Snapshots of the cystine lyase C-DES during catalysis. Studies in solution and in the crystalline state

The cystine lyase (C-DES) of Synechocystis is a pyridoxal-5'-phosphate-dependent enzyme distantly related to the family of NifS-like proteins. The crystal structure of an N-terminal modified variant has recently been determined. Herein, the reactivity of this enzyme variant was investigated spectroscopically in solution and in the crystalline state to follow the course of the reaction and to determine the catalytic mechanism on a molecular level. Using the stopped-flow technique, the reaction with the preferred substrate cystine was found to follow biphasic kinetics leading to the formation of absorbing species at 338 and 470 nm, attributed to the external aldimine and the alpha-aminoacrylate; the reaction with cysteine also exhibited biphasic behavior but only the external aldimine accumulated. The same reaction intermediates were formed in crystals as seen by polarized absorption microspectrophotometry, thus indicating that C-DES is catalytically competent in the crystalline state. The three-dimensional structure of the catalytically inactive mutant C-DES(K223A) in the presence of cystine showed the formation of an external aldimine species, in which two alternate conformations of the substrate were observed. The combined results allow a catalytic mechanism to be proposed involving interactions between cystine and the active site residues Arg-360, Arg-369, and Trp-251*; these residues reorient during the beta-elimination reaction, leading to the formation of a hydrophobic pocket that stabilizes the enolimine tautomer of the aminoacrylate and the cysteine persulfide product.     

SufS protein from Haloferax volcanii involved in Fe-S cluster assembly in haloarchaea

NifS-like proteins are pyridoxal 5′-phosphate (PLP)-dependent enzymes involved in sulphur transfer metabolism. These enzymes have been catalogued as cysteine desulphurases (CDs) which catalyse the conversion of L-cysteine into L-alanine and an enzyme-bound persulphide radical. This reaction, assisted by different scaffold protein machineries, seems to be the main source of sulphur for the synthesis of essential cofactors of the[Fe-S] cluster. CDs genes have been detected in the tree domains of life, but, up until now, there has been no biochemical characterisation or study into the physiological role of this enzyme in haloarchaea. In this study, we have cloned, expressed and characterised a cysteine desulphurase (SufS) from Haloferax volcanii and demonstrated that this protein is able to reconstitute the [Fe-S] cluster of halophilic ferredoxin.     

Structure of external aldimine of Escherichia coli CsdB, an IscS/NifS homolog: implications for its specificity toward selenocysteine

Escherichia coli CsdB is a pyridoxal 5'-phosphate (PLP)-dependent enzyme that catalyzes both cysteine desulfuration and selenocysteine deselenation. The enzyme has a high specific activity for L-selenocysteine relative to L-cysteine. On the other hand, its paralog, IscS, exhibits higher activity for L-cysteine, which acts as a sulfur donor during the biosynthesis of the iron-sulfur cluster and 4-thiouridine. The structure of CsdB complexed with L-propargylglycine was determined by X-ray crystallography at 2.8 A resolution. The overall polypeptide fold of the complex is similar to that of the uncomplexed enzyme, indicating that no significant structural change occurs upon formation of the complex. In the complex, propargylglycine forms a Schiff base with PLP, providing the features of the external aldimine formed in the active site. The Cys364 residue, which is essential for the activity of CsdB toward L-cysteine but not toward L-selenocysteine, is clearly visible on a loop of the extended lobe (Thr362-Arg375) in all enzyme forms studied, in contrast to the corresponding disordered loop (Ser321-Arg332) of the Thermotoga maritima NifS-like protein, which is closely related to IscS. The extended lobe of CsdB has an 11-residue deletion compared with that of the NifS-like protein. These facts suggest that the restricted flexibility of the Cys364-anchoring extended lobe in CsdB may be responsible for the ability of the enzyme to discriminate between selenium and sulfur.     

