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.     

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.     

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.     

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.     

The first transmembrane segment (TMS1) of UapA contains determinants necessary for expression in the plasma membrane and purine transport

UapA, a member of the NAT/NCS2 family, is a high affinity, high capacity, uric acid-xanthine/H+ symporter in Aspergillus nidulans. Determinants critical for substrate binding and transport lie in a highly conserved signature motif downstream from TMS8 and within TMS12. Here we examine the role of TMS1 in UapA biogenesis and function. First, using a mutational analysis, we studied the role of a short motif (Q85H86), conserved in all NATs. Q85 mutants were cryosensitive, decreasing (Q85L, Q85N, Q85E) or abolishing (Q85T) the capacity for purine transport, without affecting physiological substrate binding or expression in the plasma membrane. All H86 mutants showed nearly normal substrate binding affinities but most (H86A, H86K, H86D) were cryosensitive, a phenotype associated with partial ER retention and/or targeting of UapA in small vacuoles. Only mutant H86N showed nearly wild-type function, suggesting that His or Asn residues might act as H donors in interactions affecting UapA topology. Thus, residues Q85 and H86 seem to affect the flexibility of UapA, in a way that affects either transport catalysis per se (Q85), or expression in the plasma membrane (H86). We then examined the role of a transmembrane Leu Repeat (LR) motif present in TMS1 of UapA, but not in other NATs. Mutations replacing Leu with Ala residues altered differentially the binding affinities of xanthine and uric acid, in a temperature-sensitive manner. This result strongly suggested that the presence of L77, L84 and L91 affects the flexibility of UapA substrate binding site, in a way that is necessary for high affinity uric acid transport. A possible role of the LR motif in intramolecular interactions or in UapA dimerization is discussed.     

The first transmembrane segment (TMS1) of UapA contains determinants necessary for expression in the plasma membrane and purine transport

UapA, a member of the NAT/NCS2 family, is a high affinity, high capacity, uric acid-xanthine/H⁺ symporter in Aspergillus nidulans. Determinants critical for substrate binding and transport lie in a highly conserved signature motif downstream from TMS8 and within TMS12. Here we examine the role of TMS1 in UapA biogenesis and function. First, using a mutational analysis, we studied the role of a short motif (Q⁸⁵H⁸⁶), conserved in all NATs. Q85 mutants were cryosensitive, decreasing (Q85L, Q85N, Q85E) or abolishing (Q85T) the capacity for purine transport, without affecting physiological substrate binding or expression in the plasma membrane. All H86 mutants showed nearly normal substrate binding affinities but most (H86A, H86K, H86D) were cryosensitive, a phenotype associated with partial ER retention and/or targeting of UapA in small vacuoles. Only mutant H86N showed nearly wild-type function, suggesting that His or Asn residues might act as H donors in interactions affecting UapA topology. Thus, residues Q85 and H86 seem to affect the flexibility of UapA, in a way that affects either transport catalysis per se (Q⁸⁵), or expression in the plasma membrane (H⁸⁶). We then examined the role of a transmembrane Leu Repeat (LR) motif present in TMS1 of UapA, but not in other NATs. Mutations replacing Leu with Ala residues altered differentially the binding affinities of xanthine and uric acid, in a temperature-sensitive manner. This result strongly suggested that the presence of L⁷⁷, L⁸⁴ and L⁹¹ affects the flexibility of UapA substrate binding site, in a way that is necessary for high affinity uric acid transport. A possible role of the LR motif in intramolecular interactions or in UapA dimerization is discussed.     

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.     

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.     

Chimeric purine transporters of Aspergillus nidulans define a domain critical for function and specificity conserved in bacterial, plant and metazoan homologues.

In Aspergillus nidulans, purine uptake is mediated by three transporter proteins: UapA, UapC and AzgA. UapA and UapC have partially overlapping functions, are 62% identical and have nearly identical predicted topologies. Their structural similarity is associated with overlapping substrate specificities; UapA is a high-affinity, high-capacity specific xanthine/uric acid transporter. UapC is a low/moderate-capacity general purine transporter. We constructed and characterized UapA/UapC, UapC/UapA and UapA/UapC/UapA chimeric proteins and UapA point mutations. The region including residues 378-446 in UapA (336-404 in UapC) has been shown to be critical for purine recognition and transport. Within this region, we identified: (i) one amino acid residue (A404) important for transporter function but probably not for specificity and two residues (E412 and R414) important for UapA function and specificity; and (ii) a sequence, (F/Y/S)X(Q/E/P) NXGXXXXT(K/R/G), which is highly conserved in all homologues of nucleobase transporters from bacteria to man. The UapC/UapA series of chimeras behaves in a linear pattern and leads to an univocal assignment of functional domains while the analysis of the reciprocal and 'sandwich' chimeras revealed unexpected inter-domain interactions. cDNAs coding for transporters including the specificity region defined by these studies have been identified for the first time in the human and Caenorhabditis elegans databases.     

