Mutational analysis of N-glycosylation recognition sites on the biochemical properties of Aspergillus kawachii α-l-arabinofuranosidase 54

A role for N-linked oligosaccharides on the biochemical properties of recombinant α-l-arabinofuranosidase 54 (AkAbf54) defined in glycoside hydrolase family 54 from Aspergillus kawachii expressed in Pichia pastoris was analyzed by site-directed mutagenesis. Two N-linked glycosylation motifs (Asn⁸³–Thr–Thr and Asn²⁰²–Ser–Thr) were found in the AkAbf54 sequence. AkAbf54 comprises two domains, a catalytic domain and an arabinose-binding domain classified as carbohydrate-binding module 42. Two N-linked glycosylation sites are located in the catalytic domain. Asn⁸³, Asn²⁰², and the two residues together were replaced with glutamine by site-directed mutagenesis. The biochemical properties and kinetic parameters of the wild-type and mutant enzymes expressed in P. pastoris were examined. The N83Q mutant enzyme had the same catalytic activity and thermostability as the wild-type enzyme. On the other hand, the N202Q and N83Q/N202Q mutant enzymes exhibited a considerable decrease in thermostability compared to the glycosylated wild-type enzyme. The N202Q and N83Q/N202Q mutant enzymes also had slightly less specific activity towards arabinan and debranched arabinan. However, no significant effect on the affinity of the mutant enzymes for the ligands arabinan, debranched arabinan, and wheat and rye arabinoxylans was detected by affinity gel electrophoresis. These observations suggest that the glycosylation at Asn²⁰² may contribute to thermostability and catalysis.     

Glycosylation at Asn211 Regulates the Activation State of the Discoidin Domain Receptor 1 (DDR1)

Discoidin domain receptor 1 (DDR1) belongs to a unique family of receptor tyrosine kinases that signal in response to collagens. DDR1 undergoes autophosphorylation in response to collagen binding with a slow and sustained kinetics that is unique among members of the receptor tyrosine kinase family. DDR1 dimerization precedes receptor activation suggesting a structural inhibitory mechanism to prevent unwarranted phosphorylation. However, the mechanism(s) that maintains the autoinhibitory state of the DDR1 dimers is unknown. Here, we report that N-glycosylation at the Asn²¹¹ residue plays a unique role in the control of DDR1 dimerization and autophosphorylation. Using site-directed mutagenesis, we found that mutations that disrupt the conserved ²¹¹NDS N-glycosylation motif, but not other N-glycosylation sites (Asn²⁶⁰, Asn³⁷¹, and Asn³⁹⁴), result in collagen I-independent constitutive phosphorylation. Mass spectrometry revealed that the N211Q mutant undergoes phosphorylation at Tyr⁴⁸⁴, Tyr⁵²⁰, Tyr⁷⁹², and Tyr⁷⁹⁷. The N211Q traffics to the cell surface, and its ectodomain displays collagen I binding with an affinity similar to that of the wild-type DDR1 ectodomain. However, unlike the wild-type receptor, the N211Q mutant exhibits enhanced receptor dimerization and sustained activation upon ligand withdrawal. Taken together, these data suggest that N-glycosylation at the highly conserved ²¹¹NDS motif evolved to act as a negative repressor of DDR1 phosphorylation in the absence of ligand. The presence of glycan moieties at that site may help to lock the collagen-binding domain in the inactive state and prevent unwarranted signaling by receptor dimers. These studies provide a novel insight into the structural mechanisms that regulate DDR activation.     

Pancreatic Polypeptide Is Recognized by Two Hydrophobic Domains of the Human Y4 Receptor Binding Pocket

