Crystal Structure of Clostridium botulinum Whole Hemagglutinin Reveals a Huge Triskelion-shaped Molecular Complex

Clostridium botulinum HA is a component of the large botulinum neurotoxin complex and is critical for its oral toxicity. HA plays multiple roles in toxin penetration in the gastrointestinal tract, including protection from the digestive environment, binding to the intestinal mucosal surface, and disruption of the epithelial barrier. At least two properties of HA contribute to these roles: the sugar-binding activity and the barrier-disrupting activity that depends on E-cadherin binding of HA. HA consists of three different proteins, HA1, HA2, and HA3, whose structures have been partially solved and are made up mainly of β-strands. Here, we demonstrate structural and functional reconstitution of whole HA and present the complete structure of HA of serotype B determined by x-ray crystallography at 3.5 Å resolution. This structure reveals whole HA to be a huge triskelion-shaped molecule. Our results suggest that whole HA is functionally and structurally separable into two parts: HA1, involved in recognition of cell-surface carbohydrates, and HA2-HA3, involved in paracellular barrier disruption by E-cadherin binding.     

Structure of Stem Cell Growth Factor R-spondin 1 in Complex with the Ectodomain of Its Receptor LGR5

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Crystal Structure of the Bacillus subtilis Phosphodiesterase PhoD Reveals an Iron and Calcium-containing Active Site

The PhoD family of extra-cytoplasmic phosphodiesterases are among the most commonly occurring bacterial phosphatases. The exemplars for this family are the PhoD protein of Bacillus subtilis and the phospholipase D of Streptomyces chromofuscus. We present the crystal structure of B. subtilis PhoD. PhoD is most closely related to purple acid phosphatases (PAPs) with both types of enzyme containing a tyrosinate-ligated Fe³⁺ ion. However, the PhoD active site diverges from that found in PAPs and uses two Ca²⁺ ions instead of the single extra Fe²⁺, Mn²⁺, or Zn²⁺ ion present in PAPs. The PhoD crystals contain a phosphate molecule that coordinates all three active site metal ions and that is proposed to represent a product complex. A C-terminal helix lies over the active site and controls access to the catalytic center. The structure of PhoD defines a new phosphatase active site architecture based on Fe³⁺ and Ca²⁺ ions.     

Crystal Structure of the Mineralocorticoid Receptor DNA Binding Domain in Complex with DNA

The steroid hormone receptors regulate important physiological functions such as reproduction, metabolism, immunity, and electrolyte balance. Mutations within steroid receptors result in endocrine disorders and can often drive cancer formation and progression. Despite the conserved three-dimensional structure shared among members of the steroid receptor family and their overlapping DNA binding preference, activation of individual steroid receptors drive unique effects on gene expression. Here, we present the first structure of the human mineralocorticoid receptor DNA binding domain, in complex with a canonical DNA response element. The overall structure is similar to the glucocorticoid receptor DNA binding domain, but small changes in the mode of DNA binding and lever arm conformation may begin to explain the differential effects on gene regulation by the mineralocorticoid and glucocorticoid receptors. In addition, we explore the structural effects of mineralocorticoid receptor DNA binding domain mutations found in type I pseudohypoaldosteronism and multiple types of cancer.     

Structure of an Arrestin2-Clathrin Complex Reveals a Novel Clathrin Binding Domain That Modulates Receptor Trafficking