Transport-dependent endocytosis and turnover of a uric acid-xanthine permease

In this work we unmask a novel downregulation mechanism of the uric acid/xanthine transporter UapA, the prototype member of the ubiquitous Nucleobase-Ascorbate Transporter family, directly related to its function. In the presence of substrates, UapA is endocytosed, sorted into the multivesicular body pathway and degraded in vacuoles. Substrate-induced endocytosis, unlike ammonium-induced turnover, is absolutely dependent on UapA activity and several lines of evidence showed that the signal for increased endocytosis is the actual translocation of substrates through the UapA protein. The use of several UapA functional mutants with altered kinetics and specificity has further shown that transport-dependent UapA endocytosis occurs through a mechanism, which senses subtle conformational changes associated with the transport cycle. We also show that distinct mechanisms of UapA endocytosis necessitate ubiquitination of a single Lys residue (K572) by HulA^Rsp5. Finally, we demonstrate that in the presence of substrates, non-functional UapA versions can be endocytosed in trans if expressed in the simultaneous presence of active UapA versions, even if the latter cannot be endocytosed themselves.     

Allopurinol and xanthine use different translocation mechanisms and trajectories in the fungal UapA transporter

In Aspergillus nidulans UapA is a H⁺-driven transporter specific for xanthine, uric acid and several analogues. Here, genetic and physiological evidence is provided showing that allopurinol is a high-affinity, low-capacity, substrate for UapA. Surprisingly however, transport kinetic measurements showed that, uniquely among all recognized UapA substrates, allopurinol is transported by apparent facilitated diffusion and exhibits a paradoxical effect on the transport of physiological substrates. Specifically, excess xanthine or other UapA substrates inhibit allopurinol uptake, as expected, but the presence of excess allopurinol results in a concentration-dependent enhancement of xanthine binding and transport. Flexible docking approaches failed to detect allopurinol binding in the major UapA substrate binding site, which was recently identified by mutational analysis and substrate docking using all other UapA substrates. These results and genetic evidence suggest that the allopurinol translocation pathway is distinct from, but probably overlapping with, that of physiological UapA substrates. Furthermore, although the stimulating effect of allopurinol on xanthine transport could, in principle, be rationalized by a cryptic allopurinol-specific allosteric site, evidence was obtained supporting that accelerated influx of xanthine is triggered through exchange with cytoplasmically accumulated allopurinol. Our results are in line with recently accumulating evidence revealing atypical and complex mechanisms underlying transport systems.     

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.     

Role of Intramembrane Polar Residues in the YgfO Xanthine Permease: HIS-31 AND ASN-93 ARE CRUCIAL FOR AFFINITY AND SPECIFICITY, AND ASP-304 AND GLU-272 ARE IRREPLACEABLE

