On the contribution of the positively charged headgroup of choline to substrate binding and catalysis in the reaction catalyzed by choline oxidase

Recent kinetic studies established that the positive charge on the trimethylammonium group of choline plays an important role in substrate binding and specificity in the reaction catalyzed by choline oxidase. In the present study, pH and solvent viscosity effects with the isosteric analogue of choline 3,3-dimethyl-butan-1-ol have been used to further dissect the contribution of the substrate positive charge to substrate binding and catalysis in the reaction catalyzed by choline oxidase. Both the kcat and kcat/Km values with 3,3-dimethyl-butan-1-ol increased to limiting values that were approximately 3- and approximately 400-times lower than those observed with choline, defining pKa values that were similar to the thermodynamic pKa value of approximately 7.5 previously determined. No effects of increased solvent viscosity were observed on the kcat and kcat/Km values with the substrate analogue at pH 8, suggesting that the chemical step of substrate oxidation is fully rate-limiting for the overall turnover and the reductive half-reaction in which the alcohol substrate is oxidized to the aldehyde. The kcat/Km value for oxygen determined with the substrate analogue was pH-independent in the pH range from 6 to 10, with an average value that was approximately 75-times lower than that previously determined with choline as substrate. These data are consistent with the positive charge headgroup of choline playing important roles for substrate binding and flavin oxidation, with minimal contribution to substrate oxidation.     

Ala-504 is a determinant of substrate binding affinity in the mouse Na/dicarboxylate cotransporter

The Na⁺/dicarboxylate cotransporters from mouse (mNaDC1) and rabbit (rbNaDC1) differ in their ability to handle adipate, a six-carbon terminal dicarboxylic acid. The mNaDC1 and rbNaDC1 amino acid sequences are 75% identical. The rbNaDC1 does not transport adipate and only succinate produced inward currents under two-electrode voltage clamp. In contrast, oocytes expressing mNaDC1 had adipate-dependent inward currents that were about 60% of those induced by succinate. In order to identify domains involved in adipate transport, we examined the functional properties of a series of chimeric transporters made between mouse and rabbit NaDC1. We find that multiple transmembrane helices (TM), particularly TM 8, 9, and 10, are involved in adipate transport. In TM 10 there is only one amino acid difference between the two proteins, corresponding to Ala-504 in mouse and Ser-512 in rabbit NaDC1. The mNaDC1-A504S mutant had decreased adipate-dependent currents relative to succinate-dependent currents and an increase in the K_0.5 for both succinate and glutarate. We conclude that multiple amino acids from TM 8, 9 and 10 contribute to the transport of adipate in NaDC1. Furthermore, Ala-504 in TM 10 is an important determinant of K_0.5 for both adipate and succinate.     

The sulfhydryl oxidase Erv1 is a substrate of the Mia40-dependent protein translocation pathway

The thiol oxidase Erv1 and the redox-regulated receptor Mia40/Tim40 are components of a disulfide relay system which mediates import of proteins into the intermembrane space (IMS) of mitochondria. Here we report that Erv1 requires Mia40 for its import into mitochondria. After passage across the translocase of the mitochondrial outer membrane Erv1 interacts via disulfide bonds with Mia40. Erv1 does not contain twin “CX₃C” or twin “CX₉C” motifs which are crucial for import of typical substrates of this pathway and it does not need two “CX₂C” motifs for import into mitochondria. Thus, Erv1 represents an unusual type of substrate of the Mia40-dependent import pathway.     

The actin binding protein, fesselin, is a member of the synaptopodin family

Fesselin is a natively unfolded protein that is abundant in avian smooth muscle. Like many natively unfolded proteins, fesselin has multiple binding partners including actin, myosin, calmodulin and α-actinin. Fesselin accelerates actin polymerization and bundles actin. These and other observations suggest that fesselin is a component of the cytoskeleton. We have now cloned fesselin and have determined the cDNA derived amino acid sequence. We verified parts of the sequence by Edman analysis and by mass spectroscopy. Our results confirmed fesselin is homologous to human synaptopodin 2 and belongs to the synaptopodin family of proteins.     

