Characterization of an extremophile bacterial acid phosphatase derived from metagenomics analysis.

Acid phosphatases are enzymes that play a crucial role in the hydrolysis of various organophosphorous molecules. A putative acid phosphatase called FS6 was identified using genetic profiles and sequences from different environments. FS6 showed high sequence similarity to type C acid phosphatases and retained more than 30% of consensus residues in its protein sequence. A histidine-tagged recombinant FS6 produced in Escherichia coli exhibited extremophile properties, functioning effectively in a broad pH range between 3.5 and 8.5. The enzyme demonstrated optimal activity at temperatures between 25 and 50°C, with a melting temperature of 51.6°C. Kinetic parameters were determined using various substrates, and the reaction catalysed by FS6 with physiological substrates was at least 100-fold more efficient than with p-nitrophenyl phosphate. Furthermore, FS6 was found to be a decamer in solution, unlike the dimeric forms of crystallized proteins in its family.

First 3-D structural evidence of a native-like intertwined dimer in the acylphosphatase family.

Acylphosphatase (AcP, EC 3.6.1.7) is a small model protein conformed by a ferredoxin-like fold, profoundly studied to get insights into protein folding and aggregation processes. Numerous studies focused on the aggregation and/or amyloidogenic properties of AcPs suggest the importance of edge-ß-strands in the process. In this work, we present the first crystallographic structure of Escherichia coli AcP (EcoAcP), showing notable differences with the only available NMR structure for this enzyme. EcoAcP is crystalised as an intertwined dimer formed by replacing a single C-terminal ß-strand between two protomers, suggesting a flexible character of the C-terminal edge of EcoAcP. Despite numerous works where AcP from different sources have been used as a model system for protein aggregation, our domain-swapped EcoAcP structure is the first 3-D structural evidence of native-like aggregated species for any AcP reported to date, providing clues on molecular determinants unleashing aggregation.

Magnetite Mineralization inside Cross-Linked Protein Crystals.

Crystallization in confined spaces is a widespread process in nature that also has important implications for the stability and durability of many man-made materials. It has been reported that confinement can alter essential crystallization events, such as nucleation and growth and, thus, have an impact on crystal size, polymorphism, morphology, and stability. Therefore, the study of nucleation in confined spaces can help us understand similar events that occur in nature, such as biomineralization, design new methods to control crystallization, and expand our knowledge in the field of crystallography. Although the fundamental interest is clear, basic models at the laboratory scale are scarce mainly due to the difficulty in obtaining well-defined confined spaces allowing a simultaneous study of the mineralization process outside and inside the cavities. Herein, we have studied magnetite precipitation in the channels of cross-linked protein crystals (CLPCs) with different channel pore sizes, as a model of crystallization in confined spaces. Our results show that nucleation of an Fe-rich phase occurs inside the protein channels in all cases, but, by a combination of chemical and physical effects, the channel diameter of CLPCs exerted a precise control on the size and stability of those Fe-rich nanoparticles. The small diameters of protein channels restrain the growth of metastable intermediates to around 2 nm and stabilize them over time. At larger pore diameters, recrystallization of the Fe-rich precursors into more stable phases was observed. This study highlights the impact that crystallization in confined spaces can have on the physicochemical properties of the resulting crystals and shows that CLPCs can be interesting substrates to study this process.

Structural insights into choline-O-sulfatase reveal the molecular determinants for ligand binding.

Choline-O-sulfatase (COSe; EC 3.1.6.6) is a member of the alkaline phosphatase (AP) superfamily, and its natural function is to hydrolyze choline-O-sulfate into choline and sulfate. Despite its natural function, the major interest in this enzyme resides in the landmark catalytic/substrate promiscuity of sulfatases, which has led to attention in the biotechnological field due to their potential in protein engineering. In this work, an in-depth structural analysis of wild-type Sinorhizobium (Ensifer) meliloti COSe (SmeCOSe) and its C54S active-site mutant is reported. The binding mode of this AP superfamily member to both products of the reaction (sulfate and choline) and to a substrate-like compound are shown for the first time. The structures further confirm the importance of the C-terminal extension of the enzyme in becoming part of the active site and participating in enzyme activity through dynamic intra-subunit and inter-subunit hydrogen bonds (Asn146A-Asp500B-Asn498B). These residues act as the `gatekeeper' responsible for the open/closed conformations of the enzyme, in addition to assisting in ligand binding through the rearrangement of Leu499 (with a movement of approximately 5 Å). Trp129 and His145 clamp the quaternary ammonium moiety of choline and also connect the catalytic cleft to the C-terminus of an adjacent protomer. The structural information reported here contrasts with the proposed role of conformational dynamics in promoting the enzymatic catalytic proficiency of an enzyme.

