Structure of the full-length major pilin from Streptococcus pneumoniae: implications for isopeptide bond formation in gram-positive bacterial pili

The surface of the pneumococcal cell is adorned with virulence factors including pili. The major pilin RrgB, which forms the pilus shaft on pathogenic Streptococcus pneumoniae, comprises four immunoglobulin (Ig)-like domains, each with a common CnaB topology. The three C-terminal domains are each stabilized by internal Lys-Asn isopeptide bonds, formed autocatalytically with the aid of an essential Glu residue. The structure and orientation of the crucial N-terminal domain, which provides the covalent linkage to the next pilin subunit in the shaft, however, remain incompletely characterised. We report the crystal structure of full length RrgB, solved by X-ray crystallography at 2.8 Å resolution. The N-terminal (D1) domain makes few contacts with the rest of the RrgB structure, and has higher B-factors. This may explain why D1 is readily lost by proteolysis, as are the N-terminal domains of many major pilins. D1 is also found to have a triad of Lys, Asn and Glu residues in the same topological positions as in the other domains, yet mass spectrometry and the crystal structure show that no internal isopeptide bond is formed. We show that this is because β-strand G of D1, which carries the Asn residue, diverges from β-strand A, carrying the Lys residue, such that these residues are too far apart for bond formation. Strand G also carries the YPKN motif that provides the essential Lys residue for the sortase-mediated intermolecular linkages along the pilus shaft. Interaction with the sortase and formation of the intermolecular linkage could result in a change in the orientation of this strand, explaining why isopeptide bond formation in the N-terminal domains of some major pilins appears to take place only upon assembly of the pili.     

Two Intramolecular Isopeptide Bonds are Identified in the Crystal Structure of the Streptococcus gordonii SspB C-terminal Domain

Streptococcus gordonii is a primary colonizer and is involved in the formation of dental plaque. This bacterium expresses several surface proteins. One of them is the adhesin SspB, which is a member of the Antigen I/II family of proteins. SspB is a large multi-domain protein that has interactions with surface molecules on other bacteria and on host cells, and is thus a key factor in the formation of biofilms. Here, we report the crystal structure of a truncated form of the SspB C-terminal domain, solved by single-wavelength anomalous dispersion to 1.5 Å resolution. The structure represents the first of a C-terminal domain from a streptococcal Antigen I/II protein and is comprised of two structurally related β-sandwich domains, C2 and C3, both with a Ca²⁺ bound in equivalent positions. In each of the domains, a covalent isopeptide bond is observed between a lysine and an asparagine, a feature that is believed to be a common stabilization mechanism in Gram-positive surface proteins. S. gordonii biofilms contain attachment sites for the periodontal pathogen Porphyromonas gingivalis and the SspB C-terminal domain has been shown to have one such recognition motif, the SspB adherence region. The motif protrudes from the protein, and serves as a handle for attachment. The structure suggests several additional putative binding surfaces, and other binding clefts may be created when the full-length protein is folded.     

Solution structure of the RIM1alpha PDZ domain in complex with an ELKS1b C-terminal peptide

PDZ domains are widespread protein modules that commonly recognize C-terminal sequences of target proteins and help to organize macromolecular signaling complexes. These sequences usually bind in an extended conformation to relatively shallow grooves formed between a beta-strand and an alpha-helix in the corresponding PDZ domains. Because of this binding mode, many PDZ domains recognize primarily the C-terminal and the antepenultimate side-chains of the target protein, which commonly conform to motifs that have been categorized into different classes. However, an increasing number of PDZ domains have been found to exhibit unusual specificities. These include the PDZ domain of RIMs, which are large multidomain proteins that regulate neurotransmitter release and help to organize presynaptic active zones. The RIM PDZ domain binds to the C-terminal sequence of ELKS with a unique specificity that involves each of the four ELKS C-terminal residues. To elucidate the structural basis for this specificity, we have determined the 3D structure in solution of an RIM/ELKS C-terminal peptide complex using NMR spectroscopy. The structure shows that the RIM PDZ domain contains an unusually deep and narrow peptide-binding groove with an exquisite shape complementarity to the four ELKS C-terminal residues in their bound conformation. This groove is formed, in part, by a set of side-chains that is conserved selectively in RIM PDZ domains and that hence determines, at least in part, their unique specificity.     