Using the YgfO xanthine permease of Escherichia coli as a bacterial model for the study of the evolutionarily ubiquitous nucleobase-ascorbate transporter (NAT/NCS2) family, we performed a systematic Cys-scanning and site-directed mutagenesis of 14 putatively charged (Asp, Glu, His, Lys, or Arg) and 7 highly polar (Gln or Asn) residues that are predicted to lie in transmembrane helices (TMs). Of 21 single-Cys mutants engineered in the background of a functional YgfO devoid of Cys residues (C-less), only four are inactive or have marginal activity (H31C, N93C, E272C, D304C). The 4 residues are conserved throughout the family in TM1 (His-31), TM3 (Asn-93/Ser/Thr), TM8 (Glu-272), and putative TM9a (Asp-304/Asn/Glu). Extensive site-directed mutagenesis in wild-type background showed that H31N and H31Q have high activity and affinity for xanthine but H31Q recognizes novel purine bases and analogues, whereas H31C and H31L have impaired affinity for xanthine and analogues, and H31K or H31R impairs expression in the membrane. N93S and N93A are highly active but more promiscuous for recognition of analogues at the imidazole moiety of substrate, N93D has low activity, N93T has low affinity for xanthine or analogues, and N93Q or N93C is inactive. All mutants replacing Glu-272 or Asp-304, including E272D, E272Q, D304E, and D304N, are inactive, although expressed to high levels in the membrane. Finally, one of the 17 assayable single-Cys mutants, Q258C, was sensitive to inactivation by N-ethylmaleimide. The findings suggest that polar residues important for the function of YgfO cluster in TMs 1, 3, 8 and 9a.The nucleobase-ascorbate transporter (NAT)² or nucleobase-cation symporter-2 (NCS2) family is an evolutionarily ubiquitous family of purine, pyrimidine, and l-ascorbate transporters, with members specific for cellular uptake of uracil, xanthine, or uric acid (microbial and plant genomes) or vitamin C (mammalian genomes) (1, 2). Despite their importance for the recognition and uptake of several frontline purine-related drugs, NAT/NCS2 members have not been studied systematically at the molecular level, and high resolution structures or mechanistic models are missing. More than 1000 sequence entries are known, but few have been functionally characterized to date. The best studied eukaryotic member is UapA, a high affinity uric acid/xanthine:H⁺ symporter from the ascomycote Aspergillus nidulans (3–7). Studies with chimeric transporter constructs (3), site-directed mutagenesis, second-site suppressors, and kinetic inhibition analysis of ligand specificity have shown that a conserved NAT/NCS2 motif region between putative transmembrane helices 8 and 9 of UapA includes determinants of substrate recognition and selectivity, with at least one residue (Gln-408) implicated in binding with the imidazole moiety of purine (4), whereas a conserved QH motif at the middle of TM1 is important for activity and/or correct targeting to the plasma membrane (5), and an aromatic residue at the middle of TM12 (Phe-528) may act as a purine substrate selectivity filter (6). It has been proposed that TM1, TM12, and the NAT motif region interact functionally to determine affinity and specificity for uric acid (7).Recently, we characterized the first purine-specific members of the NAT/NCS2 family from a Gram-negative bacterium, namely YgfO and YicE of Escherichia coli K-12 (8), as high affinity xanthine:H⁺ symporters that cannot use uric acid, hypoxanthine, uracil, or other nucleobases as a substrate and cannot recognize analogues substituted at positions 7 or 8 of the imidazole ring. We launched a systematic series of Cys-scanning and site-directed mutagenesis studies of YgfO to elucidate structure-function relationships in a bacterial NAT (9, 10). In the course of these studies, we showed that the NAT motif sequence region of YgfO includes the essential determinants Gln-324, irreplaceable for high affinity binding and uptake; Asn-325, irreplaceable for active transport; and an α-helical stripe of residues (Thr-332, Gly-333, Ser-336, Val-339), highly sensitive to site-directed alkylation and important for ligand selectivity³ (9). In addition, we provided evidence that Asn-430 of TM12 is close to the purine binding site and Ile-432 optimizes binding indirectly (10). These studies also show that the bacterial (9, 10) and fungal (4, 6) NAT determinants are strikingly similar, implying that few of the residues conserved within the members of NAT family may be invariably critical for function.In this report, we have studied the highly polar (Gln or Asn) and putatively charged (Asp, Glu, His, Lys, or Arg) residues of YgfO permease that are predicted to lie in transmembrane helices. Such residues are expected to face other hydrophilic parts of the protein and/or the solvent-accessible environment of the binding pocket and often play crucial roles in substrate binding and the mechanism of energy coupling in active transport (11–14). Employing systematic site-directed mutagenesis of a set of 14 putatively charged and 7 highly polar residues predicted to lie in TMs (Fig. 1) and combining evidence from transport, immunoblotting, sulfhydryl alkylation, and ligand inhibition assays of a set of 60 site-directed mutants, we have identified four new important determinants in the YgfO mechanism: His-31 and Asn-93, which are crucial for affinity and/or specificity of binding purine analogues; and Glu-272 and Asp-304, which are irreplaceable for active xanthine transport. The results are discussed in conjunction with our previous findings on the role of TM12 and the NAT motif region and with respect to comparison with the major fungal homolog (UapA).Open in a separate windowFIGURE 1.Proposed topology of YgfO highlighting the polar/charged residues. This model is based on the program TMHMM, evidence that the C terminus is cytoplasmic (10, 25), and our unpublished evidence⁶ on the accessibility of loops to hydrophilic reagents from SCAM analysis. Putatively charged (K/R/H/D/E) or highly polar (Q/H) residues are enlarged and circled. Residues that fall in transmembrane helices (TMs) or in the NAT motif sequence (residues 323–333), as well as residue Asp-276 (which is discussed under “Discussion”) are shown with a dark background. Residues delineated as important to our studies are numbered and shown in red (this study) or blue (previous studies). The ambiguous topology segment 299–323 upstream of the NAT motif is designated as TM9a, and the transmembrane segment 330–357 that follows is designated as TM9b. SCAM analysis⁶ of the NAT motif shows that residues 323–333 are accessible to solvent from the outside (light blue-gray area), indicating that this region is topologically dynamic and might constitute a flexible, substrate-accessible (7, 9) reentry loop.     

