Molecular characterization of Bacillus pasteurii UreE, a metal-binding chaperone for the assembly of the urease active site

The present study describes the cloning, isolation, and thorough biochemical characterization of UreE from Bacillus pasteurii, a novel protein putatively involved in the transport of Ni in the urease assembly process. A DNA fragment of the B. pasteurii urease operon, containing all four accessory genes (ureE, ureF, ureG, and ureD) required for the incorporation of Ni ions into the active site of urease, was cloned, sequenced, and analyzed. B. pasteurii ureE was cloned, and the UreE protein (BpUreE) was over-expressed and purified to homogeneity. The identity of the recombinant protein was determined by N- and C-terminal sequencing and by mass spectrometry. BpUreE has a chain length of 147 amino acids, and features a p I value of 4.7. As isolated, BpUreE contains one Zn(II) ion per dimer, while no Ni(II) is present, as shown by mass spectrometry and atomic absorption spectroscopy. BpUreE behaves as a dimer independently of the presence of Zn(II), as shown by gel filtration and mass spectrometry. Paramagnetic NMR spectroscopy on concentrated (2 mM) UreE solutions reveals a one Ni atom per tetramer stoichiometry, with the Ni(II) ion bound to histidines in an octahedral coordination environment. BpUreE has a high sequence similarity with UreE proteins isolated from different biological sources, while no sequence homology is observed with proteins belonging to different classes. In particular, BpUreE is most similar to UreE from Bacillus halodurans (55% identity). A multiple sequence alignment reveals the presence of four strictly conserved residues (Leu55, Gly97, Asn98, His100; BpUreE numbering), in addition to position 115, conservatively occupied by an Asp or a Glu residue. Several secondary structure elements, including a betaalphabetabetaalphabeta "ferredoxin-like" motif, are highly conserved throughout the UreE sequences.     

Structural characterization of the nickel-binding properties of Bacillus pasteurii urease accessory protein (Ure)E in solution

Urease activation is critical to the virulence of many human and animal pathogens. Urease possesses multiple, nickel-containing active sites, and UreE, the only nickel-binding protein among the urease accessory proteins, activates urease by transporting nickel ions. We performed NMR experiments to investigate the solution structure and the nickel-binding properties of Bacillus pasteurii (Bp) UreE. The secondary structures and global folds of BpUreE were determined for its metal-free and nickel-bound forms. The results indicated that no major structural change of BpUreE arises from the nickel binding. In addition to the previously identified nickel-binding site (Gly(97)-Cys(103)), the C-terminal tail region (Lys(141)-His(147)) was confirmed for the first time to be involved in the nickel binding. The C-terminally conserved sequence ((144)GHQH(147)) was confirmed to have an inherent nickel-binding ability. Nickel addition to 1.6 mm subunit, a concentration where BpUreE predominantly forms a tetramer upon the nickel binding, induced a biphasic spectral change consistent with binding of up to at least three nickel ions per tetrameric unit. In contrast, nickel addition to 0.1 mm subunit, a concentration at which the protein is primarily a dimer, caused a monophasic spectral change consistent with more than 1 equivalent per dimeric unit. Combined with the equilibrium dialysis results, which indicated 2.5 nickel equivalents binding per dimer at a micromolar protein concentration, the nickel-binding stoichiometry of BpUreE at a physiological concentration could be three nickel ions per dimer. Altogether, the present results provide the first detailed structural data concerning the nickel-binding properties of intact, wild-type BpUreE in solution.     

Structural basis for Ni(2+) transport and assembly of the urease active site by the metallochaperone UreE from Bacillus pasteurii

Bacillus pasteurii UreE (BpUreE) is a putative chaperone assisting the insertion of Ni(2+) ions in the active site of urease. The x-ray structure of the protein has been determined for two crystal forms, at 1.7 and 1.85 A resolution, using SIRAS phases derived from a Hg(2+)-derivative. BpUreE is composed of distinct N- and C-terminal domains, connected by a short flexible linker. The structure reveals the topology of an elongated homodimer, formed by interaction of the two C-terminal domains through hydrophobic interactions. A single Zn(2+) ion bound to four conserved His-100 residues, one from each monomer, connects two dimers resulting in a tetrameric BpUreE known to be formed in concentrated solutions. The Zn(2+) ion can be replaced by Ni(2+) as shown by anomalous difference maps obtained on a crystal of BpUreE soaked in a solution containing NiCl(2). A large hydrophobic patch surrounding the metal ion site is surface-exposed in the biologically relevant dimer. The BpUreE structure represents the first for this class of proteins and suggests a possible role for UreE in the urease nickel-center assembly.     