Non-visual arrestins play a pivotal role as adaptor proteins in regulating the signaling and trafficking of multiple classes of receptors. Although arrestin interaction with clathrin, AP-2, and phosphoinositides contributes to receptor trafficking, little is known about the configuration and dynamics of these interactions. Here, we identify a novel interface between arrestin2 and clathrin through x-ray diffraction analysis. The intrinsically disordered clathrin binding box of arrestin2 interacts with a groove between blades 1 and 2 in the clathrin β-propeller domain, whereas an 8-amino acid splice loop found solely in the long isoform of arrestin2 (arrestin2L) interacts with a binding pocket formed by blades 4 and 5 in clathrin. The apposition of the two binding sites in arrestin2L suggests that they are exclusive and may function in higher order macromolecular structures. Biochemical analysis demonstrates direct binding of clathrin to the splice loop in arrestin2L, whereas functional analysis reveals that both binding domains contribute to the receptor-dependent redistribution of arrestin2L to clathrin-coated pits. Mutagenesis studies reveal that the clathrin binding motif in the splice loop is (L/I)₂GXL. Taken together, these data provide a framework for understanding the dynamic interactions between arrestin2 and clathrin and reveal an essential role for this interaction in arrestin-mediated endocytosis.Many transmembrane signaling systems consist of specific G protein-coupled receptors (GPCRs)³ that transduce a diverse array of extracellular stimuli into intracellular signaling events (1). GPCRs modulate the activity of numerous effector molecules and regulate multiple biological functions including neurotransmission, sensory perception, cardiovascular function, development, and cell growth and differentiation (2). To ensure that extracellular stimuli are translated into intracellular signals of appropriate magnitude and duration, these signaling cascades are tightly regulated. GPCRs are subject to three principle modes of regulation; 1) desensitization, in which a receptor becomes refractory to continued stimuli; 2) endocytosis, where receptors are removed from the cell surface; 3) down-regulation, where total receptor levels are decreased (3, 4). Agonist-dependent regulation is primarily mediated by GPCR kinases that specifically phosphorylate activated GPCRs and initiate the recruitment of arrestins. Arrestins are divided into two major classes, visual and non-visual, based on their localization and function. The non-visual arrestins, arrestin2 and 3 (also termed β-arrestin1 and -2, respectively), are broadly distributed and function in multiple processes including GPCR desensitization, trafficking, and signaling (4–6).Initial structural insight on arrestins was provided by the x-ray crystal structure of bovine arrestin1 (7, 8), whereas the crystal structures of C-terminal-truncated (9) and wild type (10) bovine arrestin2 and salamander arrestin4 (11) have also been solved. In general, arrestins are composed of two major domains made up of β strands and connecting loops that are held together by a polar core region consisting of buried salt bridges. It has been proposed that arrestins adopt an active conformation upon binding to phosphorylated receptors, which disrupts the polar core resulting in the release of the C-terminal tail (12). Disruption of the polar core by point mutation of Arg-169 generates a constitutively active arrestin2, which mimics the active state. This mutated arrestin binds to the β₂-adrenergic receptor (β₂AR) in a phosphorylation-independent manner, induces internalization of a δ-opioid receptor lacking phosphorylation sites (13), and has increased binding to clathrin and AP-2 (14).A role for non-visual arrestins in GPCR endocytosis was first described for the β₂AR (15, 16), although it is now evident that arrestins regulate the trafficking of multiple GPCRs as well as additional classes of receptors (4). An early step in this process involves arrestin binding to an activated phosphorylated receptor that enhances arrestin interaction with the endocytic proteins, clathrin, and AP-2 (16, 17). An additional important step in this process involves arrestin interaction with phosphoinositides such as phosphatidylinositol diphosphate and trisphosphate (18). Although the dynamics of these interactions have not been studied, arrestin2 and -3 have been shown to interact specifically and stoichiometrically with clathrin (16). Furthermore, fluorescence microscopy reveals that activated β₂AR, arrestin2, clathrin, and AP-2 all colocalize upon receptor stimulation (16). The primary clathrin binding determinant in arrestin2, LIELD, spans residues 376–380 and is located in an extended disordered loop that immediately precedes the final C-terminal β-strand (10, 19). This region, the clathrin binding box, is consistent with a consensus motif, LϕXϕ(D/E) (where ϕ is a bulky hydrophobic residue, and X represents any polar amino acid), established in other clathrin-binding proteins including AP-2 (20), AP180 (21), amphiphysin (22), and epsin (23). Importantly, the mutation of this motif in arrestin3 and its deletion in arrestin2 significantly disrupts clathrin binding and receptor endocytosis (14, 19). A mutagenesis study of clathrin localized an arrestin binding site to the N-terminal domain of the clathrin heavy chain, specifically residues Glu-89, Lys-96, and Lys-98 (24). Moreover, a crystal structure of clathrin-(1–363) in complex with an arrestin3 peptide (residues 369–381) supports the mutagenesis data and the predicted location of the arrestin-clathrin interaction site (25).To further elucidate the mechanisms involved in mediating arrestin/clathrin interaction, we have determined the crystal structure of clathrin with the short (arrestin2S) and long (arrestin2L) isoforms of arrestin2, which differ by an 8-amino acid insert between β strands 18 and 19 (26). Our results identify an additional and unique interaction encoded in the arrestin2L isoform that is distinct from the previously well characterized interaction involving the LϕXϕ(D/E) motif. Specifically, we observe that the 8 amino acid splice loop in arrestin2L interacts with a pocket formed by blades 4 and 5 in clathrin. Biochemical and cell biological analysis confirm a role for both binding sites in arrestin2L/clathrin interaction and demonstrate an essential role of these interactions in arrestin-mediated GPCR endocytosis.     