Expression and substrate specificity of betaine/proline transporters suggest a novel choline transport mechanism in sugar beet

Proline transporters (ProTs) originally described as highly selective transporters for proline, have been shown to also transport glycinebetaine (betaine). Here we examined and compared the transport properties of Bet/ProTs from betaine accumulating (sugar beet, Amaranthus, and Atriplex,) and non-accumulating (Arabidopsis) plants. Using a yeast mutant deficient for uptake of proline and betaine, it was shown that all these transporters exhibited higher affinity for betaine than proline. The uptake of betaine and proline was pH-dependent and inhibited by the proton uncoupler carbonylcyanide m-chlorophenylhydrazone (CCCP). We also investigated choline transport by using a choline transport-deficient yeast mutant. Results revealed that these transporters exhibited a higher affinity for choline uptake rather than betaine. Uptake of choline by sugar beet BvBet/ProT1 was independent of the proton gradient and the inhibition by CCCP was reduced compared with that for uptake of betaine, suggesting different proton binding properties between the transport of choline and betaine. Additionally, in situ hybridization experiments revealed the localization of sugar beet BvBet/ProT1 in phloem and xylem parenchyma cells.     

Porphyrin binding and distortion and substrate specificity in the ferrochelatase reaction: the role of active site residues

The specific insertion of a divalent metal ion into tetrapyrrole macrocycles is catalyzed by a group of enzymes called chelatases. Distortion of the tetrapyrrole has been proposed to be an important component of the mechanism of metallation. We present the structures of two different inhibitor complexes: (1) N-methylmesoporphyrin (N-MeMP) with the His183Ala variant of Bacillus subtilis ferrochelatase; (2) the wild-type form of the same enzyme with deuteroporphyrin IX 2,4-disulfonic acid dihydrochloride (dSDP). Analysis of the structures showed that only one N-MeMP isomer out of the eight possible was bound to the protein and it was different from the isomer that was earlier found to bind to the wild-type enzyme. A comparison of the distortion of this porphyrin with other porphyrin complexes of ferrochelatase and a catalytic antibody with ferrochelatase activity using normal-coordinate structural decomposition reveals that certain types of distortion are predominant in all these complexes. On the other hand, dSDP, which binds closer to the protein surface compared to N-MeMP, does not undergo any distortion upon binding to the protein, underscoring that the position of the porphyrin within the active site pocket is crucial for generating the distortion required for metal insertion. In addition, in contrast to the wild-type enzyme, Cu²⁺-soaking of the His183Ala variant complex did not show any traces of porphyrin metallation. Collectively, these results provide new insights into the role of the active site residues of ferrochelatase in controlling stereospecificity, distortion and metallation.     

Structural and biochemical characterization of the broad substrate specificity of Bacteroides thetaiotaomicron commensal sialidase

Sialidases release the terminal sialic acid residue from a wide range of sialic acid-containing polysaccharides. Bacteroides thetaiotaomicron, a symbiotic commensal microbe, resides in and dominates the human intestinal tract. We characterized the recombinant sialidase from B. thetaiotaomicron (BTSA) and demonstrated that it has broad substrate specificity with a relative activity of 97, 100 and 64 for 2,3-, 2,6- and 2,8-linked sialic substrates, respectively. The hydrolysis activity of BTSA was inhibited by a transition state analogue, 2-deoxy-2,3-dehydro-N-acetyl neuraminic acid, by competitive inhibition with a K_i value of 35 μM. The structure of BSTA was determined at a resolution of 2.3 Å. This structure exhibited a unique carbohydrate-binding domain (CBM) at its N-terminus (a.a. 23–190) that is adjacent to the catalytic domain (a.a. 191–535). The catalytic domain has a conserved arginine triad with a wide-open entrance for the substrate that exposes the catalytic residue to the surface. Unlike other pathogenic sialidases, the polysaccharide-binding site in the CBM is near the active site and possibly holds and positions the polysaccharide substrate directly at the active site. The structural feature of a wide substrate-binding groove and closer proximity of the polysaccharide-binding site to the active site could be a unique signature of the commensal sialidase BTSA and provide a molecular basis for its pharmaceutical application.     