Nickel-binding properties of the C-terminal tail peptide of Bacillus pasteurii UreE

Urease activation, which is critical to the virulence of many human and animal pathogens, is mediated by several accessory proteins. UreE, the only nickel-binding protein among the urease accessory proteins, catalyzes the activation of urease by transporting nickel ions into the urease active sites. The nickel-binding properties of UreE are still not clear, particularly for the protein from Bacillus pasteurii (Bp). Since the flexible C-terminal tail of BpUreE possesses two conserved histidines, the nickel-binding properties of the tail peptide were examined by circular dichroism spectroscopy, size-exclusion chromatography, and nuclear magnetic resonance spectroscopy. Specific nickel binding leading to alteration of the peptide backbone geometry was clearly observed. Side-chains of the two conserved histidines were identified as the main ligands for nickel coordination. The peptide became dimerized upon nickel binding and the binding stoichiometry was estimated as 1 equivalent of nickel per peptide dimer. Altogether, it is postulated that the C-terminal tail of BpUreE contributes to the nickel binding of the protein in different ways between the dimeric and tetrameric protein folds.     

The nickel site of Bacillus pasteurii UreE, a urease metallo-chaperone, as revealed by metal-binding studies and X-ray absorption spectroscopy

UreE is a homodimeric metallo-chaperone that assists the insertion of Ni(2+) ions in the active site of urease. The crystal structures of UreE from Bacillus pasteurii and Klebsiella aerogenes have been determined, but the details of the nickel-binding site were not elucidated due to solid-state effects that caused disorder in a key portion of the protein. A complementary approach to this problem is described here. Titrations of wild-type Bacillus pasteurii UreE (BpUreE) with Ni(2+), followed by metal ion quantitative analysis using inductively coupled plasma optical emission spectrometry (ICP-OES), established the binding of 2 Ni(2+) ions to the functional dimer, with an overall dissociation constant K(D) = 35 microM. To establish the nature, the number, and the geometry of the ligands around the Ni(2+) ions in BpUreE-Ni(2), X-ray absorption spectroscopy data were collected and analyzed using an approach that combines ab initio extended X-ray absorption fine structure (EXAFS) calculations with a systematic search of several possible coordination geometries, using the Simplex algorithm. This analysis indicated the presence of Ni(2+) ions in octahedral coordination geometry and an average of two histidine residues and four O/N ligands bound to each metal ion. The fit improved significantly with the incorporation, in the model, of a Ni-O-Ni moiety, suggesting the presence of a hydroxide-bridged dinuclear cluster in the Ni-loaded BpUreE. These results were interpreted using two possible models. One model involves the presence of two identical metal sites binding Ni(2+) with negative cooperativity, with each metal ion bound to the conserved His(100) as well as to either His(145) or His(147) from each monomer, residues found largely conserved at the C-terminal. The alternative model comprises the presence of two different binding sites featuring different affinity for Ni(2+). This latter model would involve the presence of a dinuclear metallic core, with one Ni(2+) ion bound to one His(100) from each monomer, and the second Ni(2+) ion bound to a pair of either His(145) or His(147). The arguments in favor of one model as compared to the other are discussed on the basis of the available biochemical data.     

Single-step purification of Proteus mirabilis urease accessory protein UreE, a protein with a naturally occurring histidine tail, by nickel chelate affinity chromatography.