Kinetic and structural characterization of Slr0077/SufS, the essential cysteine desulfurase from Synechocystis sp. PCC 6803

Cysteine desulfurases, designated NifS, IscS, and SufS, cleave L-cysteine to form alanine and an enzyme cysteinyl persulfide intermediate. Genetic studies on the photosynthetic cyanobacterium Synechocystis sp. PCC 6803 have shown that of the three Nif/Isc/SufS-like proteins encoded in its genome only the sequence group II protein, Slr0077/SufS, is essential. This protein has been overexpressed in Escherichia coli, purified to homogeneity, shown to bind pyridoxal-5'-phosphate (PLP) and to catalyze cysteine desulfuration, and characterized in terms of its structure and kinetics. The results suggest that catalysis in the absence of accessory factors has two constituent pathways, one involving nucleophilic attack by C372 to form the Slr0077/SufS-bound cysteinyl persulfide intermediate and the second involving intermolecular attack by the sulfur of a second molecule of the substrate on the initial l-cysteine-PLP complex to form free l-cysteine persulfide. The second pathway is operant in the C372A variant protein, explaining why it retains significant activity, which is proportional to the concentration of l-cysteine (i.e., does not saturate). C-S bond cleavage by the first (normal) pathway is considerably less efficient than the equivalent step in a group I desulfurase (Slr0387) from the same organism (characterized in the accompanying paper). The 1.8 A crystal structure of the protein, which is very similar to that previously reported for E. coli SufS, shows that the loop on which C372 resides is well-ordered and shorter by 11 residues than the corresponding disordered loop of the group I NifS-like protein from Thermotoga maritima. Sequence comparisons establish that the T. maritima and Slr0387 proteins have loops of similar length. The combined structural and kinetic data imply that the modest activity of Slr0077/SufS and other SufS proteins in comparison to their sequence group I (NifS/IscS-like) paralogues results from inefficiency in the nucleophilic attack step associated with differences in the structure or dynamics of this loop. The recent reports that SufS proteins can be activated manyfold by binding to SufE thus implies that the accessory protein either accelerates nucleophilic attack by the conserved cysteine residue of SufS by a conformational mechanism or itself contributes a nucleophilic cysteine for more efficient intermolecular attack.     

Characterization of a NifS-like chloroplast protein from Arabidopsis. Implications for its role in sulfur and selenium metabolism

NifS-like proteins catalyze the formation of elemental sulfur (S) and alanine from cysteine (Cys) or of elemental selenium (Se) and alanine from seleno-Cys. Cys desulfurase activity is required to produce the S of iron (Fe)-S clusters, whereas seleno-Cys lyase activity is needed for the incorporation of Se in selenoproteins. In plants, the chloroplast is the location of (seleno) Cys formation and a location of Fe-S cluster formation. The goal of these studies was to identify and characterize chloroplast NifS-like proteins. Using seleno-Cys as a substrate, it was found that 25% to 30% of the NifS activity in green tissue in Arabidopsis is present in chloroplasts. A cDNA encoding a putative chloroplast NifS-like protein, AtCpNifS, was cloned, and its chloroplast localization was confirmed using immunoblot analysis and in vitro import. AtCpNIFS is expressed in all major tissue types. The protein was expressed in Escherichia coli and purified. The enzyme contains a pyridoxal 5' phosphate cofactor and is a dimer. It is a type II NifS-like protein, more similar to bacterial seleno-Cys lyases than to Cys desulfurases. The enzyme is active on both seleno-Cys and Cys but has a much higher activity toward the Se substrate. The possible role of AtCpNifS in plastidic Fe-S cluster formation or in Se metabolism is discussed.     

The three-dimensional structure of N-succinyldiaminopimelate aminotransferase from Mycobacterium tuberculosis