Structural and functional characterization of the Streptococcus pneumoniae RrgB pilus backbone D1 domain

Streptococcus pneumoniae expresses on its surface adhesive pili, involved in bacterial attachment to epithelial cells and virulence. The pneumococcal pilus is composed of three proteins, RrgA, RrgB, and RrgC, each stabilized by intramolecular isopeptide bonds and covalently polymerized by means of intermolecular isopeptide bonds to form an extended fiber. RrgB is the pilus scaffold subunit and is protective in vivo in mouse models of sepsis and pneumonia, thus representing a potential vaccine candidate. The crystal structure of a major RrgB C-terminal portion featured an organization into three independently folded protein domains (D2-D4), whereas the N-terminal D1 domain (D1) remained unsolved. We have tested the four single recombinant RrgB domains in active and passive immunization studies and show that D1 is the most effective, providing a level of protection comparable with that of the full-length protein. To elucidate the structural features of D1, we solved the solution structure of the recombinant domain by NMR spectroscopy. The spectra analysis revealed that D1 has many flexible regions, does not contain any intramolecular isopeptide bond, and shares with the other domains an Ig-like fold. In addition, we demonstrated, by site-directed mutagenesis and complementation in S. pneumoniae, that the D1 domain contains the Lys residue (Lys-183) involved in the formation of the intermolecular isopeptide bonds and pilus polymerization. Finally, we present a model of the RrgB protein architecture along with the mapping of two surface-exposed linear epitopes recognized by protective antisera.     

Model for the three-dimensional structure of vitronectin: predictions for the multi-domain protein from threading and docking.

The structure of vitronectin, an adhesive protein that circulates in high concentrations in human plasma, was predicted through a combination of computational methods and experimental approaches. Fold recognition and sequence-structure alignment were performed using the threading program PROSPECT for each of three structural domains, i.e., the N-terminal somatomedin B domain (residues 1-53), the central region that folds into a four-bladed beta-propeller domain (residues 131-342), and the C-terminal heparin-binding domain (residues 347-459). The atomic structure of each domain was generated using MODELLER, based on the alignment obtained from threading. Docking experiments between the central and C-terminal domains were conducted using the program GRAMM, with limits on the degrees of freedom from a known inter-domain disulfide bridge. The docked structure has a large inter-domain contact surface and defines a putative heparin-binding groove at the inter-domain interface. We also docked heparin together with the combined structure of the central and C-terminal domains, using GRAMM. The predictions from the threading and docking experiments are consistent with experimental data on purified plasma vitronectin pertaining to protease sensitivity, ligand-binding sites, and buried cysteines.     

Intramolecular Isopeptide Bonds Give Thermodynamic and Proteolytic Stability to the Major Pilin Protein of Streptococcus pyogenes