Proteus mirabilis urease, a nickel metalloenzyme, is essential for the virulence of this species in the urinary tract. Escherichia coli containing cloned structural genes ureA, ureB, and ureC and accessory genes ureD, ureE, ureF, and ureG displays urease activity when cultured in M9 minimal medium. To study the involvement of one of these accessory genes in the synthesis of active urease, deletion mutations were constructed. Cultures of a ureE deletion mutant did not produce an active urease in minimal medium. Urease activity, however, was partially restored by the addition of 5 microM NiCl2 to the medium. The predicted amino acid sequence of UreE, which concludes with seven histidine residues among the last eight C-terminal residues (His-His-His-His-Asp-His-His-His), suggested that UreE may act as a Ni2+ chelator for the urease operon. To exploit this potential metal-binding motif, we attempted to purify UreE from cytoplasmic extracts of E. coli containing cloned urease genes. Soluble protein was loaded onto a nickel-nitrilotriacetic acid column, a metal chelate resin with high affinity for polyhistidine tails, and bound protein was eluted with a 0 to 0.5 M imidazole gradient. A single polypeptide of 20-kDa apparent molecular size, as shown by sodium dodecyl sulfate-10 to 20% polyacrylamide gel electrophoresis, was eluted between 0.25 and 0.4 M imidazole. The N-terminal 10 amino acids of the eluted polypeptide exactly matched the deduced amino acid sequence of P. mirabilis UreE. The molecular size of the native protein was estimated on a Superdex 75 column to be 36 kDa, suggesting that the protein is a dimer. These data suggest that UreE is a Ni(2)+-binding protein that is necessary for synthesis of a catalytically active urease at low Ni(2+) concentrations.     

Crystallographic and X-ray absorption spectroscopic characterization of Helicobacter pylori UreE bound to Ni²⁺ and Zn²⁺ reveals a role for the disordered C-terminal arm in metal trafficking

The survival and growth of the pathogen Helicobacter pylori in the gastric acidic environment is ensured by the activity of urease, an enzyme containing two essential Ni2? ions in the active site. The metallo-chaperone UreE facilitates in vivo Ni2? insertion into the apoenzyme. Crystals of apo-HpUreE (H. pylori UreE) and its Ni?- and Zn?-bound forms were obtained from protein solutions in the absence and presence of the metal ions. The crystal structures of the homodimeric protein, determined at 2.00 ? (apo), 1.59 ? (Ni2?) and 2.52 ? (Zn2?) resolution, show the conserved proximal and solvent-exposed His1?2 residues from two adjacent monomers invariably involved in metal binding. The C-terminal regions of the apoprotein are disordered in the crystal, but acquire significant ordering in the presence of the metal ions due to the binding of His1?2. The analysis of X-ray absorption spectral data obtained using solutions of Ni2?- and Zn2?-bound HpUreE provided accurate information of the metal-ion environment in the absence of solid-state effects. These results reveal the role of the histidine residues at the protein C-terminus in metal-ion binding, and the mutual influence of protein framework and metal-ion stereo-electronic properties in establishing co-ordination number and geometry leading to metal selectivity.     

Molecular landscape of the interaction between the urease accessory proteins UreE and UreG

Urease, the most efficient enzyme so far discovered, depends on the presence of nickel ions in the catalytic site for its activity. The transformation of inactive apo-urease into active holo-urease requires the insertion of two Ni(II) ions in the substrate binding site, a process that involves the interaction of four accessory proteins named UreD, UreF, UreG and UreE. This study, carried out using calorimetric and NMR-based structural analysis, is focused on the interaction between UreE and UreG from Sporosarcina pasteurii, a highly ureolytic bacterium. Isothermal calorimetric protein–protein titrations revealed the occurrence of a binding event between SpUreE and SpUreG, entailing two independent steps with positive cooperativity (K_d1 = 42 ± 9 μM; K_d2 = 1.7 ± 0.3 μM). This was interpreted as indicating the formation of the (UreE)₂(UreG)₂ hetero-oligomer upon binding of two UreG monomers onto the pre-formed UreE dimer. The molecular details of this interaction were elucidated using high-resolution NMR spectroscopy. The occurrence of SpUreE chemical shift perturbations upon addition of SpUreG was investigated and analyzed to establish the protein–protein interaction site. The latter appears to involve the Ni(II) binding site as well as mobile portions on the C-terminal and the N-terminal domains. Docking calculations based on the information obtained from NMR provided a structural basis for the protein–protein contact site. The high sequence and structural similarity within these protein classes suggests a generality of the interaction mode among homologous proteins. The implications of these results on the molecular details of the urease activation process are considered and analyzed.     