Inhibitors of the enzymes of the lysine biosynthetic pathway are considered promising lead compounds for the design of new antibacterial drugs, because the pathway appears to be indispensable for bacteria and because it is absent in humans. As part of our efforts to structurally characterize all enzymes of this pathway in Mycobacterium tuberculosis (Mtb), we have determined the three-dimensional structure of N-succinyldiaminopimelate aminotransferase (DapC, DAP-AT, Rv0858c) to a resolution of 2.0 A. This structure is the first DAP-AT structure reported to date. The orthorhombic crystals of Mtb-DAP-AT contain one functional dimer exhibiting C(2) symmetry in the asymmetric unit. The homodimer displays the typical S-shape of class I pyridoxal-5'-phosphate (PLP)-binding proteins. The two active sites of the dimer both feature an internal aldimine with the co-factor PLP covalently bound to the Lys232, although neither substrate nor co-factor had been added during protein production, purification and crystallization. Nine water molecules are conserved in the active site and form an intricate hydrogen-bonding network with the co-factor and the surrounding amino acid residues. Together with some residual difference electron density in the active site, this architecture permitted the building of external aldimine models of the enzyme with the substrates glutamate, the amine donor, and N-succinyl-2-amino-6-keto-pimelate, the amine acceptor. Based on these models, the amino acids relevant for substrate binding and specificity can be postulated. Furthermore, in the external aldimine model of N-succinyl-2-amino-6-keto-pimelate, the succinyl group overlaps with a glycerol binding site that has also been identified in both active sites of the Mtb-DAP-AT dimer. A comparison of the structure of Mtb-DAP-AT with other class I PLP-binding proteins, revealed that some inhibitors utilize the same binding site. Thus, the proposed models also provide an explanation for the mode of inhibition of Mtb-DAP-AT and they may be of help in the design of compounds, which are capable of inhibiting the enzyme. Last, but not least, a chloride binding helix exhibiting a peculiar amino acid sequence with a number of exposed hydrophobic side-chains was identified, which may be hypothesized as a putative docking site.     

Role of a NifS-like protein from the cyanobacterium Synechocystis PCC 6803 in the maturation of FeS proteins

In Azotobacter vinelandii and Escherichia coli NifS or NifS-like proteins are involved in FeS protein assembly by mobilizing sulfur from free cysteine. This sulfur together with Fe(2+) is then incorporated into apo-FeS proteins to form an FeS center. A different activity termed C-DES [for cyst(e)ine desulfurylase] was recently isolated from the cyanobacterium Synechocystis PCC 6714 which also mobilized sulfur and which was able to incorporate the FeS center into apoferredoxin. In the genome of the cyanobacterium Synechocystis PCC 6803, there are three open reading frames (orfs) that are similar to NifS and one that is similar to C-DES, indicating that this bacterium might contain both activities, NifS and C-DES. One orf from Synechocystis PCC 6803 encoding a NifS-like protein, slr0387, was overexpressed in E. coli and purified. The molecular mass of the recombinant protein was determined to be about 82 kDa, indicating that it is a homodimer. The absorption spectrum was typical for PLP-containing proteins with an absorption maximum at 390 nm at pH 9.0 and at 425 nm at pH 6.5. The pH dependence of the absorption spectrum correlated with enzyme activity. Maximal activity measured as sulfide production was observed between pH 8.5 and 10. The activity decreased at lower pH values and was undetectable at pH 5.5. pH-dependent changes in the absorption spectrum and activity were attributed to protonation of the Schiff base formed by a lysine side chain and the PLP cofactor. Studies on substrate specificity demonstrated that cysteine derivatives other than cysteine methyl ester and cysteine-sulfinic acid could not serve as substrates for this enzyme. In particular, cystine was not a substrate for the Synechocystis NifS-like protein, whereas it is the best substrate for C-DES. In the presence of Fe(2+), cysteine, and a reductant, the NifS-like protein was able to produce holoferredoxin from apoferredoxin. The implications of two different activities for FeS center biosynthesis in Synechocystis are discussed.     

Identification of persulfide-binding and disulfide-forming cysteine residues in the NifS-like domain of the molybdenum cofactor sulfurase ABA3 by cysteine-scanning mutagenesis