The pili expressed by Streptococcus pyogenes and certain other Gram-positive bacterial pathogens are based on a polymeric backbone in which individual pilin subunits are joined end-to-end by covalent isopeptide bonds through the action of sortase enzymes. The crystal structure of the major pilin of S. pyogenes, Spy0128, revealed that each domain of the two domain protein contained an intramolecular isopeptide bond cross-link joining a Lys side chain to an Asn side chain. In the present work, mutagenesis was used to create mutant proteins that lacked either one isopeptide bond (E117A, N168A, and E258A mutants) or both isopeptide bonds (E117A/E258A). Both the thermal stability and proteolytic stability of Spy0128 were severely compromised by loss of the isopeptide bonds. Unfolding experiments, monitored by circular dichroism, revealed a transition temperature T_m of 85 °C for the wild type protein. In contrast, mutants with only one isopeptide bond showed biphasic unfolding, with the domain lacking an isopeptide bond having a T_m that was ∼30 °C lower than the unaltered domain. High resolution crystal structures of the E117A and N168A mutants showed that the loss of an isopeptide bond did not change the overall pilin structure but caused local disturbance of the protein core that was greater for E117A than for N168A. These effects on stability appear also to be important for pilus assembly.The stability of a globular protein is in general a fine balance between large numbers of weak, noncovalent stabilizing forces (hydrophobic interactions, hydrogen bonds, and ion pairs) and the destabilizing loss of conformational entropy (1). Stability can be greatly enhanced, however, by the presence of a small number of strategically placed covalent bonds, for example those provided by disulfide bonds between Cys residues or by a bound metal ion that bonds to several amino acid side chains. Indeed, some striking examples have been reported in which the introduction of disulfide bonds that link sequentially distant parts of a polypeptide chain can result in large increases in protein stability (2).Our recent discovery of cross-linking isopeptide bonds within the protein subunits of the pili expressed by the Gram-positive organism Streptococcus pyogenes (3) has raised questions as to how these bonds are formed and what they contribute to stability. These pili, which are extremely thin (2–5 nm in diameter) but can extend up to 4 μm from the bacterial cell surface (4), are formed as covalently linked polymers through the action of cysteine transpeptidase enzymes called sortases. In this process, which is common to a number of Gram-positive bacterial pathogens, the pilus backbone is formed from a single protein subunit, the so-called major pilin, by the covalent, end-to-end polymerization of major pilin subunits, generating an assembly resembling beads on a string (5–7). Polymerization requires recognition, by the sortase, of an LPXTG-type sequence motif near the pilin C terminus, cleavage after the Thr residue, and transfer to a specific Lys residue in the next pilin subunit. The resulting amide bond, between the terminal COOH of one subunit and the Lys ϵ-amino group of the next subunit, is referred to as an isopeptide bond.Surprisingly, the three-dimensional structure of Spy0128, the major pilin from the M1 strain of S. pyogenes (group A streptococcus; GAS),² revealed the presence of additional isopeptide bonds as internal cross-links within the protein. These bonds, which were confirmed by mass spectrometry, joined lysine and asparagine side chains (3). One such bond was found within each domain of the two domain protein and, in a similar location, between the first and last strands of the domain (Fig. 1). Isopeptide bonds have until now been recognized for their importance in the intermolecular cross-linking of a variety of proteins, such as in ubiquitination (8), transglutamination (9), and sortase-mediated cell wall anchoring of surface proteins (10), as well as pilus polymerization. In this context, the presence of the intramolecular isopeptide bonds in Spy0128 seemed highly unusual. There has been speculation in the past that such internal bonds could exist, but no mechanism has been put forward, and none has previously been proven to exist.Open in a separate windowFIGURE 1.Overall structure and topology of Spy0128 with internal isopeptide bonds. A, the structure of Spy0128 is shown in ribbon representation with the N terminus (N) and C terminus (C) marked. The isopeptide bond in each of the N and C domains is shown as spheres with residue labels next to them. The residue forming the intersubunit bond, Lys¹⁶¹, is shown in stick mode. The sortase recognition motif, EVPTG, is shown as a dotted line at the C terminus of the structure. B, the topology diagram of Spy0128 is color-coded in rainbow from blue (N terminus) to red (C terminus). The position of Lys¹⁶¹ is indicated by the red arrowhead, and the positions of the isopeptide bonds are indicated by black bars. C, the N domain isopeptide bond of Spy0128 between Lys³⁶ and Asn¹⁶⁸ and the catalytic residue Glu¹¹⁷ are shown in ball-and-stick mode.The locations of the two internal Lys-Asn isopeptide bonds in Spy0128 immediately suggested that they are self-generated, each being the result of an intramolecular reaction. Mutagenesis showed that bond formation was in each case dependent on an adjacent Glu residue, Glu¹¹⁷ in the N-terminal domain and Glu²⁵⁸ in the C-terminal domain; mutation of either of these Glu residues to Ala abrogated the formation of the associated isopeptide bond (3). A close parallel exists in the self-generated Lys-Asn isopeptide bonds that form during maturation of the protein coat of the bacteriophage HK97, where a nearby Glu residue is essential for the reaction, and the capsid subunits become covalently linked to form interlocked circular rings referred to as chain mail (11, 12).Further investigations have shown that similar isopeptide bonds can be found as internal cross-links in other proteins. Examination of previously determined structures of a minor pilin GBS52 from Streptococcus agalactiae (13) and the CnaA and CnaB domains of a collagen-binding adhesin from Staphylococcus aureus (14–16) revealed constellations of Lys-Asn-Glu/Asp residues similar to those that form the internal cross-links in Spy0128, and examination of the electron density confirmed their probable presence in those cases where the x-ray data were available (3). Sequence comparisons showed that similar domains, with corresponding Lys-Asn-Glu/Asp residues, are present in many cell surface proteins of Gram-positive bacteria. Recently the Bacillus cereus major pilin BcpA was shown, by mass spectral analyses, to contain internal isopeptide bonds similar to those in Spy0128 (7), and sequence comparisons point to similar bonds in the major pilins of other species. These data suggest that isopeptide bond cross-links could be important features in many surface proteins involved in adhesive functions, where stability against physical and chemical stresses is important.Here we describe the preparation of mutants of Spy0128 that lack one or both of the internal isopeptide bonds, using mass spectrometry to confirm their absence. We show by x-ray crystallography that the overall structure of Spy0128 is not significantly affected by the loss of an isopeptide bond. We also show, however, that the proteolytic and thermal stability of Spy0128 is severely compromised when the internal isopeptide bonds are removed and thereby establish their important stabilizing role in proteins of this type.     

