Complex structures of Thermoactinomyces vulgaris R-47 alpha-amylase 1 with malto-oligosaccharides demonstrate the role of domain N acting as a starch-binding domain

The X-ray structures of complexes of Thermoactinomyces vulgaris R-47 alpha-amylase 1 (TVAI) with an inhibitor acarbose and an inactive mutant TVAI with malto-hexaose and malto-tridecaose have been determined at 2.6, 2.0 and 1.8A resolution, and the structures have been refined to R-factors of 0.185 (R(free)=0.225), 0.184 (0.217) and 0.164 (0.200), respectively, with good chemical geometries. Acarbose binds to the catalytic site of TVAI, and interactions between acarbose and the enzyme are very similar to those found in other structure-solved alpha-amylase/acarbose complexes, supporting the proposed catalytic mechanism. Based on the structure of the TVAI/acarbose complex, the binding mode of pullulan containing alpha-(1,6) glucoside linkages could be deduced. Due to the structural difference caused by the replaced amino acid residue (Gln396 for Glu) in the catalytic site, malto-hexaose and malto-tridecaose partially bind to the catalytic site, giving a mimic of the enzyme/product complex. Besides the catalytic site, four sugar-binding sites on the molecular surface are found in these X-ray structures. Two sugar-binding sites in domain N hold the oligosaccharides with a regular helical structure of amylose, which suggests that the domain N is a starch-binding domain acting as an anchor to starch in the catalytic reaction of the enzyme. An assay of hydrolyzing activity for the raw starches confirmed that TVAI can efficiently hydrolyze raw starch.     

Probing the role of a mobile loop in substrate binding and enzyme activity of human salivary amylase

Mammalian amylases harbor a flexible, glycine-rich loop 304GHGAGGA(310), which becomes ordered upon oligosaccharide binding and moves in toward the substrate. In order to probe the role of this loop in catalysis, a deletion mutant lacking residues 306-310 (Delta306) was generated. Kinetic studies showed that Delta306 exhibited: (1) a reduction (>200-fold) in the specific activity using starch as a substrate; (2) a reduction in k(cat) for maltopentaose and maltoheptaose as substrates; and (3) a twofold increase in K(m) (maltopentaose as substrate) compared to the wild-type (rHSAmy). More cleavage sites were observed for the mutant than for rHSAmy, suggesting that the mutant exhibits additional productive binding modes. Further insight into its role is obtained from the crystal structures of the two enzymes soaked with acarbose, a transition-state analog. Both enzymes modify acarbose upon binding through hydrolysis, condensation or transglycosylation reactions. Electron density corresponding to six and seven fully occupied subsites in the active site of rHSAmy and Delta306, respectively, were observed. Comparison of the crystal structures showed that: (1) the hydrophobic cover provided by the mobile loop for the subsites at the reducing end of the rHSAmy complex is notably absent in the mutant; (2) minimal changes in the protein-ligand interactions around subsites S1 and S1', where the cleavage would occur; (3) a well-positioned water molecule in the mutant provides a hydrogen bond interaction similar to that provided by the His305 in rHSAmy complex; (4) the active site-bound oligosaccharides exhibit minimal conformational differences between the two enzymes. Collectively, while the kinetic data suggest that the mobile loop may be involved in assisting the catalysis during the transition state, crystallographic data suggest that the loop may play a role in the release of the product(s) from the active site.     

Probing the role of aromatic residues at the secondary saccharide-binding sites of human salivary alpha-amylase in substrate hydrolysis and bacterial binding

Human salivary α-amylase (HSAmy) has three distinct functions relevant to oral health: (1) hydrolysis of starch, (2) binding to hydroxyapatite (HA), and (3) binding to bacteria (e.g., viridans streptococci). Although the active site of HSAmy for starch hydrolysis is well-characterized, the regions responsible for bacterial binding are yet to be defined. Since HSAmy possesses several secondary saccharide-binding sites in which aromatic residues are prominently located, we hypothesized that one or more of the secondary saccharide-binding sites harboring the aromatic residues may play an important role in bacterial binding. To test this hypothesis, the aromatic residues at five secondary binding sites were mutated to alanine to generate six mutants representing either single (W203A, Y276A, and W284A), double (Y276A/W284A and W316A/W388A), or multiple [W134A/W203A/Y276A/W284A/W316A/W388A; human salivary α-amylase aromatic residue multiple mutant (HSAmy-ar)] mutations. The crystal structure of HSAmy-ar as an acarbose complex was determined at a resolution of 1.5 Å and compared with the existing wild-type acarbose complex. The wild-type and the mutant enzymes were characterized for their abilities to exhibit enzyme activity, starch-binding activity, HA-binding activity, and bacterial binding activity. Our results clearly showed that (1) mutation of aromatic residues does not alter the overall conformation of the molecule; (2) single or double mutants showed either moderate or minimal changes in both starch-binding activity and bacterial binding activity, whereas HSAmy-ar showed significant reduction in these activities; (3) starch-hydrolytic activity was reduced by 10-fold in HSAmy-ar; (4) oligosaccharide-hydrolytic activity was reduced in all mutants, but the action pattern was similar to that of the wild-type enzyme; and (5) HA binding was unaffected in HSAmy-ar. These results clearly show that the aromatic residues at the secondary saccharide-binding sites in HSAmy play a critical role in bacterial binding and in starch-hydrolytic functions of HSAmy.     