The Moco (molybdenum cofactor) sulfurase ABA3 from Arabidopsis thaliana catalyses the sulfuration of the Moco of aldehyde oxidase and xanthine oxidoreductase, which represents the final activation step of these enzymes. ABA3 consists of an N-terminal NifS-like domain that exhibits L-cysteine desulfurase activity and a C-terminal domain that binds sulfurated Moco. The strictly conserved Cys430 in the NifS-like domain binds a persulfide intermediate, which is abstracted from the substrate L-cysteine and finally needs to be transferred to the Moco of aldehyde oxidase and xanthine oxidoreductase. In addition to Cys?3?, another eight cysteine residues are located in the NifS-like domain, with two of them being highly conserved among Moco sulfurase proteins and, at the same time, being in close proximity to Cys?3?. By determination of the number of surface-exposed cysteine residues and the number of persulfide-binding cysteine residues in combination with the sequential substitution of each of the nine cysteine residues, a second persulfide-binding cysteine residue, Cys2??, was identified. Furthermore, the active-site Cys?3? was found to be located on top of a loop structure, formed by the two flanking residues Cys?2? and Cys?3?, which are likely to form an intramolecular disulfide bridge. These findings are confirmed by a structural model of the NifS-like domain, which indicates that Cys?2? and Cys?3? are within disulfide bond distance and that a persulfide transfer from Cys?3? to Cys2?? is indeed possible.     

X-ray structure refinement and comparison of three forms of mitochondrial aspartate aminotransferase.

The X-ray crystal structures of three forms of the enzyme aspartate aminotransferase (EC 2.6.1.1) from chicken heart mitochondria have been refined by least-squares methods: holoenzyme with the co-factor pyridoxal-5'-phosphate bound at pH 7.5 (1.9 A resolution), holoenzyme with pyridoxal-5'-phosphate bound at pH 5.1 (2.3 A resolution) and holoenzyme with the co-factor pyridoxamine-5'-phosphate bound at pH 7.5 (2.2 A resolution). The crystallographic agreement factors [formula: see text] for the structures are 0.166, 0.130 and 0.131, respectively, for all data in the resolution range from 10.0 A to the limit of diffraction for each structure. The secondary, super-secondary and domain structures of the pyridoxal-phosphate holoenzyme at pH 7.5 are described in detail. The surface area of the interface between the monomer subunits of this dimeric alpha 2 protein is unusually large, indicating a very stable dimer. This is consistent with biochemical data. Both subunit and domain interfaces are relatively smooth compared with other proteins. The interactions of the protein with its co-factor are described and compared among the three structures. Observed changes in co-factor conformation may be related to spectral changes and the energetics of the catalytic reaction. Small but significant adjustments of the protein to changes in co-factor conformation are seen. These adjustments may be accommodated by small rigid-body shifts of secondary structural elements, and by packing defects in the protein core.     

Substitutions in an active site loop of Escherichia coli IscS result in specific defects in Fe-S cluster and thionucleoside biosynthesis in vivo

IscS catalyzes the fragmentation of l-cysteine to l-alanine and sulfane sulfur in the form of a cysteine persulfide in the active site of the enzyme. In Escherichia coli IscS, the active site cysteine Cys(328) resides in a flexible loop that potentially influences both the formation and stability of the cysteine persulfide as well as the specificity of sulfur transfer to protein substrates. Alanine-scanning substitution of this 14 amino acid region surrounding Cys(328) identified additional residues important for IscS function in vivo. Two mutations, S326A and L333A, resulted in strains that were severely impaired in Fe-S cluster synthesis in vivo. The mutant strains were deficient in Fe-S cluster-dependent tRNA thionucleosides (s(2)C and ms(2)i(6)A) yet showed wild type levels of Fe-S-independent thionucleosides (s(4)U and mnm(5)s(2)U) that require persulfide formation and transfer. In vitro, the mutant proteins were similar to wild type in both cysteine desulfurase activity and sulfur transfer to IscU. These results indicate that residues in the active site loop can selectively affect Fe-S cluster biosynthesis in vivo without detectably affecting persulfide delivery and suggest that additional assays may be necessary to fully represent the functions of IscS in Fe-S cluster formation.     