X-ray structure of simian immunodeficiency virus integrase containing the core and C-terminal domain (residues 50-293)--an initial glance of the viral DNA binding platform

The crystal structure of simian immunodeficiency virus (SIV) integrase that contains in a single polypeptide the core and the C-terminal deoxyoligonucleotide binding domain has been determined at 3 A resolution with an R-value of 0.203 in the space group P2(1)2(1)2(1). Four integrase core domains and one C-terminal domain are found to be well defined in the asymmetric unit. The segment extending from residues 114 to 121 assumes the same position as seen in the integrase core domain of avian sarcoma virus as well as human immunodeficiency virus type-1 (HIV-1) crystallized in the absence of sodium cacodylate. The flexible loop in the active site, composed of residues 141-151, remains incompletely defined, but the location of the essential Glu152 residue is unambiguous. The residues from 210-218 that link the core and C-terminal domains can be traced as an extension from the core with a short gap at residues 214-215. The C(alpha) folding of the C-terminal domain is similar to the solution structure of this domain from HIV-1 integrase. However, the dimeric form seen in the NMR structure cannot exist as related by the non-crystallographic symmetry in the SIV integrase crystal. The two flexible loops of the C-terminal domain, residues 228-236 and residues 244-249, are much better fixed in the crystal structure than in the NMR structure with the former in the immediate vicinity of the flexible loop of the core domain. The interface between the two domains encompasses a solvent-exclusion area of 1500 A(2). Residues from both domains purportedly involved in DNA binding are narrowly distributed on the same face of the molecule. They include Asp64, Asp116, Glu152 and Lys159 from the core and Arg231, Leu234, Arg262, Arg263 and Lys264 from the C-terminal domain. A model for DNA binding is proposed to bridge the two domains by tethering the 228-236 loop of the C-terminal domain and the flexible loop of the core.     