The role of the extracellular loops of the CGRP receptor, a family B GPCR

The CGRP (calcitonin gene-related peptide) receptor is a family B GPCR (G-protein-coupled receptor). It consists of a GPCR, CLR (calcitonin receptor-like receptor) and an accessory protein, RAMP1 (receptor activity-modifying protein 1). RAMP1 is needed for CGRP binding and also cell-surface expression of CLR. There have been few systematic studies of the ECLs (extracellular loops) of family B GPCRs. However, they are likely to be especially important for the interaction of the N-termini of the peptide agonists that are the natural agonists for these receptors. We have carried out alanine scans on all three ECLs of CLR, as well as their associated juxtamembrane regions. Residues within all three loops influence CGRP binding and receptor activation. Mutation of Ala203 and Ala206 on ECL1 to leucine increased the affinity of CGRP. Residues at the top of TM (transmembrane) helices 2 and 3 influenced CGRP binding and receptor activation. L351A and E357A in TM6/ECL3 reduced receptor expression and may be needed for CLR association with RAMP1. ECL2 seems especially important for CLR function; of the 16 residues so far examined in this loop, eight residues reduce the potency of CGRP at stimulating cAMP production when mutated to alanine.     

Crystal Structure of the Ectoine Hydroxylase,a Snapshot of the Active Site

Ectoine and its derivative 5-hydroxyectoine are compatible solutes that are widely synthesized by bacteria to cope physiologically with osmotic stress. They also serve as chemical chaperones and maintain the functionality of macromolecules. 5-Hydroxyectoine is produced from ectoine through a stereo-specific hydroxylation, an enzymatic reaction catalyzed by the ectoine hydroxylase (EctD). The EctD protein is a member of the non-heme-containing iron(II) and 2-oxoglutarate-dependent dioxygenase superfamily and is evolutionarily well conserved. We studied the ectoine hydroxylase from the cold-adapted marine ultra-microbacterium Sphingopyxis alaskensis (Sa) and found that the purified SaEctD protein is a homodimer in solution. We determined the SaEctD crystal structure in its apo-form, complexed with the iron catalyst, and in a form that contained iron, the co-substrate 2-oxoglutarate, and the reaction product of EctD, 5-hydroxyectoine. The iron and 2-oxoglutarate ligands are bound within the EctD active site in a fashion similar to that found in other members of the dioxygenase superfamily. 5-Hydroxyectoine, however, is coordinated by EctD in manner different from that found in high affinity solute receptor proteins operating in conjunction with microbial import systems for ectoines. Our crystallographic analysis provides a detailed view into the active site of the ectoine hydroxylase and exposes an intricate network of interactions between the enzyme and its ligands that collectively ensure the hydroxylation of the ectoine substrate in a position- and stereo-specific manner.     