Crystal structure of YnjE from Escherichia coli,a sulfurtransferase with three rhodanese domains

Rhodaneses/sulfurtransferases are ubiquitous enzymes that catalyze the transfer of sulfane sulfur from a donor molecule to a thiophilic acceptor via an active site cysteine that is modified to a persulfide during the reaction. Here, we present the first crystal structure of a triple‐domain rhodanese‐like protein, namely YnjE from Escherichia coli, in two states where its active site cysteine is either unmodified or present as a persulfide. Compared to well‐characterized tandem domain rhodaneses, which are composed of one inactive and one active domain, YnjE contains an extra N‐terminal inactive rhodanese‐like domain. Phylogenetic analysis reveals that YnjE triple‐domain homologs can be found in a variety of other γ‐proteobacteria, in addition, some single‐, tandem‐, four and even six‐domain variants exist. All YnjE rhodaneses are characterized by a highly conserved active site loop (CGTGWR) and evolved independently from other rhodaneses, thus forming their own subfamily. On the basis of structural comparisons with other rhodaneses and kinetic studies, YnjE, which is more similar to thiosulfate:cyanide sulfurtransferases than to 3‐mercaptopyruvate:cyanide sulfurtransferases, has a different substrate specificity that depends not only on the composition of the active site loop with the catalytic cysteine at the first position but also on the surrounding residues. In vitro YnjE can be efficiently persulfurated by the cysteine desulfurase IscS. The catalytic site is located within an elongated cleft, formed by the central and C‐terminal domain and is lined by bulky hydrophobic residues with the catalytic active cysteine largely shielded from the solvent.     

ABA3 is a molybdenum cofactor sulfurase required for activation of aldehyde oxidase and xanthine dehydrogenase in Arabidopsis thaliana.

The xanthine oxidase class of molybdenum enzyzmes requires a terminal sulfur ligand at the active site. It has been proposed that a special sulfurase catalyzes the insertion of this ligand thereby activating the enzymes. Previous analyses of mutants in plants indicated that the genetic locus aba3 is involved in this step leading to activation of the molybdenum enzymes aldehyde oxidase and xanthine dehydrogenase. Here we report the cloning of the aba3 gene from Arabidopsis thaliana and the biochemical characterization of the purified protein. ABA3 is a two-domain protein with a N-terminal NifS-like sulfurase domain and a C-terminal domain that might be involved in recognizing the target enzymes. Molecular analysis of three aba3 mutants identified mutations in both domains. ABA3 contains highly conserved binding motifs for pyridoxal phosphate and for a persulfide. The purified recombinant protein possesses a cysteine desulfurase activity, is yellow in color, and shows a NifS-like change in absorbance in the presence of L-cysteine. Pretreatment of ABA3 with a thiol-specific alkylating reagent inhibited its desulfurase activity. These data indicate a transsulfuration reaction similar to bacterial NifS. In a fully defined in vitro system, the purified protein was able to activate aldehyde oxidase by using L-cysteine as sulfur donor. Finally, we show that the expression of the aba3 gene is inducible by drought-stress.     

Escherichia coli NifS-like proteins provide selenium in the pathway for the biosynthesis of selenophosphate

Selenophosphate synthetase (SPS), the selD gene product from Escherichia coli, catalyzes the biosynthesis of monoselenophosphate, AMP, and orthophosphate in a 1:1:1 ratio from selenide and ATP. Kinetic characterization revealed the K(m) value for selenide approached levels that are toxic to the cell. Our previous demonstration that a Se(0)-generating system consisting of l-selenocysteine and the Azotobacter vinelandii NifS protein can replace selenide for selenophosphate biosynthesis in vitro suggested a mechanism whereby cells can overcome selenide toxicity. Recently, three E. coli NifS-like proteins, CsdB, CSD, and IscS, have been overexpressed and characterized. All three enzymes act on selenocysteine and cysteine to produce Se(0) and S(0), respectively. In the present study, we demonstrate the ability of each E. coli NifS-like protein to function as a selenium delivery protein for the in vitro biosynthesis of selenophosphate by E. coli wild-type SPS. Significantly, the SPS (C17S) mutant, which is inactive in the standard in vitro assay with selenide as substrate, was found to exhibit detectable activity in the presence of CsdB, CSD, or IscS and l-selenocysteine. Taken together the ability of the NifS-like proteins to generate a selenium substrate for SPS and the activation of the SPS (C17S) mutant suggest a selenium delivery function for the proteins in vivo.     