Structural characterization of the human Y₄ receptor (hY₄R) interaction with human pancreatic polypeptide (hPP) is crucial, not only for understanding its biological function but also for testing treatment strategies for obesity that target this interaction. Here, the interaction of receptor mutants with pancreatic polypeptide analogs was studied through double-cycle mutagenesis. To guide mutagenesis and interpret results, a three-dimensional comparative model of the hY₄R-hPP complex was constructed based on all available class A G protein-coupled receptor crystal structures and refined using experimental data. Our study reveals that residues of the hPP and the hY₄R form a complex network consisting of ionic interactions, hydrophobic interactions, and hydrogen binding. Residues Tyr^2.64, Asp^2.68, Asn^6.55, Asn^7.32, and Phe^7.35 of Y₄R are found to be important in receptor activation by hPP. Specifically, Tyr^2.64 interacts with Tyr²⁷ of hPP through hydrophobic contacts. Asn^7.32 is affected by modifications on position Arg³³ of hPP, suggesting a hydrogen bond between these two residues. Likewise, we find that Phe^7.35 is affected by modifications of hPP at positions 33 and 36, indicating interactions between these three amino acids. Taken together, we demonstrate that the top of transmembrane helix 2 (TM2) and the top of transmembrane helices 6 and 7 (TM6–TM7) form the core of the peptide binding pocket. These findings will contribute to the rational design of ligands that bind the receptor more effectively to produce an enhanced agonistic or antagonistic effect.     

Site-Specific N-Glycosylation of Caprine Lysostaphin Restricts its Bacteriolytic Activity Toward Staphylococcus Aureus

Lysostaphin (LYS) is an anti-staphylococcal prokaryotic polypeptide that has been used to avoid Staphylococcus aureus mastitis through transgenic or viral vector approaches exogenously expressed in dairy animals. However, glycosylation of lysostaphin expressed in mammalian cells results in a loss of bioactivity. Until now, the mechanism of site-specific glycosylation of lysostaphin causing this loss of bioactivity remains unknown. An immortalized caprine mammary epithelial cell line (CMEC-08-D) was used to study recombinant lysostaphin fused with goat β-casein, goat lactoferrin (LF) or prokaryotic signal peptides. These constructs were separately ectopically expressed in CMEC-08-D. Results of site-directed mutagenesis show that Asn¹²⁵ but not Asn²³² is the exact glycosylation site of lysostaphin expressed in CMEC-08-D. In addition, the effect of glycosylation of lysostaphin on its staphylolytic activity was identified through bacterial plate assay. The data indicated that wild type and mutated N232Q-lysostaphin (Asn²³² to Gln²³² substitution) lacked staphylolytic activity. In contrast, mutated N125Q (Asn¹²⁵ to Gln¹²⁵ substitution) and N125Q/N232Q-lysostaphin possessed staphylolytic activity. On the other hand, all mutated lysostaphin showed no change in binding ability to S. aureus. This reveals that N-glycosylation at Asn¹²⁵ of lysostaphin expressed in a eukaryotic system greatly decreases lysostaphin bacteriolytic activity but does not affect its binding ability to S. aureus.     

Triple mutated antibody scFv2F3 with high GPx activity: insights from MD, docking, MDFE, and MM-PBSA simulation

By combining computational design and site-directed mutagenesis, we have engineered a new catalytic ability into the antibody scFv2F3 by installing a catalytic triad (Trp²⁹–Sec⁵²–Gln⁷²). The resulting abzyme, Se-scFv2F3, exhibits a high glutathione peroxidase (GPx) activity, approaching the native enzyme activity. Activity assays and a systematic computational study were performed to investigate the effect of successive replacement of residues at positions 29, 52, and 72. The results revealed that an active site Ser⁵²/Sec substitution is critical for the GPx activity of Se-scFv2F3. In addition, Phe²⁹/Trp–Val⁷²/Gln mutations enhance the reaction rate via functional cooperation with Sec⁵². Molecular dynamics simulations showed that the designed catalytic triad is very stable and the conformational flexibility caused by Tyr¹⁰¹ occurs mainly in the loop of complementarity determining region 3. The docking studies illustrated the importance of this loop that favors the conformational shift of Tyr⁵⁴, Asn⁵⁵, and Gly⁵⁶ to stabilize substrate binding. Molecular dynamics free energy and molecular mechanics-Poisson Boltzmann surface area calculations estimated the pK _a shifts of the catalytic residue and the binding free energies of docked complexes, suggesting that dipole–dipole interactions among Trp²⁹–Sec⁵²–Gln⁷² lead to the change of free energy that promotes the residual catalytic activity and the substrate-binding capacity. The calculated results agree well with the experimental data, which should help to clarify why Se-scFv2F3 exhibits high catalytic efficiency.     