The UreEF fusion protein provides a soluble and functional form of the UreF urease accessory protein

Four accessory proteins (UreD, UreE, UreF, and UreG) are typically required to form the nickel-containing active site in the urease apoprotein (UreABC). Among the accessory proteins, UreD and UreF have been elusive targets for biochemical and structural characterization because they are not overproduced as soluble proteins. Using the best-studied urease system, in which the Klebsiella aerogenes genes are expressed in Escherichia coli, a translational fusion of ureE and ureF was generated. The UreEF fusion protein was overproduced as a soluble protein with a convenient tag involving the His-rich region of UreE. The fusion protein was able to form a UreD(EF)G-UreABC complex and to activate urease in vivo, and it interacted with UreD-UreABC in vitro to form a UreD(EF)-UreABC complex. While the UreF portion of UreEF is fully functional, the fusion significantly affected the role of the UreE portion by interrupting its dimerization and altering its metal binding properties compared to those of the wild-type UreE. Analysis of a series of UreEF deletion mutants revealed that the C terminus of UreF is required to form the UreD(EF)G-UreABC complex, while the N terminus of UreF is essential for activation of urease.     

Multiple protein sequence alignment

Multiple sequence alignments are essential in computational analysis of protein sequences and structures, with applications in structure modeling, functional site prediction, phylogenetic analysis and sequence database searching. Constructing accurate multiple alignments for divergent protein sequences remains a difficult computational task, and alignment speed becomes an issue for large sequence datasets. Here, I review methodologies and recent advances in the multiple protein sequence alignment field, with emphasis on the use of additional sequence and structural information to improve alignment quality.     

Crystal structure of Klebsiella aerogenes UreE, a nickel-binding metallochaperone for urease activation

UreE is proposed to be a metallochaperone that delivers nickel ions to urease during activation of this bacterial virulence factor. Wild-type Klebsiella aerogenes UreE binds approximately six nickel ions per homodimer, whereas H144*UreE (a functional C-terminal truncated variant) was previously reported to bind two. We determined the structure of H144*UreE by multi-wavelength anomalous diffraction and refined it to 1.5 A resolution. The present structure reveals an Hsp40-like peptide-binding domain, an Atx1-like metal-binding domain, and a flexible C terminus. Three metal-binding sites per dimer, defined by structural analysis of Cu-H144*UreE, are on the opposite face of the Atx1-like domain than observed in the copper metallochaperone. One metal bridges the two subunits via the pair of His-96 residues, whereas the other two sites involve metal coordination by His-110 and His-112 within each subunit. In contrast to the copper metallochaperone mechanism involving thiol ligand exchanges between structurally similar chaperones and target proteins, we propose that the Hsp40-like module interacts with urease apoprotein and/or other urease accessory proteins, while the Atx1-like domain delivers histidyl-bound nickel to the urease active site.     

Klebsiella aerogenes UreF: identification of the UreG binding site and role in enhancing the fidelity of urease activation