Structural basis for the alteration of coenzyme specificity in a malate dehydrogenase mutant

To elucidate the structural basis for the alteration of coenzyme specificity from NADH toward NADPH in a malate dehydrogenase mutant EX7 from Thermus flavus, we determined the crystal structures at 2.0 A resolution of EX7 complexed with NADPH and NADH, respectively. In the EX7-NADPH complex, Ser42 and Ser45 form hydrogen bonds with the 2'-phosphate group of the adenine ribose of NADPH, although the adenine moiety is not seen in the electron density map. In contrast, although Ser42 and Ser45 occupy a similar position in the EX7-NADH complex structure, both the adenine and adenine ribose moieties of NADH are missing in the map. These results and kinetic analysis of site-directed mutant enzymes indicate (1) that the preference of EX7 for NADPH over NADH is ascribed to the recognition of the 2'-phosphate group by two Ser and Arg44, and (2) that the adenine moiety of NADPH is not recognized in this mutant.     

Structural basis for branching-enzyme activity of glycoside hydrolase family 57: structure and stability studies of a novel branching enzyme from the hyperthermophilic archaeon Thermococcus kodakaraensis KOD1

Branching enzymes (BEs) catalyze the formation of branch points in glycogen and amylopectin by cleavage of α-1,4 glycosidic bonds and subsequent transfer to a new α-1,6 position. BEs generally belong to glycoside hydrolase family 13 (GH13); however TK1436, isolated from the hyperthermophilic archaeon Thermococcus kodakaraensis KOD1, is the first GH57 member, which possesses BE activity. To date, the only BE structure that had been determined is a GH13-type from Escherichia coli. Herein, we have determined the crystal structure of TK1436 in the native state and in complex with glucose and substrate mimetics that permitted mapping of the substrate-binding channel and identification of key residues for glucanotransferase activity. Its structure encompasses a distorted (β/α)(7)-barrel juxtaposed to a C-terminal α-helical domain, which also participates in the formation of the active-site cleft. The active site comprises two acidic catalytic residues (Glu183 and Asp354), the polarizer His10, aromatic gate-keepers (Trp28, Trp270, Trp407, and Trp416) and the residue Tyr233, which is fully conserved among GH13- and GH57-type BEs. Despite TK1436 displaying a completely different fold and domain organization when compared to E. coli BE, they share the same structural determinants for BE activity. Structural comparison with AmyC, a GH57 α-amylase devoid of BE activity, revealed that the catalytic loop involved in substrate recognition and binding, is shortened in AmyC structure and it has been addressed as a key feature for its inability for glucanotransferase activity. The oligomerization has also been pointed out as a possible determinant for functional differentiation among GH57 members.     

A P-loop-like motif in a widespread ATP pyrophosphatase domain: Implications for the evolution of sequence motifs and enzyme activity

A conserved amino acid sequence motif was identified in four distinct groups of enzymes that catalyze the hydrolysis of the α–β phosphate bond of ATP, namely GMP synthetases, argininosuccinate synthetases, asparagine synthetases, and ATP sulfurylases. The motif is also present in Rhodobacter capsulata AdgA, Escherichia coli NtrL, and Bacillus subtilis OutB, for which no enzymatic activities are currently known. The observed pattern of amino acid residue conservation and predicted secondary structures suggest that this motif may be a modified version of the P-loop of nucleotide binding domains, and that it is likely to be involved in phosphate binding. We call it PP-motif, since it appears to be a part of a previously uncharacterized ATP pyrophophatase domain. ATP sulfurylases, NtrL, and OutB consist of this domain alone. In other proteins, the pyrophosphatase domain is associated with amidotransferase domains (type I or type II), a putative citrulline-aspartate ligase domain or a nitrilase/amidase domain. Unexpectedly, statistically significant overall sequence similarity was found between ATP sulfurylase and 3′-phosphoadenosine 5′-phosphosulfate (PAPS) reductase, another protein of the sulfate activation pathway. The PP-motif is strongly modified in PAPS reductases, but they share with ATP sulfurylases another conserved motif which might be involved in sulfate binding. We propose that PAPS reductases may have evolved from ATP sulfurylases; the evolution of the new enzymatic function appears to be accompanied by a switch of the strongest functional constraint from the PP-motif to the putative sulfate-binding motif. © 1994 Wiley-Liss, Inc.     