Carbohydrate-binding site of a novel mannose-specific lectin from fugu (Takifugu rubripes) skin mucus

Pufflectin-s, identified in the skin mucus of the fugu Takifugu rubripes, is a novel mannose-specific lectin with similar structure to monocotyledonous plant lectins. In the present study, mutational analysis was used to reveal the mannose-binding sites of pufflectin-s. Putative binding sites were mutated as follows: binding site 1; rPL-D32E (Asp³² → Glu³²), rPL-N34S (Asn³⁴ → Ser³⁴) and rPL-V36A (Val³⁶ → Ala³⁶) whereas binding site 2; rPL-D61E (Asp⁶¹ → Glu⁶¹), rPL-N63S (Asn⁶³ → Ser⁶³) and rPL-V65A (Val⁶⁵ → Ala⁶⁵). All recombinant proteins were expressed in Escherichia coli, purified with two chromatographic steps, and then subjected to mannose-binding assay by affinity chromatography. Recombinant wild-type pufflectin-s (rPL-wt) as well as three mutants with changes in binding site 2 could bind to mannose, in contrast to the three mutants with changes in binding site 1 in which mannose-binding activity was completely lost. These results clearly demonstrate that, at the least, binding site 1 is critical to mannose-binding activity in pufflectin-s.     

Mutagenesis analyses explore residues responsible for the neurotoxic and anticoagulant activities of Trimucrotoxin, a pit-viper venom Asn6-phospholipase A2

Trimucrotoxin (TmCT) is an Asn⁶-containing phospholipase A₂ (PLA₂) from Protobothrops mucrosquamatus (pit-viper) venom. In an attempt to characterize the amino acid residues responsible for the neurotoxic and anticoagulant activities of TmCT, the recombinant fusion proteins of TmCT wild type and mutants were expressed in Escherichia coli. Correct refolding and processing of 37 TmCT mutants were confirmed by their HPLC retention times, circular dichroism spectra, and masses obtained from ESI-MS spectrometry. Each mutant was assayed by pH-stat titration using zwitterionic as well as anionic micelle substrates, and the neurotoxicity was evaluated by using the contractile responses of chick biventer cervicis muscles. The results demonstrated that the residues Asn¹, Asn⁶, Lys⁷, Ile¹¹, Met¹², Gly⁵³, Thr⁷⁹, His¹⁰⁸ and Met¹¹⁸ are important to TmCT neurotoxicity. Through various tests, we also confirmed that enzymatic activity, as opposed to binding to Factor Xa, was a necessary part of TmCT’s anticoagulant effect. In addition, pulldown assays of the WT and selected mutants revealed that TmCT’s in vitro binding to crotoxin acidic subunit may involve a broad surface area. We conclude that the hot spot mutations at specific positions 53, 79, 108, and 118 during the pit-viper Asn⁶-PLA₂ evolution regulate their neurotoxicities, and that many of the neurotoxic site residues and the anticoagulant mechanism of TmCT are different from those of ammodytoxin A (a true-viper venom neurotoxic PLA₂).     

Recombinant Deamidated Mutants of Erwinia chrysanthemi l-Asparaginase Have Similar or Increased Activity Compared to Wild-Type Enzyme

The enzyme Erwinia chrysanthemi l-asparaginase (ErA) is an important biopharmaceutical product used in the treatment of acute lymphoblastic leukaemia. Like all proteins, certain asparagine (Asn) residues of ErA are susceptible to deamidation to aspartic acid (Asp), which may be a concern with respect to enzyme activity and potentially to pharmaceutical efficacy. Recombinant ErA mutants containing Asn to Asp changes were expressed, purified and characterised. Two mutants with single deamidation sites (N41D and N281D) were found to have approximately the same specific activity (1,062 and 924 U/mg, respectively) as the wild-type (908 U/mg). However, a double mutant (N41D N281D) had an increased specific activity (1261 U/mg). The N41D mutation conferred a slight increase in the catalytic constant (k _cat 657 s^?1) when compared to the WT (k _cat 565 s^?1), which was further increased in the double mutant, with a k _cat of 798 s^?1. Structural analyses showed that the slight changes caused by point mutation of Asn₄₁ to Asp may have reduced the number of hydrogen bonds in this α-helical part of the protein structure, resulting in subtle changes in enzyme turnover, both structurally and catalytically. The increased α-helical content observed with the N41D mutation by circular dichroism spectroscopy correlates with the difference in k _cat, but not K _m. The N281D mutation resulted in a lower glutaminase activity compared with WT and the N41D mutant, however the N281D mutation also imparted less stability to the enzyme at elevated temperatures. Taken as a whole, these data suggest that ErA deamidation at the Asn₄₁ and Asn₂₈₁ sites does not affect enzyme activity and should not be a concern during processing, storage or clinical use. The production of recombinant deamidated variants has proven an effective and powerful means of studying the effect of these changes and may be a useful strategy for other biopharmaceutical products.     

