Protein structural change upon ligand binding correlates with enzymatic reaction mechanism

Overall structural changes of enzymes in response to ligand binding were investigated by database analysis of 62 non-redundant enzymes whose ligand-unbound and ligand-bound forms were available in the Protein Data Bank. The results of analysis indicate that transferases often undergo large rigid-body domain motions upon ligand binding, while other enzymes, most typically, hydrolases, change their structures to a small extent. It was also found that the solvent accessibility of the substrate molecule was low in transferases but high in hydrolases. These differences are explained by the enzymatic reaction mechanisms. The transferase reaction requires the catalytic groups to be insulated from the water environment, and thus transferases bury the ligand molecule inside the protein by closing the cleft. On the other hand, the hydrolase reaction involves the surrounding water molecules and occurs at the protein surface, requiring only a small structural change.     

Alteration of oligomeric state and domain architecture is essential for functional transformation between transferase and hydrolase with the same scaffold

Transferases and hydrolases catalyze different chemical reactions and express different dynamic responses upon ligand binding. To insulate the ligand molecule from the surrounding water, transferases bury it inside the protein by closing the cleft, while hydrolases undergo a small conformational change and leave the ligand molecule exposed to the solvent. Despite these distinct ligand‐binding modes, some transferases and hydrolases are homologous. To clarify how such different catalytic modes are possible with the same scaffold, we examined the solvent accessibility of ligand molecules for 15 SCOP superfamilies, each containing both transferase and hydrolase catalytic domains. In contrast to hydrolases, we found that nine superfamilies of transferases use two major strategies, oligomerization and domain fusion, to insulate the ligand molecules. The subunits and domains that were recruited by the transferases often act as a cover for the ligand molecule. The other strategies adopted by transferases to insulate the ligand molecule are the relocation of catalytic sites, the rearrangement of secondary structure elements, and the insertion of peripheral regions. These findings provide insights into how proteins have evolved and acquired distinct functions with a limited number of scaffolds.     

Structural insights into the specific recognition of N‐heterocycle biodenitrogenation‐derived substrates by microbial amide hydrolases

N‐heterocyclic compounds from industrial wastes, including nicotine, are environmental pollutants or toxicants responsible for a variety of health problems. Microbial biodegradation is an attractive strategy for the removal of N‐heterocyclic pollutants, during which carbon–nitrogen bonds in N‐heterocycles are converted to amide bonds and subsequently severed by amide hydrolases. Previous studies have failed to clarify the molecular mechanism through which amide hydrolases selectively recognize diverse amide substrates and complete the biodenitrogenation process. In this study, structural, computational and enzymatic analyses showed how the N‐formylmaleamate deformylase Nfo and the maleamate amidase Ami, two pivotal amide hydrolases in the nicotine catabolic pathway of Pseudomonas putida S16, specifically recognize their respective substrates. In addition, comparison of the α‐β‐α groups of amidases, which include Ami, pinpointed several subgroup‐characteristic residues differentiating the two classes of amide substrates as containing either carboxylate groups or aromatic rings. Furthermore, this study reveals the molecular mechanism through which the specially tailored active sites of deformylases and amidases selectively recognize their unique substrates. Our work thus provides a thorough elucidation of the molecular mechanism through which amide hydrolases accomplish substrate‐specific recognition in the microbial N‐heterocycles biodenitrogenation pathway.     

Structural and Functional Comparison of Polysaccharide-Degrading Enzymes

Sugar molecules as well as enzymes degrading them are ubiquitously present in physiological systems, especially for vertebrates. Polysaccharides have at least two aspects to their function, one due to their mechanical properties and the second one involves multiple regulatory processes or interactions between molecules, cells, or extracellular space. Various bacteria exert exogenous pressures on their host organism to diversity glycans and their structures in order for the host organism to evade the destructive function of such microbes. Many bacterial organism produce glycan-degrading enzymes in order to facilitate their invasion of host tissues. Such polysaccharide degrading enzymes utilize mainly two modes of polysaccharide-degradation, a hydrolysis and a β-elimination process. The three-dimensional structures of several of these enzymes have been elucidated recently using X-ray crystallography. There are many common structural motifs among these enzymes, mainly the presence of an elongated cleft transversing these molecules which functions as a polysaccharide substrate binding site as well as the catalytic site for these enzymes. The detailed structural information obtained about these enzymes allowed formulation of proposed mechanisms of their action. The polysaccharide lyases utilize a proton acceptance and donation mechanism (PAD), whereas polysaccharide hydrolases use a direct double displacement (DD) mechanism to degrade their substrates.     