Properties of D-arabinose isomerase purified from two strains of Escherichia coli

d-Arabinose isomerase (EC 5.3.1.3) has been isolated from l-fucose-induced cultures of Escherichia coli K-12 and d-arabinose-induced cultures of E. coli B/r. Both enzymes were homogeneous in an ultracentrifuge and migrated as single bands upon disc electrophoresis in acrylamide gels. The s(20,w) was 14.5 x 10(-13) sec for the E. coli K-12 enzyme and 14.3 x 10(-13) sec for the E. coli B/r enzyme. The molecular weight, determined by high-speed sedimentation equilibrium, was 3.55 +/- 0.06 x 10(5) for the E. coli K-12 enzyme and 3.42 +/- 0.04 x 10(5) for the enzyme isolated from E. coli B/r. Both enzyme preparations were active wth l-fucose or d-arabinose as substrates and showed no activity on any of the other aldopentoses or aldohexoses tested. With the E. coli K-12 enzyme, the K(m) was 2.8 x 10(-1)m for d-arabinose and 4.5 x 10(-2)m for l-fucose; with the E. coli B/r enzyme, the K(m) was 1.7 x 10(-1)m for d-arabinose and 4.2 x 10(-2)m for l-fucose. Both enzymes were inhibited by several of the polyalcohols tested, ribitol, l-arabitol, and dulcitol being the strongest. Both enzymes exhibited a broad plateau of optimal catalytic activity in the alkaline range. Both enzymes were stimulated by the presence of Mn(2+) or Co(2+) ions, but were strongly inhibited by the presence of Cd(2+) ions. Both enzymes were precipitated by antisera prepared against either enzyme preparation. The amino acid composition for both proteins has been determined; a striking similarity has been detected. Both enzymes could be dissociated, by protonation at pH 2 or by dialysis against buffer containing 8 m urea, into subunits that were homogeneous in an ultracentrifuge and migrated as single bands on disc electrophoresis in acrylamide gels containing urea. The molecular weight of the subunit, determined by high-speed sedimentation equilibrium, was 9.09 +/- 0.2 x 10(4) for the enzyme from E. coli K-12 and 8.46 +/- 0.1 x 10(4) for the enzyme from E. coli B/r. On the basis of biophysical studies, both isomerases appear to be oligomeric proteins consisting of four identical subunits.     

抑制差减杂交筛选禽致病性大肠杆菌基因组差异片段及其分析

采用抑制差减杂交技术(Suppression subtractive hybridization,SSH)对禽致病性大肠杆菌E037株(血清型O78)与非致病菌株K-12MG1655以及同一O2血清型高致病菌株E058与低致病菌株E526进行基因组差异片段克隆与分析。从E037株中共检出17个特异性差异片段,E058株中共检出32个特异性差异片段。经同源分析,这些序列可分为4类:质粒相关序列、噬菌体相关序列、已知功能序列、未知功能序列。这些差异片段包含许多重要的大肠杆菌毒力相关基因,如大肠杆菌素、气杆菌素受体、铁基因簇等。49个片段中,14个片段与其它微生物基因组同源性较高。结果表明,大肠杆菌高致病株与低致病菌株或非致病菌株基因组间存在较多差异基因,其中包括毒力、毒力相关基因、代谢以及噬菌体等基因成分。     

Over-representation of Chi sequences caused by di-codon increase in Escherichia coli K-12