MOSC domains: ancient, predicted sulfur-carrier domains, present in diverse metal-sulfur cluster biosynthesis proteins including Molybdenum cofactor sulfurases

Using computational analysis, a novel superfamily of beta-strand-rich domains was identified in the Molybdenum cofactor sulfurase and several other proteins from both prokaryotes and eukaryotes. These MOSC domains contain an absolutely conserved cysteine and occur either as stand-alone forms such as the bacterial YiiM proteins, or fused to other domains such as a NifS-like catalytic domain in Molybdenum cofactor sulfurase. The MOSC domain is predicted to be a sulfur-carrier domain that receives sulfur abstracted by the pyridoxal phosphate-dependent NifS-like enzymes, on its conserved cysteine, and delivers it for the formation of diverse sulfur-metal clusters. The identification of this domain may clarify the mechanism of biogenesis of various metallo-enzymes including Molybdenum cofactor-containing enzymes that are compromised in human type II xanthinuria.     

Rotational dynamics of 4-aminobutyrate aminotransferase

The fluorescence dye 1-anilinonaphthalene-8-sulfonate (ANS) was used as a probe of non-polar binding sites in 4-aminobutyrate aminotransferase. ANS binds to a single binding site of the dimeric protein with a K_d of 6 μM. Nanosecond emission anisotropy measurements were performed on the ANS-enzyme in an effort to detect independent rotation of the subunits in the native enzyme. The observed rotational correlation time (φ = 65 ns) corresponds to the rotation of a rather rigid dimeric structure. The microenvironment surrounding the natural probe pyridoxal-5-P covalently bound to the dimeric structure was explored using ³¹P-NMR at 72.86 MHz. In the native enzyme, the pyridoxal-5-P ³¹P-chemical shift is pH-independent, indicating that the phosphate group is well protected from the solvent. The correlation time determined from the ³¹P-spectrum of the aminotransferase exceeds the value calculated for the hydrated spherical model (φ = 40 ns). It is concluded that the phosphate of the pyridoxal-5-P molecule is rigidly bound to the active site of 4-aminobutyrate aminotransferase.     

Conserved Loop Cysteines of Vitamin K Epoxide Reductase Complex Subunit 1-like 1 (VKORC1L1) Are Involved in Its Active Site Regeneration

Vitamin K epoxide reductase complex subunit 1 (VKORC1) reduces vitamin K epoxide in the vitamin K cycle for post-translational modification of proteins that are involved in a variety of biological functions. However, the physiological function of VKORC1-like 1 (VKORC1L1), a paralogous enzyme sharing about 50% protein identity with VKORC1, is unknown. Here we determined the structural and functional differences of these two enzymes using fluorescence protease protection (FPP) assay and an in vivo cell-based activity assay. We show that in vivo VKORC1L1 reduces vitamin K epoxide to support vitamin K-dependent carboxylation as efficiently as does VKORC1. However, FPP assays show that unlike VKORC1, VKORC1L1 is a four-transmembrane domain protein with both its termini located in the cytoplasm. Moreover, the conserved loop cysteines, which are not required for VKORC1 activity, are essential for VKORC1L1''s active site regeneration. Results from domain exchanges between VKORC1L1 and VKORC1 suggest that it is VKORC1L1''s overall structure that uniquely allows for active site regeneration by the conserved loop cysteines. Intermediate disulfide trapping results confirmed an intra-molecular electron transfer pathway for VKORC1L1''s active site reduction. Our results allow us to propose a concerted action of the four conserved cysteines of VKORC1L1 for active site regeneration; the second loop cysteine, Cys-58, attacks the active site disulfide, forming an intermediate disulfide with Cys-139; the first loop cysteine, Cys-50, attacks the intermediate disulfide resulting in active site reduction. The different membrane topologies and reaction mechanisms between VKORC1L1 and VKORC1 suggest that these two proteins might have different physiological functions.     