Changing the substrate specificity of a chitooligosaccharide oxidase from Fusarium graminearum by model-inspired site-directed mutagenesis

Chitooligosaccharide oxidase (ChitO) catalyzes the oxidation of C1 hydroxyl moieties on chitooligosaccharides and in this way displays a different substrate preference as compared to other known oligosaccharide oxidases. ChitO was identified in the genome of Fusarium graminearum and a structural model revealed that one active site residue (Q268) was likely to be involved in the recognition of the N-acetyl moiety on the chitooligosaccharide substrates. The substrate specificity of wild type ChitO and the Q268R mutant were examined and confirmed that Q268 is indeed involved in N-acetyl recognition.     

Leishmania major thialysine Nepsilon-acetyltransferase: identification of amino acid residues crucial for substrate binding

Thialysine N(epsilon)-acetyltransferases and spermidine/spermine N-acetyltransferases (SSAT) are closely related members of the GCN5-related N-acetyltransferase superfamily. Accordingly, a putative orthologue from the human protozoan parasite Leishmania major exhibits an almost equal similarity to human SSAT and thialysine N(epsilon)-acetyltransferase. Characterisation of the recombinantly expressed L. major protein indicated that it represents a thialysine N(epsilon)-acetyltransferase, preferring thialysine (S-aminoethyl-l-cysteine) and structurally related amino acids as acceptor molecules. The known thialysine N(epsilon)-acetyltransferases contain five conserved amino acid residues that are replaced in SSAT sequences. Kinetic analyses of the respective recombinant mutant proteins suggest that Ser(82) and Thr(83) of L. major thialysine N(epsilon)-acetyltransferase are key residues for acceptor binding. In addition, the conserved Leu(130) is tentatively involved in specific interaction with the sulphur-containing side chain of thialysine. The presence of these three amino acid residues is suggested to be a means by which thialysine N(epsilon)-acetyltransferases can be distinguished from SSAT sequences.     

Site-directed mutagenesis of a potential catalytic and formyl phosphate binding site and substrate inhibition of N10-formyltetrahydrofolate synthetase

Structural studies of N(10)-formyltetrahydrofolate synthetase (FTHFS) have indicated the involvement of Arg 97 in the binding of the formyl phosphate intermediate. Two site-directed mutants were constructed to test this hypothesis: R97S (Ser substitution) and R97E (Glu substitution). The k(cat) of R97S was approximately 60% that of the wild-type enzyme and had K(m) for ATP and formate twofold higher than those of wild type. R97E was completely inactive and had a K(m) for ATP nearly six times that of wild type. Substrate inhibition by tetrahydrofolate was shown to occur in wild-type and R97S enzymes using both steady-state and transient-state kinetic approaches. These results lend greater insight into the mechanistic function of FTHFS by confirming the interaction of both ATP and formate with Arg 97 and introducing the aspect of substrate inhibition by tetrahydrofolate with regard to substrate binding and dissociation.     

Enhanced germination under high-salt conditions of seeds of transgenicArabidopsis with a bacterial gene (codA) for choline oxidase

Arabidopsis thaliana was transformed previously with thecodA gene from the soil bacteriumArthrobacter globiformis. This gene encodes choline oxidase, the enzyme that converts choline to glycinebetaine. Transformation with thecodA gene significantly enhanced the tolerance of transgenic plants to low temperature and high-salt stress. We report here that seeds of transgenic plants that expressed thecodA gene were also more tolerant to salt stress during germination than seeds of non-transformed wild-type plants. Seedlings of transgenic plants grew more rapidly than those of wild-type plants under salt-stress conditions. Furthermore, exogenously applied glycinebetaine was effective in alleviating the harmful effects of salt stress during germination of seeds and growth of young seedlings, a result that suggests that it was glycinebetaine that had enhanced the tolerance of the transgenic plants. These observations indicate that synthesis of glycinebetaine in transgenic plantsin vivo, as a result of the expression of thecodA gene, might be veryuseful in improving the ability of crop plants to tolerate salt stress. The extended abstract of a paper presented at the 13th International Symposium in Conjugation with Award of the International Prize for Biology “Frontier of Plant Biology”     

Mutation of active site residues in the chitin-binding domain ChBDChiA1 from chitinase A1 of Bacillus circulans alters substrate specificity: use of a green fluorescent protein binding assay