Structure of the C-terminal domain from Trypanosoma brucei variant surface glycoprotein MITat1.2

The variant surface glycoprotein (VSG) of African trypanosomes has a structural role in protecting other cell surface proteins from effector molecules of the mammalian immune system and also undergoes antigenic variation necessary for a persistent infection in a host. Here we have reported the solution structure of a VSG type 2 C-terminal domain from MITat1.2, completing the first structure of both domains of a VSG. The isolated C-terminal domain is a monomer in solution and forms a novel fold, which commences with a short alpha-helix followed by a single turn of 3(10)-helix and connected by a short loop to a small anti-parallel beta-sheet and then a longer alpha-helix at the C terminus. This compact domain is flanked by two unstructured regions. The structured part of the domain contains 42 residues, and the core comprises 2 disulfide bonds and 2 hydrophobic residues. These cysteines and hydrophobic residues are conserved in other VSGs, and we have modeled the structures of two further VSG C-terminal domains using the structure of MITat1.2. The models suggest that the overall structure of the core is conserved in the different VSGs but that the C-terminal alpha-helix is of variable length and depends on the presence of charged residues. The results provided evidence for a conserved tertiary structure for all the type 2 VSG C-terminal domains, indicated that VSG dimers form through interactions between N-terminal domains, and showed that the selection pressure for sequence variation within a conserved tertiary structure acts on the whole of the VSG molecule.     

含磷酸结合口袋的BRCT结构域功能位点预测

BRCT( BRCA1 C-terminus)是真核生物DNA损伤修复系统重要的信号传导和蛋白靶向结构域.为了探讨含磷酸结合口袋的BRCT与磷酸化配体结合的机制,对XRCC1 BRCT1、PTIP BRCT4、ECT2 BRCT1和TopBP1BRCT1进行了结构保守性和表面静电势分析.结果显示,4个BRCT的磷酸结合口袋周围所存在的结构保守并带正电势的沟槽很可能是其功能位点,并且类似的沟槽在含磷酸结合口袋的BRCT中普遍存在.沟槽两侧及底部均带有极性氨基酸残基,两侧带正电荷,而底部疏水.这说明沟槽与配体的结合以静电和疏水相互作用为主.沟槽主要位于单个BRCT中,而且4个BRCT的沟槽在形状和电荷分布上都不同,说确明BRCT配体特异性主要由单个BRCT决定.磷酸结合口袋位于沟槽中心,说明沟槽可能同时结合磷酸化残基的N端和C端附近残基.     

Structure and sequence analyses of Bacteroides proteins BVU_4064 and BF1687 reveal presence of two novel predominantly-beta domains,predicted to be involved in lipid and cell surface interactions

Background

N-terminal domains of BVU_4064 and BF1687 proteins from Bacteroides vulgatus and Bacteroides fragilis respectively are members of the Pfam family PF12985 (DUF3869). Proteins containing a domain from this family can be found in most Bacteroides species and, in large numbers, in all human gut microbiome samples. Both BVU_4064 and BF1687 proteins have a consensus lipobox motif implying they are anchored to the membrane, but their functions are otherwise unknown. The C-terminal half of BVU_4064 is assigned to protein family PF12986 (DUF3870); the equivalent part of BF1687 was unclassified.

Results

Crystal structures of both BVU_4064 and BF1687 proteins, solved at the JCSG center, show strikingly similar three-dimensional structures. The main difference between the two is that the two domains in the BVU_4064 protein are connected by a short linker, as opposed to a longer insertion made of 4 helices placed linearly along with a strand that is added to the C-terminal domain in the BF1687 protein. The N-terminal domain in both proteins, corresponding to the PF12985 (DUF3869) domain is a β–sandwich with pre-albumin-like fold, found in many proteins belonging to the Transthyretin clan of Pfam. The structures of C-terminal domains of both proteins, corresponding to the PF12986 (DUF3870) domain in BVU_4064 protein and an unclassified domain in the BF1687 protein, show significant structural similarity to bacterial pore-forming toxins. A helix in this domain is in an analogous position to a loop connecting the second and third strands in the toxin structures, where this loop is implicated to play a role in the toxin insertion into the host cell membrane. The same helix also points to the groove between the N- and C-terminal domains that are loosely held together by hydrophobic and hydrogen bond interactions. The presence of several conserved residues in this region together with these structural determinants could make it a functionally important region in these proteins.