Structural and functional comparison of polysaccharide-degrading enzymes

Sugar molecules as well as enzymes degrading them are ubiquitously present in physiological systems, especially for vertebrates. Polysaccharides have at least two aspects to their function, one due to their mechanical properties and the second one involves multiple regulatory processes or interactions between molecules, cells, or extracellular space. Various bacteria exert exogenous pressures on their host organism to diversity glycans and their structures in order for the host organism to evade the destructive function of such microbes. Many bacterial organism produce glycan-degrading enzymes in order to facilitate their invasion of host tissues. Such polysaccharide degrading enzymes utilize mainly two modes of polysaccharide-degradation, a hydrolysis and a beta-elimination process. The three-dimensional structures of several of these enzymes have been elucidated recently using X-ray crystallography. There are many common structural motifs among these enzymes, mainly the presence of an elongated cleft transversing these molecules which functions as a polysaccharide substrate binding site as well as the catalytic site for these enzymes. The detailed structural information obtained about these enzymes allowed formulation of proposed mechanisms of their action. The polysaccharide lyases utilize a proton acceptance and donation mechanism (PAD), whereas polysaccharide hydrolases use a direct double displacement (DD) mechanism to degrade their substrates.     

Multilevel structural characteristics for the natural substrate proteins of bacterial small heat shock proteins

Small heat shock proteins (sHSPs) are ubiquitous molecular chaperones that prevent the aggregation of various non‐native proteins and play crucial roles for protein quality control in cells. It is poorly understood what natural substrate proteins, with respect to structural characteristics, are preferentially bound by sHSPs in cells. Here we compared the structural characteristics for the natural substrate proteins of Escherichia coli IbpB and Deinococcus radiodurans Hsp20.2 with the respective bacterial proteome at multiple levels, mainly by using bioinformatics analysis. Data indicate that both IbpB and Hsp20.2 preferentially bind to substrates of high molecular weight or moderate acidity. Surprisingly, their substrates contain abundant charged residues but not abundant hydrophobic residues, thus strongly indicating that ionic interactions other than hydrophobic interactions also play crucial roles for the substrate recognition and binding of sHSPs. Further, secondary structure prediction analysis indicates that the substrates of low percentage of β‐sheets or coils but high percentage of α‐helices are un‐favored by both IbpB and Hsp20.2. In addition, IbpB preferentially interacts with multi‐domain proteins but unfavorably with α + β proteins as revealed by SCOP analysis. Together, our data suggest that bacterial sHSPs, though having broad substrate spectrums, selectively bind to substrates of certain structural features. These structural characteristic elements may substantially participate in the sHSP–substrate interaction and/or increase the aggregation tendency of the substrates, thus making the substrates more preferentially bound by sHSPs.     

Truncation of Medicago truncatula Auxin Conjugate Hydrolases Alters Substrate Specificity

We have previously isolated and characterized a family of auxin amino acid conjugate hydrolases from the legume Medicago truncatula. All characterized members of this family possess a conserved second methionine within the predicted hydrolase domain. We therefore constructed 5′-truncated clones of the hydrolases to investigate whether this methionine could have a potential function. Overall, the hydrolases exhibited altered substrate specificities towards a variety of auxin conjugates tested, with a somewhat broadened substrate range. In vitro hydrolase activity increased over wild-type in several of the shortened proteins, but only for some substrates. The 5′ “head” domain may be serving a regulatory function in the full-length versions of the enzymes or could provide a mechanism to broaden the substrate range in vivo.     

