO. Thus, we propose that the increased transcription of SlPer1 contributed to the high anti-TYLCV efficiency of eugenol, which might involve in the generation of endogenous SA and NO. Such findings provide the basis for the development of eugenol as an environmental-friendly agricultural antiviral agent.

Heterologous complementation studies reveal the solute transport profiles of a two-member nucleobase cation symporter 1 (NCS1) family in Physcomitrella patens

As part of an evolution-function analysis, two nucleobase cation symporter 1 (NCS1) from the moss Physcomitrella patens (PpNCS1A and PpNCS1B) are examined – the first such analysis of nucleobase transporters from early land plants. The solute specificity profiles for the moss NCS1 were determined through heterologous expression, growth and radiolabeled uptake experiments in NCS1-deficient Saccharomyces cerevisiae. Both PpNCS1A and 1B, share the same profiles as high affinity transporters of adenine and transport uracil, guanine, 8-azaguanine, 8-azaadenine, cytosine, 5-fluorocytosine, hypoxanthine, and xanthine. Despite sharing the same solute specificity profile, PpNCS1A and PpNCS1B move nucleobase compounds with different efficiencies. The broad nucleobase transport profile of PpNCS1A and 1B differs from the recently-characterized Viridiplantae NCS1 in breadth, revealing a flexibility in solute interactions with NCS1 across plant evolution.

Comprehensive genomic identification and expression analysis of the nucleobase-ascorbate transporter (NAT) gene family in apple

Nucleobase ascorbate transporters (NATs), also known as nucleobase:cation-symporter 2 (NCS2) proteins, belong to an evolutionarily widespread family of transport proteins. Because little is known about NAT genes in apple (Malus domestica), this papper screened GDR genome databases and identified 14 NATs in that species. Here, presented an overview of this gene family in apple, including structures, chromosome distribution and localization, phylogenies, and motifs. Phylogenetic and structure analyses showed that these genes could be assigned to three clusters. The 14 genes selected here displayed differential expression patterns in various tissues. Expression was very high for MdNAT12, MdNAT4, and MdNAT6 in the shoot tips, mature leaves, and young and mature fruits. MdNAT1 and MdNAT7 tended to show increased expression while the fruits were maturing. MdNAT6 proved responsive to both drought and salinity. Their transcript levels were generally up-regulated significantly during the fruit maturation process as well as in response to the imposition of drought or salt stress. Results suggest that members of this family function in tissue development, fruit maturation, and plant adaptations to adverse growing environments.

Mutational studies of the xanthine permease XanQ of Escherichia coli, a paradigm for the nucleobase‐cation symporter‐2 (NCS2) family of transporters, identified a critical role for six Gly residues in the gate domain (orange ribbons) and a hydrogen bonding network (inset) involving Gln‐75 (TM2), Asp‐304 (TM9), Thr‐321 (β10) and Gln‐90 (β3) in the core domain. For details, see the article by

Molecular MicrobiologyVolume 98, Issue 3 p. i-i Front CoverFree Access Mutational studies of the xanthine permease XanQ of Escherichia coli, a paradigm for the nucleobase-cation symporter-2 (NCS2) family of transporters, identified a critical role for six Gly residues in the gate domain (orange ribbons) and a hydrogen bonding network (inset) involving Gln-75 (TM2), Asp-304 (TM9), Thr-321 (β10) and Gln-90 (β3) in the core domain. For details, see the article by Karena et al. on pp. 502–517 of this issue. First published: 23 October 2015 https://doi.org/10.1111/mmi.13246AboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onFacebookTwitterLinked InRedditWechat No abstract is available for this article. Volume98, Issue3October 2015Pages i-i RelatedInformation

Analysis of conserved NCS2 motifs in the Escherichia coli xanthine permease XanQ.