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.     

Structural basis of the broad substrate tolerance of the antibody 7B9-catalyzed hydrolysis of p-nitrobenzyl esters

Catalytic antibody 7B9, which was elicited against p-nitrobenzyl phosphonate transition-state analogue (TSA) 1, hydrolyzes a wide range of p-nitrobenzyl monoesters and thus shows broad substrate tolerance. To reveal the molecular basis of this substrate tolerance, the 7B9 Fab fragment complexed with p-nitrobenzyl ethylphosphonate 2 was crystallized and the three-dimensional structure was determined. The crystal structure showed that the strongly antigenic p-nitrobenzyl moiety occupied a relatively shallow antigen-combining site and therefore the alkyl moiety was located outside the pocket. These results support the observed broad substrate tolerance of 7B9 and help rationalize how 7B9 can catalyze various p-nitrobenzyl ester derivatives. The crystal structure also showed that three amino acid residues (Asn^H33, Ser^H95, and Arg^L96) were placed in key positions to form hydrogen bonds with the phosphonate oxygens of the transitions-state analogue. In addition, the role of these amino acid residues was examined by site-directed mutagenesis to alanine: all mutants (Asn^H33Ala, Ser^H95Ala, and Arg^L96Ala) showed no detectable catalytic activity. Coupling the findings from our structural studies with these mutagenesis results clarified the structural basis of the observed broad substrate tolerance of antibody 7B9-catalyzed hydrolyses. Our findings provide new strategies for the generation of catalytic antibodies that accept a broad range of substrates, aiding their practical application in synthetic organic chemistry.     

Ca2+ Binding to Site I of the Cardiac Ca2+ Pump Is Sufficient to Dissociate Phospholamban

Phospholamban (PLB) inhibits the activity of SERCA2a, the Ca²⁺-ATPase in cardiac sarcoplasmic reticulum, by decreasing the apparent affinity of the enzyme for Ca²⁺. Recent cross-linking studies have suggested that PLB binding and Ca²⁺ binding to SERCA2a are mutually exclusive. PLB binds to the E2 conformation of the Ca²⁺-ATPase, preventing formation of E1, the conformation that binds two Ca²⁺ (at sites I and II) with high affinity and is required for ATP hydrolysis. Here we determined whether Ca²⁺ binding to site I, site II, or both sites is sufficient to dissociate PLB from the Ca²⁺ pump. Seven SERCA2a mutants with amino acid substitutions at Ca²⁺-binding site I (E770Q, T798A, and E907Q), site II (E309Q and N795A), or both sites (D799N and E309Q/E770Q) were made, and the effects of Ca²⁺ on N30C-PLB cross-linking to Lys³²⁸ of SERCA2a were measured. In agreement with earlier reports with the skeletal muscle Ca²⁺-ATPase, none of the SERCA2a mutants (except E907Q) hydrolyzed ATP in the presence of Ca²⁺; however, all were phosphorylatable by P_i to form E2P. Ca²⁺ inhibition of E2P formation was observed only in SERCA2a mutants retaining site I. In cross-linking assays, strong cross-linking between N30C-PLB and each Ca²⁺-ATPase mutant was observed in the absence of Ca²⁺. Importantly, however, micromolar Ca²⁺ inhibited PLB cross-linking only to mutants retaining a functional Ca²⁺-binding site I. The dynamic equilibrium between Ca²⁺ pumps and N30C-PLB was retained by all mutants, demonstrating normal regulation of cross-linking by ATP, thapsigargin, and anti-PLB antibody. From these results we conclude that site I is the key Ca²⁺-binding site regulating the physical association between PLB and SERCA2a.     