A fluorescent binding assay was developed to investigate the effects of mutagenesis on the binding affinity and substrate specificity of the chitin-binding domain of chitinase A1 from Bacillus circulans WL-12. The chitin-binding domain was genetically fused to the N-terminus of a green fluorescent protein, and the polyhistidine-tagged hybrid protein was expressed in Escherichia coli. Residues likely to be involved in the binding site were mutated and their contributions to binding and substrate specificity were evaluated by affinity electrophoresis and depletion assays. The experimental binding isotherms were analyzed by non-linear regression using a modified Langmuir equation. Non-conservative substitution of tryptophan residue (W687) nearly abolished chitin-binding affinity and dramatically lowered chitosan binding while retaining the original level of curdlan binding. Double mutation E668K/P689A had altered specificity for several substrates and also impaired chitin binding significantly. Other substitutions in the binding site altered substrate specificity but had little effect on overall affinity for chitin. Interestingly, mutation T682A led to a higher specificity towards chitinous substrates than the wildtype. Furthermore, the ChBD-GFP hybrid protein was tested for use in diagnostic staining of cell walls of fungi and yeast and for the detection of fungal infections in tissue samples.     

Inhibition of murine N1-acetylated polyamine oxidase by an acetylenic amine and the allenic amine, MDL 72527

Murine N¹-acetylated polyamine oxidase (mPAO) was treated with N,N′-bis-(prop-2-ynyl)-1,4-diaminobutane, a poor substrate and inhibitor for the enzyme, with K_m and K_i values in the millimolar range. Apparently, its oxidation produces prop-2-ynal, which reacts with amino acyl nucleophiles. Using a steady-state kinetic assay, four phases were identified, the first being the oxidation of the compound via Michealis-Menten-type kinetics. As prop-2-ynal accumulates, there is a biphasic reduction in the rate. This process leads to an mPAO form that is nearly inactive (fourth phase), but displays classical Michealis-Menten-type kinetics. The enzyme-bound flavin is not modified in this process. In contrast, micromolar concentrations of the MDL 72527 (N,N′-bis-[buta-2,3-dienyl]-1,4-diaminobutane) inhibited mPAO rapidly and completely. It inhibits by first binding tightly and apparently irreversibly, and then slowly converts to a species where the inhibitor is covalently bound to the N5-position of the flavin’s isoalloxazine ring. The covalent adduct was identified as a flavocyanine.     

The crystal structure of the cytosolic exopolyphosphatase from Saccharomyces cerevisiae reveals the basis for substrate specificity

Inorganic long-chain polyphosphate is a ubiquitous linear polymer in biology, consisting of many phosphate moieties linked by phosphoanhydride bonds. It is synthesized by polyphosphate kinase, and metabolised by a number of enzymes, including exo- and endopolyphosphatases. The Saccharomyces cerevisiae gene PPX1 encodes for a 45 kDa, metal-dependent, cytosolic exopolyphosphatase that processively cleaves the terminal phosphate group from the polyphosphate chain, until inorganic pyrophosphate is all that remains. PPX1 belongs to the DHH family of phosphoesterases, which includes: family-2 inorganic pyrophosphatases, found in Gram-positive bacteria; prune, a cyclic AMPase; and RecJ, a single-stranded DNA exonuclease. We describe the high-resolution X-ray structures of yeast PPX1, solved using the multiple isomorphous replacement with anomalous scattering (MIRAS) technique, and its complexes with phosphate (1.6 A), sulphate (1.8 A) and ATP (1.9 A). Yeast PPX1 folds into two domains, and the structures reveal a strong similarity to the family-2 inorganic pyrophosphatases, particularly in the active-site region. A large, extended channel formed at the interface of the N and C-terminal domains is lined with positively charged amino acids and represents a conduit for polyphosphate and the site of phosphate hydrolysis. Structural comparisons with the inorganic pyrophosphatases and analysis of the ligand-bound complexes lead us to propose a hydrolysis mechanism. Finally, we discuss a structural basis for substrate selectivity and processivity.     