X-ray Characterization of Conformational Changes of Human Apo- and Holo-Transferrin.

Human serum transferrin (Tf) is a bilobed glycoprotein whose function is to transport iron through receptor-mediated endocytosis. The mechanism for iron release is pH-dependent and involves conformational changes in the protein, thus making it an attractive system for possible biomedical applications. In this contribution, two powerful X-ray techniques, namely Macromolecular X-ray Crystallography (MX) and Small Angle X-ray Scattering (SAXS), were used to study the conformational changes of iron-free (apo) and iron-loaded (holo) transferrin in crystal and solution states, respectively, at three different pH values of physiological relevance. A crystallographic model of glycosylated apo-Tf was obtained at 3.0 Å resolution, which did not resolve further despite many efforts to improve crystal quality. In the solution, apo-Tf remained mostly globular in all the pH conditions tested; however, the co-existence of closed, partially open, and open conformations was observed for holo-Tf, which showed a more elongated and flexible shape overall.

The structural basis for signal promiscuity in a bacterial chemoreceptor.

Signalling through chemosensory pathways is typically initiated by the binding of signal molecules to the chemoreceptor ligand binding domain (LBD). The PcaY_PP chemoreceptor from Pseudomonas putida KT2440 is characterized by an unusually broad signal range, and minimal requisites for signal binding are the presence of a C6-membered ring and that of a carboxyl group. Previous studies have shown that only some of the multiple signals recognized by this chemoreceptor are of apparent metabolic value. We report here high-resolution structures of PcaY_PP-LBD in the absence and presence of four cognate chemoeffectors and glycerol. The domain formed a four-helix bundle (4HB), and both ligand binding sites of the dimer were occupied with the high-affinity ligands protocatechuate and quinate, whereas the lower-affinity ligands benzoate and salicylate were present in only one site. Ligand binding was verified by microcalorimetric titration of site-directed mutants revealing important roles of an arginine and number of polar residues that establish an extensive hydrogen bonding network with bound ligands. The comparison of the apo and holo structures did not provide evidence for this receptor employing a transmembrane signalling mechanism that involves piston-like shifts of the final helix. Instead, ligand binding caused rigid-body scissoring movements of both monomers of the dimer. Comparisons with the 4HB domains of the Tar and Tsr chemoreceptors revealed significant structural differences. Importantly, the ligand binding site in PcaY_PP-LBD is approximately 8 Å removed from that of the Tar and Tsr receptors. Data indicate a significant amount of structural and functional diversity among 4HB domains. DATABASES: The coordinates and structure factors have been deposited in the protein data band with the following IDs: 6S1A (apo form), 6S18 (bound glycerol), 6S33 (bound protocatechuate), 6S38 (bound quinate), 6S3B (bound benzoate) and 6S37 (bound salicylate).

N-succinylamino acid racemases: Enzymatic properties and biotechnological applications.

The N-succinylamino acid racemase/o-succinylbenzoate synthase (NSAR/OSBS) subfamily from the enolase superfamily contains different enzymes showing promiscuous N-substituted-amino acid racemase (NxAR) activity. These enzymes were originally named as N-acylamino acid racemases because of their industrial application. Nonetheless, they are pivotal in several enzymatic cascades due to their versatility to catalyze a wide substrate spectrum, allowing the production of optically pure d- or l-amino acids from cheap precursors. These compounds are of paramount economic interest, since they are used as food additives, in the pharmaceutical and cosmetics industries and/or as chiral synthons in organic synthesis. Despite its economic importance, the discovery of new N-succinylamino acid racemases has become elusive, since classical sequence-based annotation methods proved ineffective in their identification, due to a high sequence similarity among the members of the enolase superfamily. During the last decade, deeper investigations into different members of the NSAR/OSBS subfamily have shed light on the classification and identification of NSAR enzymes with NxAR activity of biotechnological potential. This review aims to gather the dispersed information on NSAR/OSBS members showing NxAR activity over recent decades, focusing on their biotechnological applications and providing practical advice to identify new enzymes.

How Bacterial Chemoreceptors Evolve Novel Ligand Specificities.