Functional Properties of Glycosylated Lysozyme Secreted in Pichia pastoris

Various mutant lysozymes having the N-glycosylation signal sequence, R21T (Asn¹⁹-Tyr²⁰-Thr²¹), G49N (Asn⁴⁹- Ser⁵⁰-Thr⁵¹), R21T/G49N (Asn¹⁹-Tyr²⁰-Thr²¹/Asn⁴⁹-Ser⁵⁰-Thr⁵¹), were secreted in the Pichia pastoris expression system. The secreted amounts of these mutant glycosylated lysozymes were almost the same as those of wild-type lysozyme (about 30 mg/liter). Glycosylation of the mutant lysozymes was confirmed by SDS-PAGE patterns, Endo-H treatment, TOF-MS analysis and chemical analysis. The composition of the carbohydrate chain attached to the single glycosylated lysozymes, R21T and G49N, was GlcNAc₂Man_9-11, while that of the double glycosylated lysozyme, R21T/G49N, was GlcNAc₄Man_27-32. The results of a CD analysis and lytic activity suggested that the conformation of the single glycosylated lysozymes had been conserved, while that of the double glycosylated lysozyme was less stable. The emulsifying properties of the lysozyme when glycosylated were greatly improved, being especially noteworthy in the double glycosylated lysozyme.     

Single Point Mutations in the Small Cytoplasmic Loop of ACA8, a Plasma Membrane Ca2+-ATPase of Arabidopsis thaliana, Generate Partially Deregulated Pumps

ACA8 is a type 2B Ca²⁺-ATPase having a regulatory N terminus whose auto-inhibitory action can be suppressed by binding of calmodulin (CaM) or of acidic phospholipids. ACA8 N terminus is able to interact with a region of the small cytoplasmic loop connecting transmembrane domains 2 and 3. To determine the role of this interaction in auto-inhibition we analyzed single point mutants produced by mutagenesis of ACA8 Glu²⁵² to Asn³⁴⁵ sequence. Mutation to Ala of any of six tested acidic residues (Glu²⁵², Asp²⁷³, Asp²⁹¹, Asp³⁰³, Glu³⁰², or Asp³³²) renders an enzyme that is less dependent on CaM for activity. These results highlight the relevance in ACA8 auto-inhibition of a negative charge of the surface area of the small cytoplasmic loop. The most deregulated of these mutants is D291A ACA8, which is less activated by controlled proteolysis or by acidic phospholipids; the D291A mutant has an apparent affinity for CaM higher than wild-type ACA8. Moreover, its phenotype is stronger than that of D291N ACA8, suggesting a more direct involvement of this residue in the mechanism of auto-inhibition. Among the other produced mutants (I284A, N286A, P289A, P322A, V344A, and N345A), only P322A ACA8 is less dependent on CaM for activity than the wild type. The results reported in this study provide the first evidence that the small cytoplasmic loop of a type 2B Ca²⁺-ATPase plays a role in the attainment of the auto-inhibited state.     

A Residue in Loop 9 of the ��2-Subunit Stabilizes the Closed State of the GABAA Receptor

In γ-aminobutyric acid type A (GABA_A) receptors, the structural elements that couple ligand binding to channel opening remain poorly defined. Here, site-directed mutagenesis was used to determine if Loop 9 on the non-GABA binding site interface of the β2-subunit may be involved in GABA_A receptor activation. Specifically, residues Gly¹⁷⁰-Gln¹⁸⁵ of the β2-subunit were mutated to alanine, co-expressed with wild-type α1- and γ2S-subunits in human embryonic kidney (HEK) 293 cells and assayed for their activation by GABA, the intravenous anesthetic propofol and the endogenous neurosteroid pregnanolone using whole cell macroscopic recordings. Three mutants, G170A, V175A, and G177A, produced 2.5-, 6.7-, and 5.6-fold increases in GABA EC₅₀ whereas one mutant, Q185A, produced a 5.2-fold decrease in GABA EC₅₀. None of the mutations affected the ability of propofol or pregnanolone to potentiate a submaximal GABA response, but the Q185A mutant exhibited 8.3- and 3.5-fold increases in the percent direct activation by propofol and pregnanolone, respectively. Mutant Q185A receptors also had an increased leak current that was sensitive to picrotoxin, indicating an increased gating efficiency. Further Q185E, Q185L, and Q185W substitutions revealed a strong correlation between the hydropathy of the amino acid at this position and the GABA EC₅₀. Taken together, these results indicate that β2 Loop 9 is involved in receptor activation by GABA, propofol, and pregnanolone and that β2(Q185) participates in hydrophilic interactions that are important for stabilizing the closed state of the GABA_A receptor.     