Conclusions

Structural analysis of BVU_4064 and BF1687 points to possible roles in mediating multiple interactions on the cell-surface/extracellular matrix. In particular the N-terminal domain could be involved in adhesive interactions, the C-terminal domain and the inter-domain groove in lipid or carbohydrate interactions.

Electronic supplementary material

The online version of this article (doi:10.1186/s12859-014-0434-7) contains supplementary material, which is available to authorized users.     

Structural basis for a homodimeric ATPase subunit of an ECF transporter

The transition metal cobalt, an essential cofactor for many enzymes in prokaryotes, is taken up by several specifi c transport systems. The CbiMNQO protein complex belongs to type-1 energy-coupling factor (ECF) transporters and is a widespread group of microbial cobalt transporters. CbiO is the ATPase subunit (A-component) of the cobalt transporting system in the gram-negative thermophilic bacterium Thermoanaerobacter tengcongensis. Here we report the crystal structure of a nucleotide-free CbiO at a resolution of 2.3 ?. CbiO contains an N-terminal canonical nucleotide-binding domain (NBD) and C-terminal helical domain. Structural and biochemical data show that CbiO forms a homodimer mediated by the NBD and the C-terminal domain. Interactions mainly via conserved hydrophobic amino acids between the two C-terminal domains result in formation of a four-helix bundle. Structural comparison with other ECF transporters suggests that non-conserved residues outside the T-component binding groove in the A component likely act as a specifi city determinant for T components. Together, our data provide information on understanding of the structural organization and interaction of the CbiMNQO system.     

Crystal structure of the C-terminal region of Streptococcus mutans antigen I/II and characterization of salivary agglutinin adherence domains

The Streptococcus mutans antigen I/II (AgI/II) is a cell surface-localized protein that adheres to salivary components and extracellular matrix molecules. Here we report the 2.5 Å resolution crystal structure of the complete C-terminal region of AgI/II. The C-terminal region is comprised of three major domains: C₁, C₂, and C₃. Each domain adopts a DE-variant IgG fold, with two β-sheets whose A and F strands are linked through an intramolecular isopeptide bond. The adherence of the C-terminal AgI/II fragments to the putative tooth surface receptor salivary agglutinin (SAG), as monitored by surface plasmon resonance, indicated that the minimal region of binding was contained within the first and second DE-variant-IgG domains (C₁ and C₂) of the C terminus. The minimal C-terminal region that could inhibit S. mutans adherence to SAG was also confirmed to be within the C₁ and C₂ domains. Competition experiments demonstrated that the C- and N-terminal regions of AgI/II adhere to distinct sites on SAG. A cleft formed at the intersection between these C₁ and C₂ domains bound glucose molecules from the cryo-protectant solution, revealing a putative binding site for its highly glycosylated receptor SAG. Finally, electron microscopy images confirmed the elongated structure of AgI/II and enabled building a composite tertiary model that encompasses its two distinct binding regions.     

Structure-function analysis of the C-terminal domain of CNM67, a core component of the Saccharomyces cerevisiae spindle pole body

The spindle pole body of the budding yeast Saccharomyces cerevisiae has served as a model system for understanding microtubule organizing centers, yet very little is known about the molecular structure of its components. We report here the structure of the C-terminal domain of the core component Cnm67 at 2.3 Å resolution. The structure determination was aided by a novel approach to crystallization of proteins containing coiled-coils that utilizes globular domains to stabilize the coiled-coils. This enhances their solubility in Escherichia coli and improves their crystallization. The Cnm67 C-terminal domain (residues Asn-429—Lys-581) exhibits a previously unseen dimeric, interdigitated, all α-helical fold. In vivo studies demonstrate that this domain alone is able to localize to the spindle pole body. In addition, the structure reveals a large functionally indispensable positively charged surface patch that is implicated in spindle pole body localization. Finally, the C-terminal eight residues are disordered but are critical for protein folding and structural stability.     