Crystal Structure of G Protein-coupled Receptor Kinase 5 in Complex with a Rationally Designed Inhibitor

G protein-coupled receptor kinases (GRKs) regulate cell signaling by initiating the desensitization of active G protein-coupled receptors. The two most widely expressed GRKs (GRK2 and GRK5) play a role in cardiovascular disease and thus represent important targets for the development of novel therapeutic drugs. In the course of a GRK2 structure-based drug design campaign, one inhibitor (CCG215022) exhibited nanomolar IC₅₀ values against both GRK2 and GRK5 and good selectivity against other closely related kinases such as GRK1 and PKA. Treatment of murine cardiomyocytes with CCG215022 resulted in significantly increased contractility at 20-fold lower concentrations than paroxetine, an inhibitor with more modest selectivity for GRK2. A 2.4 Å crystal structure of the GRK5·CCG215022 complex was determined and revealed that the inhibitor binds in the active site similarly to its parent compound GSK180736A. As designed, its 2-pyridylmethyl amide side chain occupies the hydrophobic subsite of the active site where it forms three additional hydrogen bonds, including one with the catalytic lysine. The overall conformation of the GRK5 kinase domain is similar to that of a previously determined structure of GRK6 in what is proposed to be its active state, but the C-terminal region of the enzyme adopts a distinct conformation. The kinetic properties of site-directed mutants in this region are consistent with the hypothesis that this novel C-terminal structure is representative of the membrane-bound conformation of the enzyme.     

Crystal Structure of Human Seryl-tRNA Synthetase and Ser-SA Complex Reveals a Molecular Lever Specific to Higher Eukaryotes

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Secondary Binding Site of Trypsin: Revealed by Crystal Structure of Trypsin-Peptide Complex

Abstract

Designed synthetic heterochiral peptides, when added to porcine trypsin, resulted in reduction of enzyme activity. The crystal structure of a complex formed between porcine trypsin and a heterochiral hepta peptide Boc-Pro-DAsp-Aib-Leu-Aib-Leu-Ala-NHMe has been determined at 1.9 Å resolution. The hepta peptide does not bind at the active site, but is located in the interstitial region, and interacts with the calcium-binding loop (residues 60–80). The bound peptide interacts with the active site residue Ser195 through an acetate ion, and with Lys 60 mediated by water molecules. The structure, when compared with the other trypsin-peptide complexes, suggests that the flexibility of surface loops, concerted movement of the loops towards the active site, and the interaction of the bound peptide with Lys 60, may be responsible for the reduction in enzyme activity. This study provides a structural evidence for the earlier biochemical observation regarding the role of surface loops in the catalysis of the enzyme.     

Cleavage of the SYMBIOSIS RECEPTOR-LIKE KINASE Ectodomain Promotes Complex Formation with Nod Factor Receptor 5

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Crystal Structure of the YcjX Stress Protein Reveals a Ras-Like GTP-Binding Protein

Stress proteins promote cell survival by monitoring protein homeostasis in cells and organelles. YcjX is a conserved protein of unknown function, which is highly upregulated in response to acute and chronic stress. Notably, heat shock induction of ycjX exceeded even levels observed for major stress-induced chaperones, including GroEL, ClpB, and HtpG, which use ATP as energy source. YcjX features a Walker-type nucleotide-binding domain indicating that YcjX might function as a molecular chaperone. Here, we present the first crystal structure of YcjX from Shewanella oneidensis solved at 1.9-Å resolution by SAD phasing. We show that YcjX is a GTP-binding protein that shares at its core the canonical alpha-beta domain of p21^ras (Ras). However, unlike Ras, YcjX features several unique insertions, including an entirely α-helical domain not previously observed in Ras-like GTPases. We note that this helical domain is reminiscent of a similar domain in the Gα subunit of heterotrimeric G proteins, supporting a potential role for YcjX as a signal transducer of stress responses. To elucidate the mechanism of GTP hydrolysis, we determined crystal structures of YcjX bound to GDP and GDPCP, respectively, which crystallized in three different nucleotide switch conformations. Supported by targeted mutagenesis experiments, we show that YcjX utilizes a non-canonical switch 2′ motif not previously observed in Ras-like GTPases. Together, our structures provide atomic snapshots of YcjX in different functional states, illustrating the structural determinants for stress signaling.