Recognition dynamics of dopamine to human Monoamine oxidase B: role of Leu171/Gln206 and conserved water molecules in the active site cavity

The human Monoamine oxidase (hMAO) metabolizes several biogenic amine neurotransmitters and is involved in different neurological disorders. Extensive MD simulation studies of dopamine-docked hMAO B structures have revealed the stabilization of amino-terminal of the substrate by a direct and water-mediated interaction of catalytic tyrosines, Gln206, and Leu171 residues. The catechol ring of the substrate is stabilized by Leu171(C–H)?π(Dop)?(H–C) Ile199 interaction. Several conserved water molecules are observed to play a role in the recognition of substrate to the enzyme, where W1 and W2 associate in dopamine– FAD interaction, reversible dynamics of W3 and W4 influenced the coupling of Tyr435 to Trp432 and FAD, and W5 and W8 stabilized the catalytic Tyr188/398 residues. The W6, W7, and W8 water centers are involved in the recognition of catalytic residues and FAD with the N⁺- site of dopamine through hydrogen bonding interaction. The recognition of substrate to gating residues is made through W9, W10, and W11 water centers. Beside the interplay of water molecules, the catalytic aromatic cage has also been stabilized by π?water, π?C–H, and π?π interactions. The topology of conserved water molecular sites along with the hydration dynamics of catalytic residues, FAD, and dopamine has added a new feature on the substrate binding chemistry in hMAO B which may be useful for substrate analog inhibitor design.     

Mutational analysis of the Trypanosoma vivax alternative oxidase: the E(X)6Y motif is conserved in both mitochondrial alternative oxidase and plastid terminal oxidase and is indispensable for enzyme activity

Based on amino acid sequence similarity and the ability to catalyze the four-electron reduction of oxygen to water using a quinol substrate, mitochondrial alternative oxidase (AOX) and plastid terminal oxidase (PTOX) appear to be two closely related members of the membrane-bound diiron carboxylate group of proteins. In the current studies, we took advantage of the high activity of Trypanosoma vivax AOX (TvAOX) to examine the importance of the conserved Glu and the Tyr residues around the predicted third helix region of AOXs and PTOXs. We first compared the amino acid sequences of TvAOX with AOXs and PTOXs from various taxa and then performed alanine-scanning mutagenesis of TvAOX between amino acids Y(199) and Y(247). We found that the ubiquinol oxidase activity of TvAOX is completely lost in the E214A mutant, whereas mutants E215A and E216A retained more than 30% of the wild-type activity. Among the Tyr mutants, a complete loss of activity was also observed for the Y221A mutant, whereas the activities were equivalent to wild-type for the Y199A, Y212A, and Y247A mutants. Finally, residues Glu(214) and Tyr(221) were found to be strictly conserved among AOXs and PTOXs. Based on these findings, it appears that AOXs and PTOXs are a novel subclass of diiron carboxylate proteins that require the conserved motif E(X)(6)Y for enzyme activity.     

Nutrients and water availability constrain the seasonality of vegetation activity in a Mediterranean ecosystem

Anthropogenic nitrogen (N) deposition and resulting differences in ecosystem N and phosphorus (P) ratios are expected to impact photosynthetic capacity, that is, maximum gross primary productivity (GPP_max). However, the interplay between N and P availability with other critical resources on seasonal dynamics of ecosystem productivity remains largely unknown. In a Mediterranean tree–grass ecosystem, we established three landscape‐level (24 ha) nutrient addition treatments: N addition (NT), N and P addition (NPT), and a control site (CT). We analyzed the response of ecosystem to altered nutrient stoichiometry using eddy covariance fluxes measurements, satellite observations, and digital repeat photography. A set of metrics, including phenological transition dates (PTDs; timing of green‐up and dry‐down), slopes during green‐up and dry‐down period, and seasonal amplitude, were extracted from time series of GPP_max and used to represent the seasonality of vegetation activity. The seasonal amplitude of GPP_max was higher for NT and NPT than CT, which was attributed to changes in structure and physiology induced by fertilization. PTDs were mainly driven by rainfall and exhibited no significant differences among treatments during the green‐up period. Yet, both fertilized sites senesced earlier during the dry‐down period (17–19 days), which was more pronounced in the NT due to larger evapotranspiration and water usage. Fertilization also resulted in a faster increase in GPP_max during the green‐up period and a sharper decline in GPP_max during the dry‐down period, with less prominent decline response in NPT. Overall, we demonstrated seasonality of vegetation activity was altered after fertilization and the importance of nutrient–water interaction in such water‐limited ecosystems. With the projected warming‐drying trend, the positive effects of N fertilization induced by N deposition on GPP_max may be counteracted by an earlier and faster dry‐down in particular in areas where the N:P ratio increases, with potential impact on the carbon cycle of water‐limited ecosystems.     