Chemoreceptor-based signaling pathways are among the major modes of bacterial signal transduction, and Pseudomonas aeruginosa PAO1 is an important model to study their function. Of the 26 chemoreceptors of this strain, PctA has a broad ligand range and responds to most of the proteinogenic amino acids, whereas PctB and PctC have a much narrower range and show strong ligand preference for l-glutamine and γ-aminobutyrate, respectively. Using several comparative genomics approaches, we show that these receptors are paralogs: pctA gene duplication in the common ancestor of the genus Pseudomonas led to pctC, whereas pctB originated through another, independent pctA duplication in the common ancestor of P. aeruginosa Thus, the broad-range amino acid chemoreceptor was evolutionarily older, and chemoreceptors that complemented "missing" amino acid sensing abilities arose later in specific Pseudomonas lineages. Using comparative sequence analysis, newly solved crystal structures of PctA, PctB, and PctC ligand-binding domains, and their molecular dynamics simulations, we identified a conserved amino acid recognition motif and changes in the ligand-binding pocket that led to novel ligand specificities. In addition, we determined major forces driving the evolution of this group of chemoreceptors.IMPORTANCE Many bacteria possess a large number of chemoreceptors that recognize a variety of different compounds. More than 60% of the genomes analyzed in this study contain paralogous chemoreceptors, suggesting that they emerge with high frequency. We provide first insight on how paralogous receptors have evolved and show that two chemoreceptors with a narrow ligand range have evolved from an ancestral protein with a broad chemoeffector spectrum. Protein structures show that multiple changes in the ligand-binding site account for the differences in the ligand spectrum. This work lays the ground for further studies aimed at establishing whether the principles of ligand-binding evolution reported here can be generalized for a wider spectrum of sensory proteins in bacteria.

A novel cysteine carbamoyl-switch is responsible for the inhibition of formamidase, a nitrilase superfamily member.

Formamidases (EC 3.5.1.49) and amidases (EC 3.5.1.4) are paralogous cysteine-dependent enzymes which catalyze the conversion of amide substrates to ammonia and the corresponding carboxylic acid. Both enzymes have been suggested as an alternative pathway for ammonia production during urea shortage. Urea was proved key in the transcriptional regulation of formamidases/amidases, connecting urea level to amide metabolism. In addition, different amidases have also been shown to be inhibited by urea, pointing to urea-regulation at the enzymatic level. Although amidases have been widely studied due to its biotechnological application in the hydrolysis of aliphatic amides, up to date, only two formamidases have been extensively characterized, belonging to Helicobacter pylori (HpyAmiF) and Bacillus cereus (BceAmiF). In this work, we report the first structure of an acyl-intermediate of BceAmiF. We also report the inhibition of BceAmiF by urea, together with mass spectrometry studies confirming the S-carbamoylation of BceAmiF after urea treatment. X-ray studies of urea-soaked BceAmiF crystals showed short- and long-range rearrangements affecting oligomerization interfaces. Since cysteine-based switches are known to occur in the regulation of different metabolic and signaling pathways, our results suggest a novel S-carbamoylation-switch for the regulation of BceAmiF. This finding could relate to previous observations of unexplained modifications in the catalytic cysteine of different nitrilase superfamily members and therefore extending this regulation mechanism to the whole nitrilase superfamily.

Structural Basis for Polyamine Binding at the dCACHE Domain of the McpU Chemoreceptor from Pseudomonas putida.

Many bacteria can move chemotactically to a variety of compounds and the recognition of chemoeffectors by the chemoreceptor ligand binding domain (LBD) defines the specificity of response. Many chemoreceptors were found to recognize different amino and organic acids, but the McpU chemoreceptor from Pseudomonas putida was identified as the first chemoreceptor that bound specifically polyamines. We report here the three-dimensional structure of McpU-LBD in complex with putrescine at a resolution of 2.4 Å, which fitted well a solution structure generated by small-angle X-ray scattering. Putrescine bound to a negatively charged pocket in the membrane distal module of McpU-LBD. Similarities exist in the binding of putrescine to McpU-LBD and taurine to the LBD of the Mlp37 chemoreceptor of Vibrio cholerae. In both structures, the primary amino group of the respective ligand is recognized by hydrogen bonds established by two aspartate and a tyrosine side chain. This feature may be used to predict the ligands of chemoreceptors with unknown function. Analytical ultracentrifugation revealed that McpU-LBD is monomeric in solution and that ligand binding does not alter this oligomeric state. This sensing mode thus differs from that of the well-characterised four-helix bundle domains where ligands bind to two sites at the LBD dimer interface. Although there appear to be different sensing modes, results are discussed in the context of data, indicating that chemoreceptors employ the same mechanism of transmembrane signaling. This work enhances our understanding of CACHE domains, which are the most abundant sensor domains in bacterial chemoreceptors and sensor kinases.