The xanthine permease XanQ of Escherichia coli is a paradigm for transporters of the evolutionarily broad family nucleobase-cation symporter-2 (NCS2) that transport key metabolites or anti-metabolite analogs. Most functionally known members are xanthine/uric acid transporters related to XanQ and belong to a distinct phylogenetic cluster of the family. Here, we present a comprehensive mutagenesis of XanQ based on the identification and Cys-scanning analysis of conserved sequence motifs in this cluster. Results are interpreted in relation to homology modeling on the structurally known template of UraA and previous data on critical binding-site residues in transmembrane segments (TMs) 3, 8 and 10. The current analysis, of motifs distant to the binding site, revealed a set of functionally important residues in TMs 2, 5, 12 and 13, including seven irreplaceable ones, of which six are Gly residues in the gate domain (159, 369, 370, 383, 409) and in TM2 (Gly-71), and one is polar (Gln-75). Gln-75 (TM2) is probably crucial in a network of hydrogen-bonding interactions in the middle of the core domain involving another essential residue, Asp-304 (TM9). Although the two residues are irreplaceable individually, combinatorial replacement of Gln-75 with Asn and of Asp-304 with Glu rescues significant transport activity.

The solute specificity profiles of nucleobase cation symporter 1 (NCS1) from Zea mays and Setaria viridis illustrate functional flexibility.

The solute specificity profiles (transport and binding) for the nucleobase cation symporter 1 (NCS1) proteins, from the closely related C4 grasses Zea mays and Setaria viridis, differ from that of Arabidopsis thaliana and Chlamydomonas reinhardtii NCS1. Solute specificity profiles for NCS1 from Z. mays (ZmNCS1) and S. viridis (SvNCS1) were determined through heterologous complementation studies in NCS1-deficient Saccharomyces cerevisiae strains. The four Viridiplantae NCS1 proteins transport the purines adenine and guanine, but unlike the dicot and algal NCS1, grass NCS1 proteins fail to transport the pyrimidine uracil. Despite the high level of amino acid sequence similarity, ZmNCS1 and SvNCS1 display distinct solute transport and recognition profiles. SvNCS1 transports adenine, guanine, hypoxanthine, cytosine, and allantoin and competitively binds xanthine and uric acid. ZmNCS1 transports adenine, guanine, and cytosine and competitively binds, 5-fluorocytosine, hypoxanthine, xanthine, and uric acid. The differences in grass NCS1 profiles are due to a limited number of amino acid alterations. These amino acid residues do not correspond to amino acids essential for overall solute and cation binding or solute transport, as previously identified in bacterial and fungal NCS1, but rather may represent residues involved in subtle solute discrimination. The data presented here reveal that within Viridiplantae, NCS1 proteins transport a broad range of nucleobase compounds and that the solute specificity profile varies with species.

Molecular dynamics simulations of the bacterial UraA H+-uracil symporter in lipid bilayers reveal a closed state and a selective interaction with cardiolipin.

The Escherichia coli UraA H+-uracil symporter is a member of the nucleobase/ascorbate transporter (NAT) family of proteins, and is responsible for the proton-driven uptake of uracil. Multiscale molecular dynamics simulations of the UraA symporter in phospholipid bilayers consisting of: 1) 1-palmitoyl 2-oleoyl-phosphatidylcholine (POPC); 2) 1-palmitoyl 2-oleoyl-phosphatidylethanolamine (POPE); and 3) a mixture of 75% POPE, 20% 1-palmitoyl 2-oleoyl-phosphatidylglycerol (POPG); and 5% 1-palmitoyl 2-oleoyl-diphosphatidylglycerol/cardiolipin (CL) to mimic the lipid composition of the bacterial inner membrane, were performed using the MARTINI coarse-grained force field to self-assemble lipids around the crystal structure of this membrane transport protein, followed by atomistic simulations. The overall fold of the protein in lipid bilayers remained similar to the crystal structure in detergent on the timescale of our simulations. Simulations were performed in the absence of uracil, and resulted in a closed state of the transporter, due to relative movement of the gate and core domains. Anionic lipids, including POPG and especially CL, were found to associate with UraA, involving interactions between specific basic residues in loop regions and phosphate oxygens of the CL head group. In particular, three CL binding sites were identified on UraA: two in the inner leaflet and a single site in the outer leaflet. Mutation of basic residues in the binding sites resulted in the loss of CL binding in the simulations. CL may play a role as a “proton trap” that channels protons to and from this transporter within CL-enriched areas of the inner bacterial membrane.