Differences in the chitinolytic activity of mammalian chitinases on soluble and insoluble substrates

Chitin is an abundant polysaccharide used by many organisms for structural rigidity and water repulsion. As such, the insoluble crystalline structure of chitin poses significant challenges for enzymatic degradation. Acidic mammalian chitinase, a processive glycosyl hydrolase, is the primary enzyme involved in the degradation of environmental chitin in mammalian lungs. Mutations to acidic mammalian chitinase have been associated with asthma, and genetic deletion in mice increases morbidity and mortality with age. We initially set out to reverse this phenotype by engineering hyperactive acidic mammalian chitinase variants. Using a screening approach with commercial fluorogenic substrates, we identified mutations with consistent increases in activity. To determine whether the activity increases observed were consistent with more biologically relevant chitin substrates, we developed new assays to quantify chitinase activity with insoluble chitin, and identified a one‐pot fluorogenic assay that is sufficiently sensitive to quantify changes to activity due to the addition or removal of a carbohydrate‐binding domain. We show that the activity increases from our directed evolution screen were lost when insoluble substrates were used. In contrast, naturally occurring gain‐of‐function mutations gave similar results with oligomeric and insoluble substrates. We also show that activity differences between acidic mammalian chitinase and chitotriosidase are reduced with insoluble substrate, suggesting that previously reported activity differences with oligomeric substrates may have been driven by differential substrate specificity. These results highlight the need for assays against physiological substrates when engineering metabolic enzymes, and provide a new one‐pot assay that may prove to be broadly applicable to engineering glycosyl hydrolases.     

Alpha-crystallin regions affected by adenosine 5'-triphosphate identified by hydrogen-deuterium exchange

ATP interaction with lens alpha-crystallins leading to enhanced chaperone activity is not yet well understood. One model for chaperone activity of small heat shock proteins proposes that ATP causes small heat shock proteins to release substrates, which are then renatured by other larger heat shock proteins. A similar role has been proposed for ATP in alpha-crystallin chaperone activity. To evaluate this model, ATP-induced structural changes of native human alpha-crystallin assemblies were determined by hydrogen-deuterium exchange. In these experiments, hydrogen-deuterium exchange, measured by mass spectrometry, gave direct evidence that ATP decreases the accessibility of amide hydrogens in multiple regions of both alphaA and alphaB. The surface encompassed by these regions is much larger than would be shielded by a single ATP, implying that multiple ATP molecules bind to each subunit and/or ATP causes a more compact alpha-crystallin structure. Such a conformational change could release a bound substrate. The regions most affected by ATP are near putative substrate binding regions of alphaA and alphaB and in the C-terminal extension of alphaB. The widespread decrease in hydrogen-deuterium exchange with particularly large decreases near substrate binding regions suggests that ATP releases substrates via both direct displacement and a global conformational change.     

Protein motions visualized by femtosecond time-resolved crystallography: The case of photosensory vs photosynthetic proteins

Proteins are dynamic objects and undergo conformational changes when functioning. These changes range from interconversion between states in equilibrium to ultrafast and coherent structural motions within one perturbed state. Time-resolved serial femtosecond crystallography at free-electron X-ray lasers can unravel structural changes with atomic resolution and down to femtosecond time scales. In this review, we summarize recent advances on detecting structural changes for phytochrome photosensor proteins and a bacterial photosynthetic reaction center. In the phytochrome structural changes are extensive and involve major rearrangements of many amino acids and water molecules, accompanying the regulation of its biochemical activity, whereas in the photosynthetic reaction center protein the structural changes are smaller, more localized, and are optimized to facilitate electron transfer along the chromophores. The detected structural motions underpin the proteins’ function, providing a showcase for the importance of detecting ultrafast protein structural dynamics.     

Active-site gorge and buried water molecules in crystal structures of acetylcholinesterase from Torpedo californica

Buried water molecules and the water molecules in the active-site gorge are analyzed for five crystal structures of acetylcholinesterase from Torpedo californica in the resolution range 2.2-2.5 A (native enzyme, and four inhibitor complexes). A total of 45 buried hydration sites are identified, which are populated with between 36 and 41 water molecules. About half of the buried water is located in a distinct region neighboring the active-site gorge. Most of the buried water molecules are very well conserved among the five structures, and have low displacement parameters, B, of magnitudes similar to those of the main-chain atoms of the central beta-sheet structure. The active-site gorge of the native enzyme is filled with over 20 water molecules, which have poor hydrogen-bond coordination with an average of 2.9 polar contacts per water molecule. Upon ligand binding, distinct groups of these water molecules are displaced, whereas the others remain in positions similar to those that they occupy in the native enzyme. Possible roles of the buried water molecules are discussed, including their possible action as a lubricant to allow large-amplitude fluctuations of the loop structures forming the gorge wall. Such fluctuations are required to facilitate traffic of substrate, products and water molecules to and from the active-site. Because of their poor coordination, the gorge water molecules can be considered as "activated" as compared to bulk water. This should allow their easy displacement by incoming substrate. The relatively loose packing of the gorge water molecules leaves numerous small voids, and more efficient space-filling by substrates and inhibitors may be a major driving force of ligand binding.     