The Ni-containing active site of Klebsiella aerogenes urease is assembled through the concerted action of the UreD, UreE, UreF, and UreG accessory proteins. UreE functions as a metallochaperone that delivers Ni to a UreD-UreF-UreG complex bound to urease apoprotein, with UreG serving as a GTPase during enzyme activation. This study focuses on the role of UreF, previously proposed to act as a GTPase activating protein (GAP) of UreG. Sixteen conserved UreF surface residues that may play roles in protein-protein interactions were independently changed to Ala. When produced in the context of the entire urease gene cluster, cell-free extracts of nine site-directed mutants had less than 10% of the wild-type urease activity. Enrichment of the variant forms of UreF, as the UreE-F fusion proteins, uniformly resulted in copurification of UreD and urease apoprotein, whereas UreG bound to only a subset of the species. Notably, weakened interaction with UreG correlated with the low-activity mutants. The affected residues in UreF map to a distinct surface on the crystal structure, defining the UreG binding site. In contrast to the hypothesis that UreF is a GAP, the UreD-UreF-UreG-urease apoprotein complex containing K165A UreF exhibited significantly greater levels of GTPase activity than that containing the wild-type protein. Additional studies demonstrated the UreG GTPase activity was largely uncoupled from urease activation for the complex containing this UreF variant. Further experiments with these complexes provided evidence that UreF gates the GTPase activity of UreG to enhance the fidelity of urease metallocenter assembly, especially in the presence of the noncognate metal Zn.     

A model-based proposal for the role of UreF as a GTPase-activating protein in the urease active site biosynthesis

UreF is a protein that plays a role in the in vivo urease activation as a chaperone involved in the insertion of two Ni(2+) ions in the apo-urease active site. The molecular details of this process are unknown. In the absence of any molecular information on the UreF protein class, and as a step toward the comprehension of the relationships between UreF function and structure, we applied a structural modeling approach to infer useful biochemical knowledge on Bacillus pasteurii UreF (BpUreF). Similarity searches and multiple alignment of UreF protein sequences indicated that this class of proteins has a low homology with proteins of known structure. Fold recognition methods were therefore used to identify useful protein structural templates to model the structure of BpUreF. In particular, the templates belong to the class of GTPase-activating proteins. Modeling of BpUreF based on these templates was performed using the program MODELLER. The structure validation yielded good statistics, indicating that the model is plausible. This result suggests a role for UreF in urease active site biosynthesis as a regulator of the activity of UreG, a small G protein involved in the in vivo apo-urease activation process and established to catalyze GTP hydrolysis.     

Dependence of Helicobacter pylori urease activity on the nickel-sequestering ability of the UreE accessory protein

The Helicobacter pylori ureE gene product was previously shown to be required for urease expression, but its characteristics and role have not been determined. The UreE protein has now been overexpressed in Escherichia coli, purified, and characterized, and three altered versions were expressed to address a nickel-sequestering role of UreE. Purified UreE formed a dimer in solution and was capable of binding one nickel ion per dimer. Introduction of an extra copy of ureE into the chromosome of mutants carrying mutations in the Ni maturation proteins HypA and HypB resulted in partial restoration of urease activity (up to 24% of the wild-type levels). Fusion proteins of UreE with increased ability to bind nickel were constructed by adding histidine-rich sequences (His-6 or His-10 to the C terminus and His-10 as a sandwich fusion) to the UreE protein. Each fusion protein was overexpressed in E. coli and purified, and its nickel-binding capacity and affinity were determined. Each construct was also expressed in wild-type H. pylori and in hypA and hypB mutant strains for determining in vivo urease activities. The urease activity was increased by introduction of all the engineered versions, with the greatest Ni-sequestering version (the His-6 version) also conferring the greatest urease activity on both the hypA and hypB mutants. The differences in urease activities were not due to differences in the amounts of urease peptides. Addition of His-6 to another expressed protein (triose phosphate isomerase) did not result in stimulation of urease, so urease activation is not related to the level of nonspecific protein-bound nickel. The results indicate a correlation between H. pylori urease activity and the nickel-sequestering ability of the UreE accessory protein.     

Identification of metal-binding residues in the Klebsiella aerogenes urease nickel metallochaperone, UreE