Generation of a homology model for the human cytochrome P450, CYP24A1, and the testing of putative substrate binding residues by site-directed mutagenesis and enzyme activity studies

A systematic analysis of conserved H-bonding patterns and tertiary structural motifs from 13 crystal structures was used to create a homology model for the human multicatalytic cytochrome P450, CYP24A1, involved in catabolism of 1alpha,25-dihydroxyvitamin D3. The substrate was docked in the active site and used to identify potential substrate contact residues in the B' helix, B'/C loop, F-helix and the beta-5 hairpin. Seven CYP24A1 mutants were created and studied by mammalian cell transfection and CYP24A1 activity assay. Mutants showed reduced metabolic rates and altered metabolite patterns compared to wild-type. We conclude that: Ile-131 positions substrate via A-ring and cis-triene contacts; Trp-134 and Gly-499 are determinants of substrate access; Leu-148 contacts the substrate side-chain; Met-246 is important in mediating regioselectivity. Our findings validate the new model of CYP24A1, which can now be used to predict structural modifications for rational vitamin D drug design.     

Evidence for a single active site in the human angiotensin I-converting enzyme from inhibitor binding studies with [3H] RU 44 403: role of chloride

Binding of the potent radiolabelled competitive inhibitor 3H RU 44403 to pure human kidney angiotensin-I converting enzyme was examined in equilibrium and non equilibrium conditions. Equilibrium dialysis experiments indicate that, despite the duplicated structure of the enzyme and the presence of two putative active sites, 3H RU 44403 interacts with a single high affinity (Kd = 0.44 +/- 0.05 x 10-9 M, n = 3) binding site. This suggests that only one of the two putative active sites is functional, and can bind substrates or inhibitors. Sodium chloride plays an essential role in the enzyme-inhibitor interaction. The formation of the complex is only slightly influenced by NaCl, but the kinetic of dissociation is dramatically dependent on NaCl concentration. In a Nacl free medium the complex is unstable and dissociates rapidly. These results are consistent with the hypothesis that chloride ion influences isomerization of the complex toward a more stable form.     

Interaction between separated consecutive complement control modules of human C1r: implications for dimerization of the full-length protease

Complement control protein modules (CCP) typically mediate protein:protein interaction during immune response in vertebrates. Using NMR chemical shift perturbation mapping, we present previously lacking experimental evidence for intermolecular interactions between the CCP1 and CCP2 modules of the human C1r serine protease (SP). The identified interface is clearly distinct from that observed in the covalently linked CCP1-CCP2 pair. Structural models of the CCP1-CCP2-SP segments of two C1r molecules built on the basis of shift perturbation data are fully consistent with an extended interaction interface and suggests the possibility of a structural rearrangement as a switch between functional states of human C1r.

Structured summary

MINT-8045767: CCP1 (uniprotkb:P00736) and CCP2 (uniprotkb:P00736) bind (MI:0407) by nuclear magnetic resonance (MI:0077)     

Structural preference for changes in the direction of the Ca2+-induced transition: a study of the regulatory domain of skeletal troponin-C

The determinants for specificity in the Ca(2+)-dependent response of the regulatory N-terminal domain of skeletal troponin-C are a combination of intrinsic and induced properties. We characterized computationally the intrinsic propensity of this domain for structural changes similar to those observed experimentally in the Ca(2+)-induced transition. The preference for such changes was assessed by comparing the structural effect of the harmonic and quasiharmonic vibrations specific for each Ca(2+) occupancy with crystallographic data. Results show that only the Ca(2+)-saturated form of the protein features a slow vibrational motion preparatory for the transition. From the characteristics of this mode, we identified a molecular mechanism for transition, by which residues 42-51 of helix B and of the adjacent linker move toward helices (A, D), and bind to the surface used by the protein to interact with troponin-I. By obstructing the access of the target to hydrophobic residues important in the formation of the complex, helix B and the adjacent linker act as an autoinhibitory structural element. Specific properties of the methionines at the interaction surface were found to favor the binding of the autoinhibitory region. Located over hydrophobic residues critical for binding, the methionines are easily displaceable to increase the accessibility of these residues to molecular encounter.