Comparative modelling of human PHOSPHO1 reveals a new group of phosphatases within the haloacid dehalogenase superfamily

PHOSPHO1 is a recently identified phosphatase whose expression is upregulated in mineralizing cells and is implicated in the generation of inorganic phosphate for matrix mineralization, a process central to skeletal development. The enzyme is a member of the haloacid dehalogenase (HAD) superfamily of magnesium-dependent hydrolases. However, the natural substrate(s) is as yet unidentified and to date no structural information is known. We have identified homologous proteins in a number of species and have modelled human PHOSPHO1 based upon the crystal structure of phosphoserine phosphatase (PSP) from Methanococcus jannaschii. The model includes the catalytic Mg(2+) atom bound via three conserved Asp residues (Asp32, Asp34 and Asp203); O-ligands are also provided by a phosphate anion and two water molecules. Additional residues involved in PSP-catalysed hydrolysis are conserved and are located nearby, suggesting both enzymes share a similar reaction mechanism. In PHOSPHO1, none of the PSP residues that confer the enzyme's substrate specificity (Arg56, Glu20, Met43 and Phe49) are conserved. Instead, we propose that two fully conserved Asp residues (Asp43 and Asp123), not present in PSPs contribute to substrate specificity in PHOSPHO1. Our findings show that PHOSPHO1 is not a member of the subfamily of PSPs but belongs to a novel, closely related enzyme group within the HAD superfamily.     

Chemically reprogramming the phospho‐transfer reaction to crosslink protein kinases to their substrates

The proteomic mapping of enzyme–substrate interactions is challenged by their transient nature. A method to capture interacting protein kinases in complexes with a single substrate of interest would provide a new tool for mapping kinase signaling networks. Here, we describe a nucleotide‐based substrate analog capable of reprogramming the wild‐type phosphoryl‐transfer reaction to produce a kinase‐acrylamide‐based thioether crosslink to mutant substrates with a cysteine nucleophile substituted at the native phosphorylation site. A previously reported ATP‐based methacrylate crosslinker (ATP‐MA) was capable of mediating kinase crosslinking to short peptides but not protein substrates. Exploration of structural variants of ATP‐MA to enable crosslinking of protein substrates to kinases led to the discovery that an ADP‐based methacrylate (ADP‐MA) crosslinker was superior to the ATP scaffold at crosslinking in vitro. The improved efficiency of ADP‐MA over ATP‐MA is due to reduced inhibition of the second step of the kinase–substrate crosslinking reaction by the product of the first step of the reaction. The new probe, ADP‐MA, demonstrated enhanced in vitro crosslinking between the Src tyrosine kinase and its substrate Cortactin in a phosphorylation site‐specific manner. The kinase–substrate crosslinking reaction can be carried out in a complex mammalian cell lysate setting, although the low abundance of endogenous kinases remains a significant challenge for efficient capture.     

Assessment of substrate-stabilizing factors for DnaK on the folding of aggregation-prone proteins

Hydrophobic interactions between molecular chaperones and their nonnative substrates have been believed to be mainly responsible for both substrate recognition and stabilization against aggregation. However, the hydrophobic contact area between DnaK and its substrate proteins is very limited and other factors of DnaK for the substrate stabilization could not be excluded. Here, we covalently fused DnaK to the N-termini of aggregation-prone proteins in vivo. In the context of a fusion protein, DnaK has the ability to efficiently solubilize its linked proteins. The point mutation of the residue of DnaK critical for the substrate recognition and the deletion of the C-terminal substrate-binding domain did not have significant effect on the solubilizing ability of DnaK. The results imply that other factors of DnaK, distinct from the hydrophobic shielding of folding intermediates, also contributes to stabilization of its noncovalently bound substrates against aggregation. Elucidation of the nature of these factors would further enhance our understanding of the substrate stabilization of DnaK for expedited protein folding.     