Chi sequences (5'-GCTGGTGG-3') are cis-acting 8 bp sequence elements that enhance homologous recombination promoted by the RecBCD pathway in Escherichia coli. The genome of E. coli K-12 MG1655 contains 1009 Chi sequences and this frequency far exceeds the expected value for occurrence of an 8 bp sequence in a genome of this size. It is generally thought that the over-representation of Chi sequences indicates that they have been selected for during evolution because of their function in recombination. The genes from three E. coli strains (K-12, O157 and CFT) were classified into three categories (island, match to other E. coli, and backbone). Island genes have a different base composition and codon usage in comparison with those in the backbone genes, therefore they were relatively new and not yet adapted to the base composition patterns and codon usage typical of the recipient genome. The over-representation of Chi sequences was examined by comparing Chi frequencies and codon frequencies between island and backbone genes. The difference in the CTGGTG di-codon frequency between the backbone and island genes was correlated with the frequency of Chi sequences which were translated in the Leu-Val (-G/CTG/GTG/G-) reading frame in the K-12 strain. These results suggest that the main reading frame of Chi sequences increased as a result of the di-codon CTG-GTG increasing under a genome-wide pressure for adapting to the codon usage and base composition of the E. coli K-12 strain, and that the RecBCD recombinase might adjust its recognition sequence to a frequently occurring oligomer such as G-CTG-GTG-G.     

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.     

Insights to the evolution of Nucleobase-Ascorbate Transporters (NAT/NCS2 family) from the Cys-scanning analysis of xanthine permease XanQ

The nucleobase-ascorbate transporter or nucleobase-cation symporter-2 (NAT/NCS2) family is one of the five known families of transporters that use nucleobases as their principal substrates and the only one that is evolutionarily conserved and widespread in all major taxa of organisms. The family is a typical paradigm of a group of related transporters for which conservation in sequence and overall structure correlates with high functional variations between homologs. Strikingly, the human homologs fail to recognize nucleobases or related cytotoxic compounds. This fact allows important biomedical perspectives for translation of structure-function knowledge on this family to the rational design of targeted antimicrobial purine-related drugs. To date, very few homologs have been characterized experimentally in detail and only two, the xanthine permease XanQ and the uric acid/xanthine permease UapA, have been studied extensively with site-directed mutagenesis. Recently, the high-resolution structure of a related homolog, the uracil permease UraA, has been solved for the first time with crystallography. In this review, I summarize current knowledge and emphasize how the systematic Cys-scanning mutagenesis of XanQ, in conjunction with existing biochemical and genetic evidence for UapA and the x-ray structure of UraA, allow insight on the structure-function and evolutionary relationships of this important group of transporters. The review is organized in three parts referring to (I) the theory of use of Cys-scanning approaches in the study of membrane transporter families, (II) the state of the art with experimental knowledge and current research on the NAT/NCS2 family, (III) the perspectives derived from the Cys-scanning analysis of XanQ.     

A genome rearrangement has orphaned the Escherichia coli K-12 AcpT phosphopantetheinyl transferase from its cognate Escherichia coli O157:H7 substrates

Phosphopantetheinyl transferases (PPTases) are enzymes that catalyse the transfer of a 4'-phosphopantetheine moiety from CoA to a conserved serine residue of a carrier protein. These carrier proteins use the 4'-phosphopantetheine thiol to shuttle intermediates between the active sites of biosynthetic enzymes involved in fatty acid, non-ribosomal peptide and polyketide synthesis. Three PPTases have been previously been identified in Escherichia coli K-12 and other E. coli strains by homology searches and are encoded by the genes acpS, entD and acpT. Both AcpS and EntD have been well studied whereas the function of AcpT has been an enigma because no carrier protein substrate could be found. We report genetic and biochemical evidence that AcpT modifies two carrier proteins encoded in O-island 138, a cluster of fatty acid biosynthesis-like genes located adjacent to acpT in the genome of the pathogenic E. coli strain O157:H7 (E. coli K-12 and several other sequenced E. coli and Shigella strains lack O-island 138). The two carrier proteins of O-island 138 of strain O157:H7 are not modified (or only very poorly modified) by AcpS, the PPTase responsible for 4'-phosphopantetheine attachment to the acyl carrier protein (AcpP) of fatty acid synthesis. We demonstrate that AcpT cannot functionally replace AcpS in E. coli K-12 either in its native chromosomal location or upon insertion of acpT into the acpS chromosomal location. However, in the absence of AcpS activity AcpT does allow very slow growth thus providing a rationale for its retention in the absence of its cognate substrates. These results together with phylogenetic analyses and comparisons of the E. coli and Shigella strains of known genome sequence strongly argue that AcpT has been orphaned from its cognate substrates by a deletion event that occurred in a common ancestor of these organisms. This seems one of the few cases where a chromosomal rearrangement has been functionally demonstrated to be a deletion event rather than an insertion event in the reference organism. We also show that the previously reported suppression of an acpS mutation by the deletion of Lon protease is an artifact of the increased capsular polysaccharide production of lon strains.