Immunoblot detection of pyridoxal phosphate binding proteins in liver and hepatoma cytosolic extracts

A monoclonal antibody, highly selective for the 5'-phosphopyridoxyl group, can be used to detect cytosolic pyridoxal-5'-phosphate binding proteins by an immunoblot procedure. This technique, when applied to sodium borohydride-treated cytosolic extracts obtained from normal rat liver at various stages of development as well as several liver-derived Morris hepatomas, reveals patterns of pyridoxal-5'-phosphate binding proteins that are characteristic of the various sources of cytosol. These findings suggest that there are developmental and tumor-specific requirements for pyridoxal-5'-phosphate, the coenzymatically active form of vitamin B-6.     

Effect of pH on the structure and stability of Bacillus circulans ssp. alkalophilus phosphoserine aminotransferase: thermodynamic and crystallographic studies

pH is one of the key parameters that affect the stability and function of proteins. We have studied the effect of pH on the pyridoxal-5'-phosphate-dependent enzyme phosphoserine aminotransferase produced by the facultative alkaliphile Bacillus circulans ssp. alkalophilus using thermodynamic and crystallographic analysis. Enzymatic activity assay showed that the enzyme has maximum activity at pH 9.0 and relative activity less than 10% at pH 7.0. Differential scanning calorimetry and circular dichroism experiments revealed variations in the stability and denaturation profiles of the enzyme at different pHs. Most importantly, release of pyridoxal-5'-phosphate and protein thermal denaturation were found to occur simultaneously at pH 6.0 in contrast to pH 8.5 where denaturation preceded cofactor's release by approximately 3 degrees C. To correlate the observed differences in thermal denaturation with structural features, the crystal structure of phosphoserine aminotransferase was determined at 1.2 and 1.5 A resolution at two different pHs (8.5 and 4.6, respectively). Analysis of the two structures revealed changes in the vicinity of the active site and in surface residues. A conformational change in a loop involved in substrate binding at the entrance of the active site has been identified upon pH change. Moreover, the number of intramolecular ion pairs was found reduced in the pH 4.6 structure. Taken together, the presented kinetics, thermal denaturation, and crystallographic data demonstrate a potential role of the active site in unfolding and suggest that subtle but structurally significant conformational rearrangements are involved in the stability and integrity of phosphoserine aminotransferase in response to pH changes.     

Sequence conservation in the chagasin family suggests a common trend in cysteine proteinase binding by unrelated protein inhibitors

The recently described inhibitor of cysteine proteinases from Trypanosoma cruzi, chagasin, was found to have close homologs in several eukaryotes, bacteria and archaea, the first protein inhibitors of cysteine proteases in prokaryotes. These previously uncharacterized 110-130 residue-long proteins share a well-conserved sequence motif that corresponds to two adjacent beta-strands and the short loop connecting them. Chagasin-like proteins also have other conserved, mostly aromatic, residues, and share the same predicted secondary structure. These proteins adopt an all-beta fold with eight predicted beta-strands of the immunoglobulin type. The phylogenetic distribution of the chagasins generally correlates with the presence of papain-like cysteine proteases. Previous studies have uncovered similar trends in cysteine proteinase binding by two unrelated inhibitors, stefin and p41, that belong to the cystatin and thyroglobulin families, respectively. A hypothetical model of chagasin-cruzipain interaction suggests that chagasin may dock to the cruzipain active site in a similar manner with the conserved NPTTG motif of chagasin forming a loop that is similar to the wedge structures formed at the active sites of papain and cathepsin L by stefin and p41.     

Structural basis of cellular redox regulation by human TRP14

Thioredoxin-related protein 14 (TRP14) is involved in regulating tumor necrosis factor-alpha-induced signaling pathways in a different manner from human thioredoxin 1 (Trx1). Here, we report the crystal structure of human TRP14 determined at 1.8-A resolutions. The structure reveals a typical thioredoxin fold with characteristic structural features that account for the substrate specificity of the protein. The surface of TRP14 in the vicinity of the active site includes an extended loop and an additional alpha-helix, and the distribution of charged residues in the surface is different from Trx1. The distinctive dipeptide between the redox-active cysteines contributes to stabilizing the thiolate anion of the active site cysteine 43, increasing reactivity of the cysteine toward substrates. These structural differences in the active site suggest that TRP14 has evolved to regulate cellular redox signaling by recognizing a distinctive group of substrates that would complement the group of proteins regulated by Trx1.