Gradually accumulating beneficial mutations to improve the thermostability of <Emphasis Type="Italic">N</Emphasis>-carbamoyl-<Emphasis Type="SmallCaps">d</Emphasis>-amino acid amidohydrolase by step-wise evolution

To further enhance repeated batch reactions with immobilized N-carbamoyl-d-amino acid amidohydrolase (DCase), which can be used for the industrial production of d-amino acids, the stability of high soluble mutant DCase-M3 from Ralstonia pickettii CGMCC1596 was improved by step-wise evolution. In our previous report, six thermostability-related sites were identified by error-prone PCR. Based on the above result, an improved mutant B5 (Q12L/Q23L/H248Q/T262A/T263S) was obtained through two rounds of DNA shuffling, showing a 10°C increase in the T ₅₀ (defined as the temperature at which heat treatment for 15 min reduced the initial activity by 50%) compared with the parental enzyme DCase-M3. Furthermore, several thermostability-related sites (Met³¹, Asn⁹³, Gln²⁰⁷, Asn²⁴², Glu²⁶⁶, Thr²⁷¹, Ala²⁷³) on B5 were identified using amino acid consensus approach based on sequence alignment of homologous DCases. These sites were further investigated by iterative saturation mutagenesis (ISM), and a combinational mutant D1 (Q12L/Q23L/Q207E/N242G/H248Q/T262A/T263S/E266D/T271I/A273P) that enhanced the T ₅₀ by about 16°C over DCase-M3 was obtained. Oxidative stability assay showed that the most heat-resisting mutant displayed only a slight increase in resistance to hydrogen peroxide. Comparative characterization showed that D1 not only maintained its characteristic high solubility but also shared similar k _cat and K _m values and optimum reaction pHs with the parental enzyme. The significantly improved mutants in the immobilized form are expected to be applied in the industrial production of d-p-hydroxyphenylglycine.     

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.     

Differential copper binding to alpha-synuclein and its disease-associated mutants affect the aggregation and amyloid formation

BackgroundCopper is an essential trace element required for the proper functioning of various enzymes present in the central nervous system. An imbalance in the copper homeostasis results in the pathology of various neurodegenerative disorders including Parkinson’s Disease. Hence, residue specific interaction of Cu²⁺ to α-Syn along with the familial mutants H50Q and G51D needs to be studied in detail.MethodsWe investigated the residue specific mapping of Cu²⁺ binding sites and binding strength using solution-state NMR and ITC respectively. The aggregation kinetics, secondary structural changes, and morphology of the formed fibrils in the presence and absence of Cu²⁺ were studied using fluorescence, CD, and AFM respectively.ResultsCopper binding to α-Syn takes place at three different sites with a higher affinity for the region 48-53. While one of the sites got abolished in the case of H50Q, the mutant G51D showed a binding pattern similar to WT. The aggregation kinetics of these proteins in the presence of Cu²⁺ showed an enhanced rate of fibril formation with a pronounced effect for G51D.ConclusionCu²⁺ binding results in the destabilization of long-range tertiary interactions in α-Syn leading to the exposure of highly amyloidogenic NAC region which results in the increased rate of fibril formation. Although the residues 48-53 have a stronger affinity for Cu²⁺ in case of WT and G51D, the binding is not responsible for enhancing the rate of fibril formation in case of H50Q.General SignificanceThese findings will help in the better understanding of Cu²⁺ catalyzed aggregation of synucleins.     

Identification and characterization of an anti-isoaspartic acid monoclonal antibody