Structure and Assembly of Group B Streptococcus Pilus 2b Backbone Protein

Group B Streptococcus (GBS) is a major cause of invasive disease in infants. Like other Gram-positive bacteria, GBS uses a sortase C-catalyzed transpeptidation mechanism to generate cell surface pili from backbone and ancillary pilin precursor substrates. The three pilus types identified in GBS contain structural subunits that are highly immunogenic and are promising candidates for the development of a broadly-protective vaccine. Here we report the X-ray crystal structure of the backbone protein of pilus 2b (BP-2b) at 1.06Å resolution. The structure reveals a classical IgG-like fold typical of the pilin subunits of other Gram-positive bacteria. The crystallized portion of the protein (residues 185-468) encompasses domains D2 and D3 that together confer high stability to the protein due to the presence of an internal isopeptide bond within each domain. The D2+D3 region, lacking the N-terminal D1 domain, was as potent as the entire protein in conferring protection against GBS challenge in a well-established mouse model. By site-directed mutagenesis and complementation studies in GBS knock-out strains we identified the residues and motives essential for assembly of the BP-2b monomers into high-molecular weight complexes, thus providing new insights into pilus 2b polymerization.     

Isopeptide bonds of the major pilin protein BcpA influence pilus structure and bundle formation on the surface of Bacillus cereus

Bacillus cereus strains elaborate pili on their surface using a mechanism of sortase-mediated cross-linking of major and minor pilus components. Here we used a combination of electron microscopy and atomic force microscopy to visualize these structures. Pili occur as single, double or higher order assemblies of filaments formed from monomers of the major pilin, BcpA, capped by the minor pilin, BcpB. Previous studies demonstrated that within assembled pili, four domains of BcpA - CNA(1), CNA(2), XNA and CNA(3) - each acquire intramolecular lysine-asparagine isopeptide bonds formed via catalytic glutamic acid or aspartic acid residues. Here we showed that mutants unable to form the intramolecular isopeptide bonds in the CNA(2) or CNA(3) domains retain the ability to form pilus bundles. A mutant lacking the CNA(1) isopeptide bond assembled deformed pilin subunits that failed to associate as bundles. X-ray crystallography revealed that the BcpA variant Asp(312) Ala, lacking an aspartyl catalyst, did not generate the isopeptide bond within the jelly-roll structure of XNA. The Asp(312) Ala mutant was also unable to form bundles and promoted the assembly of deformed pili. Thus, structural integrity of the CNA(1) and XNA domains are determinants for the association of pili into higher order bundle structures and determine native pilus structure.     

The structure of Bcl-w reveals a role for the C-terminal residues in modulating biological activity

Pro-survival Bcl-2-related proteins, critical regulators of apoptosis, contain a hydrophobic groove targeted for binding by the BH3 domain of the pro-apoptotic BH3-only proteins. The solution structure of the pro-survival protein Bcl-w, presented here, reveals that the binding groove is not freely accessible as predicted by previous structures of pro-survival Bcl-2-like molecules. Unexpectedly, the groove appears to be occluded by the C-terminal residues. Binding and kinetic data suggest that the C-terminal residues of Bcl-w and Bcl-x(L) modulate pro-survival activity by regulating ligand access to the groove. Binding of the BH3-only proteins, critical for cell death initiation, is likely to displace the hydrophobic C-terminal region of Bcl-w and Bcl-x(L). Moreover, Bcl-w does not act only by sequestering the BH3-only proteins. There fore, pro-survival Bcl-2-like molecules probably control the activation of downstream effectors by a mechanism that remains to be elucidated.     

EH domain of EHD1

EHD1 is a member of the mammalian C-terminal Eps15 homology domain (EH) containing protein family, and regulates the recycling of various receptors from the endocytic recycling compartment to the plasma membrane. The EH domain of EHD1 binds to proteins containing either an Asn-Pro-Phe or Asp-Pro-Phe motif, and plays an important role in the subcellular localization and function of EHD1. Thus far, the structures of five N-terminal EH domains from other proteins have been solved, but to date, the structure of the EH domains from the four C-terminal EHD family paralogs remains unknown. In this study, we have assigned the 133 C-terminal residues of EHD1, which includes the EH domain, and solved its solution structure. While the overall structure resembles that of the second of the three N-terminal Eps15 EH domains, potentially significant differences in surface charge and the structure of the tripeptide-binding pocket are discussed.     