Brownian dynamic study of an enzyme metabolon in the TCA cycle: Substrate kinetics and channeling

Malate dehydrogenase (MDH) and citrate synthase (CS) are two pacemaking enzymes involved in the tricarboxylic acid (TCA) cycle. Oxaloacetate (OAA) molecules are the intermediate substrates that are transferred from the MDH to CS to carry out sequential catalysis. It is known that, to achieve a high flux of intermediate transport and reduce the probability of substrate leaking, a MDH‐CS metabolon forms to enhance the OAA substrate channeling. In this study, we aim to understand the OAA channeling within possible MDH‐CS metabolons that have different structural orientations in their complexes. Three MDH‐CS metabolons from native bovine, wild‐type porcine, and recombinant sources, published in recent work, were selected to calculate OAA transfer efficiency by Brownian dynamics (BD) simulations and to study, through electrostatic potential calculations, a possible role of charges that drive the substrate channeling. Our results show that an electrostatic channel is formed in the metabolons of native bovine and recombinant porcine enzymes, which guides the oppositely charged OAA molecules passing through the channel and enhances the transfer efficiency. However, the channeling probability in a suggested wild‐type porcine metabolon conformation is reduced due to an extended diffusion length between the MDH and CS active sites, implying that the corresponding arrangements of MDH and CS result in the decrease of electrostatic steering between substrates and protein surface and then reduce the substrate transfer efficiency from one active site to another.     

Is the bovine lysosomal phospholipase B‐like protein an amidase?

The main function of lysosomal proteins is to degrade cellular macromolecules. We purified a novel lysosomal protein to homogeneity from bovine kidneys. By gene annotation, this protein is defined as a bovine phospholipase B‐like protein 1 (bPLBD1) and, to better understand its biological function, we solved its structure at 1.9 Å resolution. We showed that bPLBD1 has uniform noncomplex‐type N‐glycosylation and that it localized to the lysosome. The first step in lysosomal protein transport, the initiation of mannose‐6‐phosphorylation by a N‐acetylglucosamine‐1‐phosphotransferase, requires recognition of at least two distinct lysines on the protein surface. We identified candidate lysines by analyzing the structural and sequentially conserved N‐glycosylation sites and lysines in bPLBD1 and in the homologous mouse PLBD2. Our model suggests that N408 is the primarily phosphorylated glycan, and K358 a key residue for N‐acetylglucosamine‐1‐phosphotransferase recognition. Two other lysines, K334 and K342, provide the required second site for N‐acetylglucosamine‐1‐phosphotransferase recognition. bPLBD1 is an N‐terminal nucleophile (Ntn) hydrolase. By comparison with other Ntn‐hydrolases, we conclude that the acyl moiety of PLBD1 substrate must be small to fit the putative binding pocket, whereas the space for the rest of the substrate is a large open cleft. Finally, as all the known substrates of Ntn‐hydrolases have amide bonds, we suggest that bPLBD1 may be an amidase or peptidase instead of lipase, explaining the difficulty in finding a good substrate for any members of the PLBD family. Proteins 2014; 82:300–311. © 2013 Wiley Periodicals, Inc.     

Membrane Proteases in the Bacterial Protein Secretion and Quality Control Pathway

Summary: Proteolytic cleavage of proteins that are permanently or transiently associated with the cytoplasmic membrane is crucially important for a wide range of essential processes in bacteria. This applies in particular to the secretion of proteins and to membrane protein quality control. Major progress has been made in elucidating the structure-function relationships of many of the responsible membrane proteases, including signal peptidases, signal peptide hydrolases, FtsH, the rhomboid protease GlpG, and the site 1 protease DegS. These enzymes employ very different mechanisms to cleave substrates at the cytoplasmic and extracytoplasmic membrane surfaces or within the plane of the membrane. This review highlights the different ways that bacterial membrane proteases degrade their substrates, with special emphasis on catalytic mechanisms and substrate delivery to the respective active sites.     