The urease accessory protein encoded by ureE from Klebsiella aerogenes is proposed to bind intracellular Ni(II) for transfer to urease apoprotein. While native UreE possesses a histidine-rich region at its carboxyl terminus that binds several equivalents of Ni, the Ni-binding sites associated with urease activation are internal to the protein as shown by studies involving truncated H144UreE [Brayman and Hausinger (1996) J. Bacteriol. 178, 5410-5416]. Nine potential Ni-binding residues (five His, two Cys, one Asp, and one Tyr) within H144UreE were independently substituted by mutagenesis to determine their roles in metal binding and urease activation. In vivo effects of these substitutions on urease activity were measured in Escherichia coli strains containing the K. aerogenes urease gene cluster with the mutated ureE genes. Several mutational changes led to reductions in specific activity, with substitution of His96 producing urease activity below the level obtained from a ureE deletion mutant. The metal-binding properties of purified variant UreE proteins were characterized by a combination of equilibrium dialysis and UV/visible, EPR, and hyperfine-shifted 1H NMR spectroscopic methods. Ni binding was unaffected for most H144UreE variants, but mutant proteins substituted at His110 or His112 exhibited greatly reduced affinity for Ni and bound one, rather than two, metal ions per dimer. Cys79 was identified as the Cu ligand responsible for the previously observed charge-transfer transition at 370 nm, and His112 also was shown to be associated with this chromophoric site. NMR spectroscopy provided clear evidence that His96 and His110 serve as ligands to Ni or Co. The results from these and other studies, in combination with prior spectroscopic findings for metal-substituted UreE [Colpas et al. (1998) J. Biol. Inorg. Chem. 3, 150-160], allow us to propose that the homodimeric protein possesses two nonidentical metal-binding sites, each symmetrically located at the dimer interface. The first equivalent of added Ni or Co binds via His96 and His112 residues from each subunit of the dimer, and two other N or O donors. Asp111 either functions as a ligand or may affect this site by secondary interactions. The second equivalent of Ni or Co binds via the symmetric pair of His110 residues as well as four other N or O donors. In contrast, the first equivalent of Cu binds via the His110 pair and two other N/O donors, while the second equivalent of Cu binds via the His112 pair and at least one Cys79 residue. UreE sequence comparisons among urease-containing microorganisms reveal that residues His96 and Asp111, associated with the first site of Ni binding, are highly conserved, while the other targeted residues are missing in many cases. Our data are most compatible with one Ni-binding site per dimer being critical for UreE's function as a metallochaperone.     

Purification, characterization, and functional analysis of a truncated Klebsiella aerogenes UreE urease accessory protein lacking the histidine-rich carboxyl terminus.

Klebsiella aerogenes UreE, one of four accessory proteins involved in urease metallocenter assembly, contains a histidine-rich C terminus (10 of the last 15 residues) that is likely to participate in metal ion coordination by this nickel-binding protein. To study the function of the histidine-rich region in urease activation, ureE in the urease gene cluster was mutated to result in synthesis of a truncated peptide, H144* UreE, lacking the final 15 residues. Urease activity in cells containing H144* UreE approached the activities for cells possessing the wild-type protein at nickel ion concentrations ranging from 0 to 1 mM in both nutrient-rich and minimal media. In contrast, clear reductions in urease activities were observed when two ureE deletion mutant strains were examined, especially at lower nickel ion concentrations. Surprisingly, the H144* UreE, like the wild-type protein, was readily purified with a nickel-nitrilotriacetic acid resin. Denaturing polyacrylamide gel electrophoretic analysis and N-terminal sequencing confirmed that the protein was a truncated UreE. Size exclusion chromatography indicated that the H144* UreE peptide associated into a homodimer, as known for the wild-type protein. The truncated protein was shown to cooperatively bind 1.9 +/- 0.2 Ni(II) ions as assessed by equilibrium dialysis measurements, compared with the 6.05 +/- 0.25 Ni ions per dimer reported previously for the native protein. These results demonstrate that the histidine-rich motif is not essential to UreE function and is not solely responsible for UreE nickel-binding ability. Rather, we propose that internal nickel binding sites of UreE participate in urease metallocenter assembly.     