The crystal structure of yeast protein disulfide isomerase suggests cooperativity between its active sites

Protein disulfide isomerase plays a key role in catalyzing the folding of secretory proteins. It features two catalytically inactive thioredoxin domains inserted between two catalytically active thioredoxin domains and an acidic C-terminal tail. The crystal structure of yeast PDI reveals that the four thioredoxin domains are arranged in the shape of a twisted "U" with the active sites facing each other across the long sides of the "U." The inside surface of the "U" is enriched in hydrophobic residues, thereby facilitating interactions with misfolded proteins. The domain arrangement, active site location, and surface features strikingly resemble the Escherichia coli DsbC and DsbG protein disulfide isomerases. Biochemical studies demonstrate that all domains of PDI, including the C-terminal tail, are required for full catalytic activity. The structure defines a framework for rationalizing the differences between the two active sites and their respective roles in catalyzing the formation and rearrangement of disulfide bonds.     

Proposed structure for the DNA-binding domain of the Myb oncoprotein based on model building and mutational analysis

Myb-related proteins from plants to humans are characterized by a DNA-binding domain which contains two to three imperfect repeats of approximately 50 amino acids each. Based on the evolutionary conservation of specific residues, secondary structural predictions suggest an arrangement of alpha helices homologous to that seen in the homeodomains, members of the helix-turn-helix family of DNA-binding proteins. We have used molecular modelling in conjunction with site-directed mutagenesis to test the feasibility of this structure. We propose that each Myb repeat consists of three alpha helices packed over a hydrophobic core which is built around the three highly conserved tryptophan residues. The C-terminal helix forms part of the helix-turn-helix motif and can be positioned into the major groove of B-form DNA, allowing prediction of residues critical for specificity of interaction. Modelling also allowed positioning of adjacent repeats around the major groove over an 8 bp binding site.     

Crystal structure of the human carboxypeptidase N (kininase I) catalytic domain

Human carboxypeptidase N (CPN), a member of the CPN/E subfamily of "regulatory" metallo-carboxypeptidases, is an extracellular glycoprotein synthesized in the liver and secreted into the blood, where it controls the activity of vasoactive peptide hormones, growth factors and cytokines by specifically removing C-terminal basic residues. Normally, CPN circulates in blood plasma as a hetero-tetramer consisting of two 83 kDa (CPN2) domains each flanked by a 48 to 55 kDa catalytic (CPN1) domain. We have prepared and crystallized the recombinant C-terminally truncated catalytic domain of human CPN1, and have determined and refined its 2.1 A crystal structure. The structural analysis reveals that CPN1 has a pear-like shape, consisting of a 319 residue N-terminal catalytic domain and an abutting, cylindrically shaped 79 residue C-terminal beta-sandwich transthyretin (TT) domain, more resembling CPD-2 than CPM. Like these other CPN/E members, two surface loops surrounding the active-site groove restrict access to the catalytic center, offering an explanation for why some larger protein carboxypeptidase inhibitors do not inhibit CPN. Modeling of the Pro-Phe-Arg C-terminal end of the natural substrate bradykinin into the active site shows that the S1' pocket of CPN1 might better accommodate P1'-Lys than Arg residues, in agreement with CPN's preference for cleaving off C-terminal Lys residues. Three Thr residues at the distal TT edge of CPN1 are O-linked to N-acetyl glucosamine sugars; equivalent sites in the membrane-anchored CPM are occupied by basic residues probably involved in membrane interaction. In tetrameric CPN, each CPN1 subunit might interact with the central leucine-rich repeat tandem of the cognate CPN2 subunit via a unique hydrophobic surface patch wrapping around the catalytic domain-TT interface, exposing the two active centers.