Cytochemical Localization of Polyphenol Oxidase Activity in K2‐Bodies of Saprolegnia ferax Secondary Zoospores

Zoospores of the oomycete Saprolegnia ferax release adhesive material from K‐bodies at the onset of attachment to substrates. To understand more fully how K‐bodies function in adhesion, enzyme activity was investigated cytochemically in secondary zoospores. Presence of catalase, a marker enzyme for microbodies, was explored in the diaminobenzidine (DAB) reaction. Although pH 9.2 DAB‐staining characteristic of catalase activity was detected in the granular matrix regions of K‐bodies, reaction controls indicated that the reaction was due to oxidative enzyme activity other than catalase. Because polyphenol oxidase (PPO) is another metal‐containing enzyme capable of oxidizing DAB, activity of this enzyme was tested with a more specific substrate, dihydroxyphenylalanine (DOPA). In the DOPA procedure, reaction product was exclusively localized within K‐bodies, indicating the presence of PPO. Results with three methods of reaction controls (elimination of substrate, addition of a PPO enzyme inhibitor, and heat‐inactivation of enzymes) all supported the presence of PPO in K‐bodies. This study highlights potential roles for K‐body PPO in stabilization of adhesion bodies by: cross‐linking matrix phenolic proteins or glycoproteins as K‐bodies discharge adhesives onto substrates, or polymerizing phenolics protective against microbial attacks of the adhesion pad.     

Structure and substrate binding properties of cobB, a Sir2 homolog protein deacetylase from Escherichia coli

Sirtuins are NAD+-dependent protein deacetylase enzymes that are broadly conserved from bacteria to human, and have been implicated to play important roles in gene regulation, metabolism and longevity. cobB is a bacterial sirtuin that deacetylates acetyl-CoA synthetase (Acs) at an active site lysine to stimulate its enzymatic activity. Here, we report the structure of cobB bound to an acetyl-lysine containing non-cognate histone H4 substrate. A comparison with the previously reported archaeal and eukaryotic sirtuin structures reveals the greatest variability in a small zinc-binding domain implicated to play a particularly important role in substrate-specific binding by the sirtuin proteins. Comparison of the cobB/histone H4 complex with other sirtuin proteins in complex with acetyl-lysine containing substrates, further suggests that contacts to the acetyl-lysine side-chain and beta-sheet interactions with residues directly C-terminal to the acetyl-lysine represent conserved features of sirtuin-substrate recognition. Isothermal titration calorimetry studies were used to compare the affinity of cobB for a variety of cognate and non-cognate acetyl-lysine-bearing peptides revealing an exothermic reaction with relatively little discrimination between substrates. In contrast, similar studies employing intact acetylated Acs protein as a substrate reveal a binding reaction that is endothermic, suggesting that cobB recognition of substrate involves a burial of hydrophobic surface and/or structural rearrangement involving substrate regions distal to the acetyl-lysine-binding site. Together, these studies suggest that substrate-specific binding by sirtuin proteins involves contributions from the zinc-binding domain of the enzyme and substrate regions distal to the acetyl-lysine-binding site.     

Plant chitinase/lysozyme isoforms show distinct substrate specificity and cleavage site preference towards lipochitooligosaccharide Nod signals

The ability of 16 chitinases from seven different plant species to hydrolyze a collection of several structurally related lipochitooligosaccharides (LCOs) of Rhizobium was analyzed. It was found that the enzymes differed to a large extent in their activity on different LCOs. Differences were attributed to (i) the relative activity on different LCOs as substrate (e.g. sulfated versus non-sulfated LCOs); (ii) the relative cleavage site preference on a given LCO molecule (hydrolysis of either the second, third or fourth glycosidic bond from the non-reducing end of the molecule); and (iii) the stereochemistry of the reaction (retention or inversion of the anomeric configuration). A graphic representation of the different substrate specificities resulted in a ‘fingerprint’ that is characteristic for a given enzyme or a family of related enzymes. By comparing the LCO-fingerprint of unknown enzymes with those obtained for already characterized proteins, it is possible to identify new glycosyl hydrolases. The high diversity of substrate specificity found among plant chitinases may reflect variations in the natural substrates of the enzymes, such as substitutions on the chitin moiety of fungal cell walls or, in plants, the presence of putative endogenous substrates related to LCOs.