Mutational and structural analysis of L-N-carbamoylase reveals new insights into a peptidase M20/M25/M40 family member.

N-Carbamoyl-L-amino acid amidohydrolases (L-carbamoylases) are important industrial enzymes used in kinetic resolution of racemic mixtures of N-carbamoyl-amino acids due to their strict enantiospecificity. In this work, we report the first L-carbamoylase structure belonging to Geobacillus stearothermophilus CECT43 (BsLcar), at a resolution of 2.7 Å. Structural analysis of BsLcar and several members of the peptidase M20/M25/M40 family confirmed the expected conserved residues at the active site in this family, and site-directed mutagenesis revealed their relevance to substrate binding. We also found an unexpectedly conserved arginine residue (Arg(234) in BsLcar), proven to be critical for dimerization of the enzyme. The mutation of this sole residue resulted in a total loss of activity and prevented the formation of the dimer in BsLcar. Comparative studies revealed that the dimerization domain of the peptidase M20/M25/M40 family is a "small-molecule binding domain," allowing further evolutionary considerations for this enzyme family.

Understanding the polymorphic behaviour of a mutant of the α-spectrin SH3 domain by means of two 1.1 Å resolution structures.

SH3 domains are small protein modules that mediate the assembly of specific protein complexes, typically via binding to proline-rich sequences in their respective binding partners. Most of the α-spectrin SH3-domain (Spc-SH3) structures determined to date using X-ray diffraction have been solved from crystals belonging to the orthorhombic space group P2(1)2(1)2(1) with a needle-like morphology. All of these orthorhombic crystals exhibited a rapid growth rate. In addition to this crystal form, the R21D mutant of Spc-SH3 crystallizes in a new crystal form in the presence of sodium formate at pH values higher than 6. This new crystal form grows at a slower rate and belongs to the hexagonal space group P6(5)22, with unit-cell parameters a = b = 42.9, c = 127.5 Å. When both polymorphs of the R21D mutant of Spc-SH3 are simultaneously present into the same solution, it has been observed that the hexagonal crystals grow at the expense of the orthorhombic crystals. The availability of 1.1 Šresolution structures for both crystal forms allows the identification of key features that could account for the observed polymorphic behaviour.

Structure of dihydropyrimidinase from Sinorhizobium meliloti CECT4114: new features in an amidohydrolase family member.

The recombinant dihydropyrimidinase from Sinorhizobium meliloti CECT4114 (SmelDhp) has been characterised and its crystal structure elucidated at 1.85A. The global architecture of the protein is reminiscent of that of the amidohydrolase superfamily, consisting of two domains; an (alpha/beta)(8) TIM-like barrel domain, where the catalytic centre is located, and a smaller beta-sheet sandwich domain of unknown function. The c-terminal tails of each subunit extend toward another monomer in a swapping-like manner, creating a hydrogen bond network which suggests its implication in protein oligomerisation. Mutational and structural evidence suggest the involvement of a conserved tyrosine in the reaction mechanism of the enzyme. SmelDhp presents both hydantoinase and dihydropyrimidinase activities, with higher affinity for the natural six-membered ring substrates. For the five-membered ring substrates, affinity was greater for those with aliphatic and apolar groups in the 5th carbon atom, with the highest rates of hydrolysis for d-5-methyl and d-5-ethyl hydantoin (k(cat)/K(m)=2736+/-380 and 944+/-52M(-1)s(-1), respectively). The optimal conditions for the enzyme activity were found to be 60 degrees C of temperature at pH 8.0. SmelDhp retains 95% of its activity after 6-hour preincubation at 60 degrees C. This is the first dihydropyrimidinase used for the hydrolytic opening of non-natural 6-monosubstituted dihydrouracils, which may be exploited for the production of beta-amino acids.

Counterdiffusion methods applied to protein crystallization.