The transglutaminase activating metalloprotease inhibitor from Streptomyces mobaraensis is a glutamine and lysine donor substrate of the intrinsic transglutaminase

Transglutaminase (TGase) from Streptomyces mobaraensis is an extra-cellular enzyme that cross-links proteins to high molecular weight aggregates. Screening for intrinsic substrates now revealed the dual Streptomyces subtilisin inhibitor-like inhibitor Streptomyces subtilisin and transglutaminase activating metalloprotease (TAMEP) inhibitor (SSTI), equally directed against subtilisin and the TGase activating metalloprotease TAMEP, is both a glutamine and a lysine donor protein. Reactivity of glutamines is lost during culture, most likely by TGase mediated deamidation, and, accordingly, cross-linking only occurred if SSTI from early cultures was used. Interestingly, release of buried endo-glutamines by the lipoamino acid N-lauroylsarcosine could restore SSTI reactivity. Formation of lipoamino acids by Streptomycetes suggests such compounds could also modulate in vivo TGase mediated SSTI cross-linking.     

Site-directed mutagenesis of an alkaline phytase: influencing specificity, activity and stability in acidic milieu

Site-directed mutagenesis of a thermostable alkaline phytase from Bacillus sp. MD2 was performed with an aim to increase its specific activity and activity and stability in an acidic environment. The mutation sites are distributed on the catalytic surface of the enzyme (P257R, E180N, E229V and S283R) and in the active site (K77R, K179R and E227S). Selection of the residues was based on the idea that acid active phytases are more positively charged around their catalytic surfaces. Thus, a decrease in the content of negatively charged residues or an increase in the positive charges in the catalytic region of an alkaline phytase was assumed to influence the enzyme activity and stability at low pH. Moreover, widening of the substrate-binding pocket is expected to improve the hydrolysis of substrates that are not efficiently hydrolysed by wild type alkaline phytase. Analysis of the phytase variants revealed that E229V and S283R mutants increased the specific activity by about 19% and 13%, respectively. Mutation of the active site residues K77R and K179R led to severe reduction in the specific activity of the enzyme. Analysis of the phytase mutant-phytate complexes revealed increase in hydrogen bonding between the enzyme and the substrate, which might retard the release of the product, resulting in decreased activity. On the other hand, the double mutant (K77R-K179R) phytase showed higher stability at low pH (pH 2.6-3.0). The E227S variant was optimally active at pH 5.5 (in contrast to the wild type enzyme that had an optimum pH of 6) and it exhibited higher stability in acidic condition. This mutant phytase, displayed over 80% of its initial activity after 3 h incubation at pH 2.6 while the wild type phytase retained only about 40% of its original activity. Moreover, the relative activity of this mutant phytase on calcium phytate, sodium pyrophosphate and p-nitro phenyl phosphate was higher than that of the wild type phytase.     

Substrate specificity,de novo synthesis and partial purification of polyphenol oxidase derived from the wood-decay fungus,Coriolus versicolor

Summary Coriolus versicolor, a white-rot Basidiomycete, secretes cellulolytic and ligninolytic enzymes as well as polyphenol oxidase (PPO). Whereas the former degrade wood polymers, the latter can convert diphenols to diquinones and oligomerize syringic acid, a lignin derivative. Certain phenolic compounds can serve as disease-resistance factors controlling the proliferation of wood-decay fungi within host tissues. BecauseC. vesicolor can be batch-cultured, overproduction and enhanced secretion of enzymes of biological and commercial interests are feasible. Reported here are the results of attempts to define the timed appearances of intracellular and extracellular PPO, to assess substrate specificity as well as distinguish synthesis versus activation of intracellular PPO and to partially purify extracellular PPO. These efforts were to provide data enabling cell-free synthesis of PPO, cloning of the gene(s) for the oxidase and the establishment of its subcellular route of secretion. Whereas two protein peaks (6 and 12 days in a 16 day time-course) were observed for dialyzed mycelial homogenates, the homogenates' PPO specific activity rose between 4 and 12 days and then declined. Total extracellular protein content climbed from 6 to 15 days for dialyzed growth medium and the medium's PPO specific activity rose at 4 days post-inoculation and except at 9 days increased linearly to 15 days. When aliquots of dialyzed 12 and 15 day media were added to PPO assay mixtures containing catechol and either syringic or gallic acids, statistically significant differences in PPO specific activity between phenolic substrates were noted. Supplementation of cultures with 1.91 g cycloheximide ml growth medium^–1 (control, growth medium only) together with 0.5 Ci [¹⁴C]-leucine revealed that cycloheximide inhibited PPO activity and suppressed [¹⁴C]-leucine incorporation into TCA-insoluble cytoplasmic protein. As for PPO partial purification, growth medium dialysis followed by 0–30% (NH₄)₂SO₄ fractionation and subsequent 12 000×g dialyzate centrifugation yielded a 3.27-fold enhancement in PPO specific activity within the 12 000×g supernatant. Chromatography of the latter upon DEAE-Sephadex indicated that PPO exchanged with the DEAE counterion as it could be eluted with high ionic strength salt. These results suggest that: the occurrences of intracellular and extracellular PPO are time-dependent, intracellular PPO is de novo synthesized, the preferred substrate for extracellular PPO appears to be catechol and extracellular PPO can be partially purified by a combination of dialysis and ammonium sulfate fractionation as well as possibly DEAE chromatography and/or Sephadex G-150 gel filtration.     