Functional characterization of NAT/NCS2 proteins of Aspergillus brasiliensis reveals a genuine xanthine–uric acid transporter and an intrinsically misfolded polypeptide

The Nucleobase-Ascorbate Transporter (NAT) family includes members in nearly all domains of life. Functionally characterized NAT transporters from bacteria, fungi, plants and mammals are ion-coupled symporters specific for the uptake of purines, pyrimidines and related analogues. The characterized mammalian NATs are specific for the uptake of L-ascorbic acid. In this work we identify in silico a group of fungal putative transporters, named UapD-like proteins, which represent a novel NAT subfamily. To understand the function and specificity of UapD proteins, we cloned and functionally characterized the two Aspergillus brasiliensis NAT members (named AbUapC and AbUapD) by heterologous expression in Aspergillus nidulans. AbUapC represents canonical NATs (UapC or UapA), while AbUapD represents the new subfamily. AbUapC is a high-affinity, high-capacity, H+/xanthine–uric acid transporter, which can also recognize other purines with very low affinity. No apparent transport function could be detected for AbUapD. GFP-tagging showed that, unlike AbUapC which is localized in the plasma membrane, AbUapD is ER-retained and degraded in the vacuoles, a characteristic of misfolded proteins. Chimeric UapA/AbUapD molecules are also turned-over in the vacuole, suggesting that UapD includes intrinsic peptidic sequences leading to misfolding. The possible evolutionary implication of such conserved, but inactive proteins is discussed.

Ligand-Dependent Conformational Cycle of the Na+/Hydantoin Transporter Mhp1

The LeuT Fold is characterized by a five transmembrane helix, inverted repeat structure that has been observed in an increasing number of physiologically important transporter families. The recurrence of this structural scaffold among the LeuT Fold transporters has stimulated conjectures of a unified mechanism of alternating access despite significant diversity in sequence, function, and ion coupling stoichiometries. Mhp1, a Na+-coupled symporter of the Nucleobase:Cation Symporter 1 (NCS1) family, was the first LeuT Fold member to be structurally characterized by a full complement of canonical states including outward-facing, inward-facing, and occluded conformations, which implied a rocking bundle mechanism. Here we report an investigation of Mhp1 dynamics by electron paramagnetic resonance (EPR) spectroscopy. In this analysis, double electron-electron resonance (DEER) distance distributions between pairs of spin labels monitored conformational changes in response to ligand-binding. These experimental distance distributions were directly compared with the Mhp1 crystal structures by applying MD simulations of spin label rotamers at the double mutant sites and simulating distance histograms. The results of this investigation support the assertion that the crystallographically-captured conformations of Mhp1 are reflected in solution as major conformations and that Mhp1 operates primarily through a rocking bundle-like mechanism. However, unlike LeuT, Na+ binding does not induce transitions between inward- and outward-facing conformations, rather it appears that Na+ powers transport exclusively through modulation of substrate binding affinity. The model of Mhp1 transport proposed here depends critically on the description of conformational equilibria, as the Mhp1 transport cycle progresses through states using low probability transitions. A comparative analysis of the LeuT and Mhp1 mechanisms highlight significant mechanistic divergence that we speculate may in part be explained by the differential mechanisms of coupling to the Na+ gradient.

Patterns of evolutionary conservation of ascorbic acid-related genes following whole-genome triplication in Brassica rapa.

Ascorbic acid (AsA) is an important antioxidant in plants and an essential vitamin for humans. Extending the study of AsA-related genes from Arabidopsis thaliana to Brassica rapa could shed light on the evolution of AsA in plants and inform crop breeding. In this study, we conducted whole-genome annotation, molecular-evolution and gene-expression analyses of all known AsA-related genes in B. rapa. The nucleobase–ascorbate transporter (NAT) gene family and AsA l-galactose pathway genes were also compared among plant species. Four important insights gained are that: 1) 102 AsA-related gene were identified in B. rapa and they mainly diverged 12–18 Ma accompanied by the Brassica-specific genome triplication event; 2) during their evolution, these AsA-related genes were preferentially retained, consistent with the gene dosage hypothesis; 3) the putative proteins were highly conserved, but their expression patterns varied; and 4) although the number of AsA-related genes is higher in B. rapa than in A. thaliana, the AsA contents and the numbers of expressed genes in leaves of both species are similar, the genes that are not generally expressed may serve as substitutes during emergencies. In summary, this study provides genome-wide insights into evolutionary history and mechanisms of AsA-related genes following whole-genome triplication in B. rapa.

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 KM values were determined with 10.12μM, 4.85μM and 19.95μM, respectively for NAT3 and 1.74μM, 2.44μM and 29.83μM, 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.