In vivo and in vitro kinetics of metal transfer by the Klebsiella aerogenes urease nickel metallochaperone, UreE

The urease accessory protein encoded by ureE from Klebsiella aerogenes is proposed to deliver Ni(II) to the urease apoprotein during enzyme activation. Native UreE possesses a histidine-rich region at its carboxyl terminus that binds several equivalents of Ni(2+); however, a truncated form of this protein (H144*UreE) binds only 2 Ni(2+) per dimer and is functionally active (Brayman, T. G., and Hausinger, R. P. (1996) J. Bacteriol. 178, 5410-5416). The urease activation kinetics were studied in vivo by monitoring the development of urease activity upon adding Ni(2+) to spectinomycin-treated Escherichia coli cells that expressed the complete K. aerogenes urease gene cluster with altered forms of ureE. Site-specific alterations of H144*UreE decrease the rate of in vivo urease activation, with the most dramatic changes observed for the H96A, H110A, D111A, and H112A substitutions. Notably, urease activity in cells producing H96A/H144*UreE was lower than cells containing a ureE deletion. Prior studies had shown that H110A and H112A variants each bound a single Ni(2+) per dimer with elevated K(d) values compared with control H144*UreE, whereas the H96A and D111A variants bound 2 Ni(2+) per dimer with unperturbed K(d) values (Colpas, G. J., Brayman, T. G., Ming, L.-J., and Hausinger, R. P. (1999) Biochemistry 38, 4078-4088). To understand why cells containing the latter two proteins showed reduced rates of urease activation, we characterized their metal binding/dissociation kinetics and compared the results to those obtained for H144*UreE. The truncated protein was shown to sequentially bind two Ni(2+) with k(1) approximately 18 and k(2) approximately 100 M(-1) s(-1), and with dissociation rates k(-1) approximately 3 x 10(-3) and k(-2) approximately 10(-4) s(-1). Similar apparent rates of binding and dissociation were noted for the two mutant proteins, suggesting that altered H144*UreE interactions with Ni(2+) do not account for the changes in cellular urease activation. These conclusions are further supported by in vitro experiments demonstrating that addition of H144*UreE to urease apoprotein activation mixtures inhibited the rate and extent of urease formation. Our results highlight the importance of other urease accessory proteins in assisting UreE-dependent urease maturation.     

Accurate detection of very sparse sequence motifs.

Protein sequence alignments are more reliable the shorter the evolutionary distance. Here, we align distantly related proteins using many closely spaced intermediate sequences as stepping stones. Such transitive alignments can be generated between any two proteins in a connected set, whether they are direct or indirect sequence neighbors in the underlying library of pairwise alignments. We have implemented a greedy algorithm, MaxFlow, using a novel consistency score to estimate the relative likelihood of alternative paths of transitive alignment. In contrast to traditional profile models of amino acid preferences, MaxFlow models the probability that two positions are structurally equivalent and retains high information content across large distances in sequence space. Thus, MaxFlow is able to identify sparse and narrow active-site sequence signatures which are embedded in high-entropy sequence segments in the structure based multiple alignment of large diverse enzyme superfamilies. In a challenging benchmark based on the urease superfamily, MaxFlow yields better reliability and double coverage compared to available sequence alignment software. This promises to increase information returns from functional and structural genomics, where reliable sequence alignment is a bottleneck to transferring the functional or structural characterization of model proteins to entire protein superfamilies.     

MUSTANG: a multiple structural alignment algorithm

Multiple structural alignment is a fundamental problem in structural genomics. In this article, we define a reliable and robust algorithm, MUSTANG (MUltiple STructural AligNment AlGorithm), for the alignment of multiple protein structures. Given a set of protein structures, the program constructs a multiple alignment using the spatial information of the C(alpha) atoms in the set. Broadly based on the progressive pairwise heuristic, this algorithm gains accuracy through novel and effective refinement phases. MUSTANG reports the multiple sequence alignment and the corresponding superposition of structures. Alignments generated by MUSTANG are compared with several handcurated alignments in the literature as well as with the benchmark alignments of 1033 alignment families from the HOMSTRAD database. The performance of MUSTANG was compared with DALI at a pairwise level, and with other multiple structural alignment tools such as POSA, CE-MC, MALECON, and MultiProt. MUSTANG performs comparably to popular pairwise and multiple structural alignment tools for closely related proteins, and performs more reliably than other multiple structural alignment methods on hard data sets containing distantly related proteins or proteins that show conformational changes.