Functional characterization of a maize purine transporter by expression in Aspergillus nidulans

We have characterized the function of Leaf Permease1 (LPE1), a protein that is necessary for proper chloroplast development in maize, by functional expression in the filamentous fungus Aspergillus nidulans. The choice of this ascomycete was dictated by the similarity of its endogenous purine transporters to LPE1 and by particular genetic and physiological features of purine transport and metabolism in A. nidulans. When Lpe1 was expressed in a purine transport-deficient A. nidulans strain, the capacity for uric acid and xanthine transport was acquired. This capacity was directly dependent on Lpe1 copy number and expression level. Interestingly, overexpression of LPE1 from >10 gene copies resulted in transformants with pleiotropically reduced growth rates on various nitrogen sources and the absolute inability to transport purines. Kinetic analysis established that LPE1 is a high-affinity (K(m) = 30 +/- 2.5 microM), high-capacity transporter specific for the oxidized purines xanthine and uric acid. Competition studies showed that high concentrations of ascorbic acid (>30 mM) competitively inhibit LPE1-mediated purine transport. This work defines the biochemical function of LPE1, a plant representative of a large and ubiquitous transporter family. In addition, A. nidulans is introduced as a novel model system for the cloning and/or functional characterization of transporter genes.     

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.     

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.     

Comparative kinetic analysis of AzgA and Fcy21p, prototypes of the two major fungal hypoxanthine-adenine-guanine transporter families

In fungi, uptake of salvageable purines is carried out by members of two evolutionarily distinct protein families, the Purine-Related Transporters (PRT/NCS1) and the AzgA-like Transporters. We carried out a comparative kinetic analysis of two prototypes of these transporter families. The first was Fcy21p, a herein characterized protein of Candida albicans, and the second was AzgA, a transporter of Aspergillus nidulans. Our results showed that: (i) AzgA and Fcy21p are equally efficient high-affinity, high-capacity, purine transporters, (ii) Fcy21p, but not AzgA, is an efficient cytosine and 5-fluorocytosine transporter, interacting with =O2 and C4-NH2 of the pyrimidine ring, (iii) the major interactions of AzgA and Fcy21p with the purine ring are similar, but not identical, involving in all cases positions 6 and 7, and for some substrates, positions 1 and 9 as well, and (iv) in AzgA, bulky groups at position N3 have a detrimental steric effect on substrate binding, while similar substitutions at C2 or N9 are fully or partially tolerated. In contrast, in Fcy21p, C2 and N9 bulky substitutions abolish substrate binding, while similar substitutions in N3 are fully tolerated. These results suggest that all fungal purine transporters might have evolved from a single ancestral protein, and show that fungal transporters use different substrate interactions compared to the analogous protozoan or mammalian proteins. Finally, results are also discussed in respect of the possibility of using fungal purine transporters as specific gateways for the development of targeted antifungal pharmacological therapies.     

The acquisition of purines by trypanosomatids

Parasites of the family Trypanosomatidae have an absolute requirement for purines, yet lack the intracellular machinery to synthesize their own purine ring de novo. As a result, the enzymes devoted to the transport and metabolism of purines are extremely important to the parasite. Here, Claudia Cohn and Michael Gottlieb emphasize the value of understanding purine salvage for the development of trypanocidal drugs, and discuss the putative transporters devoted to purine uptake.     

Nucleoside transporters of parasitic protozoa

Protozoan parasites are incapable of synthesizing purine nucleotides de novo and so must salvage preformed purines from their hosts. This process of purine acquisition is initiated by the translocation of preformed host purines across parasite or host membranes. Here, we report upon the identification and isolation of DNAs encoding parasite nucleoside transporters and the functional characterization of these proteins in various expression systems. These potential approaches provide a powerful approach for a thorough molecular and biochemical dissection of nucleoside transport in protozoan parasites.     

A putative high affinity hexose transporter, hxtA, of Aspergillus nidulans is induced in vegetative hyphae upon starvation and in ascogenous hyphae during cleistothecium formation

Fungi employ different carbohydrate uptake systems to adapt to certain environmental conditions and to different carbon source concentrations. The hydrolysis of polymeric carbohydrates and the subsequent uptake of monomeric forms may also play a role in development. Aspergillus nidulans accumulates cell wall components during vegetative growth and degrades them during sexual development. We have identified the hxtA (high affinity hexose transporter) gene in a differential library, which was enriched for sexual-specific genes. The hxtA gene is disrupted by 6 introns and predicted to encode a 531 amino acid protein with high similarity to major facilitator superfamily members including the high affinity hexose transporter Gtt1 from Trichoderma harzianum. A. nidulans HxtA contains the 12 predicted transmembrane domains characteristic for this family. Deletion of hxtA did not impair growth of A. nidulans on a variety of carbon sources nor did it inhibit sexual development suggesting redundant sugar uptake systems. We found at least 17 putative hexose transporters in the genome of A. nidulans. Despite the high similarity of HxtA to fungal high affinity glucose transporters, the hxtA gene did not restore growth on glucose of a Saccharomyces cerevisiae mutant, in which all hexose transporters were deleted. Northern blot analysis revealed that the A. nidulans hxtA gene was repressed under high glucose conditions and expressed in vegetative hyphae upon carbon starvation and during sexual development. We found hxtA(p)::sgfp expression in developing cleistothecia specifically in ascogenous hyphae and propose that HxtA is a high affinity glucose transporter involved in sugar metabolism during sexual development.     

Molecular genetic analysis of purine nucleobase transport in Leishmania major

Leishmania major and all other parasitic protozoa are unable to synthesize purines de novo and are therefore reliant upon uptake of preformed purines from their hosts via nucleobase and nucleoside transporters. L. major expresses two nucleobase permeases, NT3 that is a high affinity transporter for purine nucleobases and NT4 that is a low affinity transporter for adenine. nt3((-/-)) null mutant promastigotes were unable to replicate in medium containing 10 microM hypoxanthine, guanine, or xanthine and replicated slowly in 10 microM adenine due to residual low affinity uptake of that purine. The NT3 transporter mediated the uptake of the anti-leishmanial drug allopurinol, and the nt3((-/-)) mutants were resistant to killing by this drug. Expression of the NT3 permease was profoundly downregulated at the protein but not the mRNA level in stationary phase compared with logarithmic phase promastigotes. The nt4((-/-)) null mutant was quantitatively impaired in survival within murine bone marrow-derived macrophages. Extensive efforts to generate an nt3((-/-))/nt4((-/-)) dual null mutant were not successful, suggesting that one of the two nucleobase permeases must be retained for robust growth of the parasite. The phenotypes of these null mutants underscore the importance of purine nucleobase transporters in the Leishmania life cycle and pharmacology.     

Insight into the genome of Aspergillus fumigatus: analysis of a 922 kb region encompassing the nitrate assimilation gene cluster

Aspergillus fumigatus is the most ubiquitous opportunistic filamentous fungal pathogen of human. As an initial step toward sequencing the entire genome of A. fumigatus, which is estimated to be approximately 30 Mb in size, we have sequenced a 922 kb region, contained within 16 overlapping bacterial artificial chromosome (BAC) clones. Fifty-four percent of the DNA is predicted to be coding with 341 putative protein coding genes. Functional classification of the proteins showed the presence of a higher proportion of enzymes and membrane transporters when compared to those of Saccharomyces cerevisiae. In addition to the nitrate assimilation gene cluster, the quinate utilisation gene cluster is also present on this 922 kb genomic sequence. We observed large scale synteny between A. fumigatus and Aspergillus nidulans by comparing this sequence to the A. nidulans genetic map of linkage group VIII.