The deamidation and rearrangement of protein-bound asparagine residues occurs when peptides and proteins are exposed to acidic or alkaline aqueous media. Asn⁹⁹ of bovine growth hormone (bGH) is readily modified via these mechanisms. We have generated a monoclonal antibody (MAb) that interacts with a bGH fragment that contains an isoaspartyl residue. To obtain this antibody, CAF₁/J mice were immunized with [isoaspartyl⁹⁹]-bGH(96–112) conjugated to BSA. Using a competitive ELISA assay, the interaction of this MAb to [isoaspartyl⁹⁹]-bGH(96–112) has been observed to have an apparentK _m of 150 nM. The corresponding native peptide and other bGH fragments do not bind to this antibody with high affinity. For example, the binding affinities of [Asp⁹⁹]-bGH(96–112) and [Glu⁹⁹]-bGH(96–112) to this antibody are 54- and 78-fold lower than the corresponding isoaspartyl peptide. The antibody also binds to bGH that is enriched in isoaspartic acid at position 99, but not to the unmodified protein. The binding epitope of the peptide has been further characterized by comparing the binding of bGH(96–112) analogues to the MAb. Alanine substitution at residues 99, 100, 101, and 103 reduce binding affinity to the antibody by more than 10³-fold. Replacement of valine with alanine at position 102 has much less impact on antibody affinity. Further experiments suggest that the relative insensitivity to this substitution is due to the structural similarity of these sidechains. Other isoaspartic acid-containing peptides not derived from the bGH sequence do not bind to the antibody. We conclude that the epitope binding site of this MAb is highly specific for 99–103 of [isoaspartyl⁹⁹]-bGH(96–112). This strategy can be used to obtain monoclonal antibodies that selectively interact with other proteins that have been similarly modified, or that contain other chemical modifications. The potential for generating antibodies that universally recognize protein- and peptide-bound isoaspartic acid residues is discussed.     

Identification of a key residue determining substrate affinity in the human glucose transporter GLUT1

Asn³³¹ in transmembrane segment 7 of the yeast Saccharomyces cerevisiae transporter Hxt2 has been identified as a single key residue for high-affinity glucose transport by comprehensive chimera approach. The glucose transporter GLUT1 of mammals belongs to the same major facilitator superfamily as Hxt2 and may therefore show a similar mechanism of substrate recognition. The functional role of Ile²⁸⁷ in human GLUT1, which corresponds to Asn³³¹ in Hxt2, was studied by its replacement with each of the other 19 amino acids. The mutant transporters were individually expressed in a recently developed yeast expression system for GLUT1. Replacement of Ile²⁸⁷ generated transporters with various affinities for glucose that correlated well with those of the corresponding mutants of the yeast transporter. Residues exhibiting high affinity for glucose were medium-sized, non-aromatic, uncharged and irrelevant to hydrogen-bond capability, suggesting an important role of van der Waals interaction. Sensitivity to phloretin, a specific inhibitor for the presumed exofacial glucose binding site, was decreased in two mutants, whereas that to cytochalasin B, a specific inhibitor for the presumed endofacial glucose binding site, was unchanged in the mutants. These results suggest that Ile²⁸⁷ is a key residue for maintaining high glucose affinity in GLUT1 as revealed in Hxt2 and is located at or near the exofacial glucose binding site.     

Nucleotide binding and dimerization at the chloroplast pre‐protein import receptor,atToc33, are not essential in vivo but do increase import efficiency

The atToc33 protein is one of several pre‐protein import receptors in the outer envelope of Arabidopsis chloroplasts. It is a GTPase with motifs characteristic of such proteins, and its loss in the plastid protein import 1 (ppi1) mutant interferes with the import of photosynthesis‐related pre‐proteins, causing a chlorotic phenotype in mutant plants. To assess the significance of GTPase cycling by atToc33, we generated several atToc33 point mutants with predicted effects on GTP binding (K49R, S50N and S50N/S51N), GTP hydrolysis (G45R, G45V, Q68A and N101A), both binding and hydrolysis (G45R/K49N/S50R), and dimerization or the functional interaction between dimeric partners (R125A, R130A and R130K). First, a selection of these mutants was assessed in vitro, or in yeast, to confirm that the mutations have the desired effects: in relation to nucleotide binding and dimerization, the mutants behaved as expected. Then, activities of selected mutants were tested in vivo, by assessing for complementation of ppi1 in transgenic plants. Remarkably, all tested mutants mediated high levels of complementation: complemented plants were similar to the wild type in growth rate, chlorophyll accumulation, photosynthetic performance, and chloroplast ultrastructure. Protein import into mutant chloroplasts was also complemented to >50% of the wild‐type level. Overall, the data indicate that neither nucleotide binding nor dimerization at atToc33 is essential for chloroplast import (in plants that continue to express the other TOC receptors in native form), although both processes do increase import efficiency. Absence of atToc33 GTPase activity might somehow be compensated for by that of the Toc159 receptors. However, overexpression of atToc33 (or its close relative, atToc34) in Toc159‐deficient plants did not mediate complementation, indicating that the receptors do not share functional redundancy in the conventional sense.