A single mutation in the active site swaps the substrate specificity of N-acetyl-L-ornithine transcarbamylase and N-succinyl-L-ornithine transcarbamylase

Transcarbamylases catalyze the transfer of the carbamyl group from carbamyl phosphate (CP) to an amino group of a second substrate such as aspartate, ornithine, or putrescine. Previously, structural determination of a transcarbamylase from Xanthomonas campestris led to the discovery of a novel N-acetylornithine transcarbamylase (AOTCase) that catalyzes the carbamylation of N-acetylornithine. Recently, a novel N-succinylornithine transcarbamylase (SOTCase) from Bacteroides fragilis was identified. Structural comparisons of AOTCase from X. campestris and SOTCase from B. fragilis revealed that residue Glu92 (X. campestris numbering) plays a critical role in distinguishing AOTCase from SOTCase. Enzymatic assays of E92P, E92S, E92V, and E92A mutants of AOTCase demonstrate that each of these mutations converts the AOTCase to an SOTCase. Similarly, the P90E mutation in B. fragilis SOTCase (equivalent to E92 in X. campestris AOTCase) converts the SOTCase to AOTCase. Hence, a single amino acid substitution is sufficient to swap the substrate specificities of AOTCase and SOTCase. X-ray crystal structures of these mutants in complexes with CP and N-acetyl-L-norvaline (an analog of N-acetyl-L-ornithine) or N-succinyl-L-norvaline (an analog of N-succinyl-L-ornithine) substantiate this conversion. In addition to Glu92 (X. campestris numbering), other residues such as Asn185 and Lys30 in AOTCase, which are involved in binding substrates through bridging water molecules, help to define the substrate specificity of AOTCase. These results provide the correct annotation (AOTCase or SOTCase) for a set of the transcarbamylase-like proteins that have been erroneously annotated as ornithine transcarbamylase (OTCase, EC 2.1.3.3).     

Evolution of putrescine N-methyltransferase from spermidine synthase demanded alterations in substrate binding

Putrescine N-methyltransferase (PMT) catalyses S-adenosylmethionine (SAM)-dependent methylation of putrescine in tropane alkaloid biosynthesis. PMT presumably evolved from the ubiquitous spermidine synthase (SPDS). SPDS protein structure suggested that only few amino acid exchanges in the active site were necessary to achieve PMT activity. Protein modelling, mutagenesis, and chimeric protein construction were applied to trace back evolution of PMT activity from SPDS. Ten amino acid exchanges in Datura stramonium SPDS dismissed the hypothesis of facile generation of PMT activity in existing SPDS proteins. Chimeric PMT and SPDS enzymes were active and indicated the necessity for a different putrescine binding site when PMT developed.     

Cytochrome c reactivity in its complexes with mammalian cytochrome c oxidase and yeast peroxidase

1.

1. The ascorbate reducibility of cytochrome c (beef or horse heart) in its complexes with cytochrome c oxidase (beef heart) and cytochrome c peroxidase (yeast) has been studied.