Accumulated experience during the last years on counterdiffusion crystallization methods shows that they are a convenient and generally applicable way of optimizing solution crystal growth experiments. Irrespective of whether the objective of the experiment is to improve crystal quality or size, many experiments reporting a positive or neutral effect of counterdiffusion exists, but adverse effects are consistently absent. Thus counterdiffusion is viewed as a rational crystallization approach to minimize supersaturation and impurity levels at the crystal growth front and to ensure steadiness of both values. This control of the phase transition state is automatically achieved and sustained by a dynamic equilibrium between mass transport and aggregation kinetics. The course of this function can be implemented in any media permitting diffusive mass transport (gels, capillaries, microfluidic devices or microgravity). The counterdiffusion technique has been exploited in many recent applications revealing interesting effects on nucleation and polymorphic precipitation, hence opening further possibilities for innovative screening of crystallization conditions.

Crystallization and preliminary crystallographic studies of the recombinant L-N-carbamoylase from Geobacillus stearothermophilus CECT43.

N-Carbamoyl-L-amino-acid amidohydrolases (L-N-carbamoylases; EC 3.5.1.87) hydrolyze the carbon-nitrogen bond of the ureido group in N-carbamoyl-L-alpha-amino acids. These enzymes are commonly used in the production of optically pure natural and non-natural L-amino acids using the ;hydantoinase process'. Recombinant L-N-carbamoylase from Geobacillus stearothermophilus CECT43 has been expressed, purified and crystallized by hanging-drop vapour diffusion. X-ray data were collected to a resolution of 2.75 A. The crystals belonged to space group P2(1)2(1)2, with unit-cell parameters a = 103.2, b = 211.7, c = 43.1 A and two subunits in the asymmetric unit.

Crystallization and preliminary crystallographic studies of an active-site mutant hydantoin racemase from Sinorhizobium meliloti CECT4114.

A recombinant active-site mutant of hydantoin racemase (C76A) from Sinorhizobium meliloti CECT 4114 (SmeHyuA) has been crystallized in the presence and absence of the substrate D,L-5-isopropyl hydantoin. Crystals of the SmeHyuA mutant suitable for data collection and structure determination were grown using the counter-diffusion method. X-ray data were collected to resolutions of 2.17 and 1.85 A for the free and bound enzymes, respectively. Both crystals belong to space group R3 and contain two molecules of SmeHyuA per asymmetric unit. The crystals of the free and complexed SmeHyuA have unit-cell parameters a = b = 85.43, c = 152.37 A and a = b = 85.69, c = 154.38 A, crystal volumes per protein weight (V(M)) of 1.94 and 1.98 A3 Da(-1) and solvent contents of 36.7 and 37.9%, respectively.

Crystallization by capillary counter-diffusion and structure determination of the N114A mutant of the SH3 domain of Abl tyrosine kinase complexed with a high-affinity peptide ligand.

The recognition of proline-rich ligands by SH3 domains is part of the process leading to diseases such as cancer or AIDS. Understanding the molecular determinants of the binding affinity and specificity of these interactions is crucial for the development of potent inhibitors with therapeutic potential. In this study, the crystallographic structure of the N114A mutant of the SH3 domain of the Abelson leukaemia virus tyrosine kinase complexed with a high-affinity peptide is presented. The crystallization was carried out using the capillary counter-diffusion technique, which facilitates the screening, manipulation and transport of the crystals and allows the collection of X-ray data directly from the capillary in which the crystals were grown. The crystals of the N114A mutant belong to the orthorhombic P2(1)2(1)2(1) space group, with unit-cell parameters a = 48.2, b = 50.1, c = 56.4 A. The quality of the diffraction data set has allowed the structure of the complex to be determined at a resolution limit of 1.75 A.

Granada Crystallisation Box: a new device for protein crystallisation by counter-diffusion techniques.

Granada Crystallisation Box (GCB) is a new crystallisation device designed to perform counter-diffusion experiments. Here we describe the device and its use for protein crystallisation purposes. GCB allows one to explore and exploit the coupling between crystallisation and diffusion. The role of viscous fluids, gels and/or microgravity can be enhanced by using capillary volumes, creating a perfect diffusive mass transport scenario. The use of capillaries also reduces the consumption of macromolecules and avoids the handling of crystals for X-ray diffraction data collection.

Agarose as crystallisation media for proteins II: trapping of gel fibres into the crystals.

The crystallisation pressure exerted by protein crystals growing in agarose gel does not disrupt the gel network. However, protein crystals trap agarose fibres when they grow in agarose gels. The fibres of agarose are distributed randomly in the crystals explaining why they do not appreciably affect the diffraction quality of the crystal