Mitsutoshi Toyama

Curved EFC/F-BAR-Domain Dimers Are Joined End to End into a Filament for Membrane Invagination in Endocytosis

Pombe Cdc15 homology (PCH) proteins play an important role in a variety of actin-based processes, including clathrin-mediated endocytosis (CME). The defining feature of the PCH proteins is an evolutionarily conserved EFC/F-BAR domain for membrane association and tubulation. In the present study, we solved the crystal structures of the EFC domains of human FBP17 and CIP4. The structures revealed a gently curved helical-bundle dimer of approximately 220 A in length, which forms filaments through end-to-end interactions in the crystals. The curved EFC dimer fits a tubular membrane with an approximately 600 A diameter. We subsequently proposed a model in which the curved EFC filament drives tubulation. In fact, striation of tubular membranes was observed by phase-contrast cryo-transmission electron microscopy, and mutations that impaired filament formation also impaired membrane tubulation and cell membrane invagination. Furthermore, FBP17 is recruited to clathrin-coated pits in the late stage of CME, indicating its physiological role.

Crystal Structure of the Interleukin-15·Interleukin-15 Receptor α Complex INSIGHTS INTO TRANS AND CIS PRESENTATION

Interleukin (IL)-15 is a pleiotropic cytokine that plays a pivotal role in both innate and adaptive immunity. IL-15 is unique among cytokines due to its participation in a trans signaling mechanism in which IL-15 receptorα (IL-15Rα) from one subset of cells presents IL-15 to neighboring IL-2Rβ/γc-expressing cells. Here we present the crystal structure of IL-15 in complex with the sushi domain of IL-15Rα. The structure reveals that theα receptor-binding epitope of IL-15 adopts a unique conformation, which, together with amino acid substitutions, permits specific interactions with IL-15Rα that account for the exceptionally high affinity of the IL-15·IL-15Rα complex. Interestingly, analysis of the topology of IL-15 and IL-15Rα at the IL-15·IL-15Rα interface suggests that IL-15 should be capable of participating in a cis signaling mechanism similar to that of the related cytokine IL-2. Indeed, we present biochemical data demonstrating that IL-15 is capable of efficiently signaling in cis through IL-15Rα and IL-2Rβ/γc expressed on the surface of a single cell. Based on our data we propose that cis presentation of IL-15 may be important in certain biological contexts and that flexibility of IL-15Rα permits IL-15 and its three receptor components to be assembled identically at the ligand-receptor interface whether IL-15 is presented in cis or trans. Finally, we have gained insights into IL-15·IL-15Rα·IL-2Rβ·γc quaternary complex assembly through the use of molecular modeling.

Crystal structure of the GAF-B domain from human phosphodiesterase 10A complexed with its ligand, cAMP.

Cyclic nucleotide phosphodiesterases (PDEs) catalyze the degradation of the cyclic nucleotides cAMP and cGMP, which are important second messengers. Five of the 11 mammalian PDE families have tandem GAF domains at their N termini. PDE10A may be the only mammalian PDE for which cAMP is the GAF domain ligand, and it may be allosterically stimulated by cAMP. PDE10A is highly expressed in striatal medium spiny neurons. Here we report the crystal structure of the C-terminal GAF domain (GAF-B) of human PDE10A complexed with cAMP at 2.1-Å resolution. The conformation of the PDE10A GAF-B domain monomer closely resembles those of the GAF domains of PDE2A and the cyanobacterium Anabaena cyaB2 adenylyl cyclase, except for the helical bundle consisting of α1, α2, and α5. The PDE10A GAF-B domain forms a dimer in the crystal and in solution. The dimerization is mainly mediated by hydrophobic interactions between the helical bundles in a parallel arrangement, with a large buried surface area. In the PDE10A GAF-B domain, cAMP tightly binds to a cNMP-binding pocket. The residues in the α3 and α4 helices, the β6 strand, the loop between 310 and α4, and the loop between α4 and β5 are involved in the recognition of the phosphate and ribose moieties. This recognition mode is similar to those of the GAF domains of PDE2A and cyaB2. In contrast, the adenine base is specifically recognized by the PDE10A GAF-B domain in a unique manner, through residues in the β1 and β2 strands.

Crystal Structure of the Rac Activator, Asef, Reveals Its Autoinhibitory Mechanism

The Rac-specific guanine nucleotide exchange factor (GEF) Asef is activated by binding to the tumor suppressor adenomatous polyposis coli mutant, which is found in sporadic and familial colorectal tumors. This activated Asef is involved in the migration of colorectal tumor cells. The GEFs for Rho family GTPases contain the Dbl homology (DH) domain and the pleckstrin homology (PH) domain. When Asef is in the resting state, the GEF activity of the DH-PH module is intramolecularly inhibited by an unidentified mechanism. Asef has a Src homology 3 (SH3) domain in addition to the DH-PH module. In the present study, the three-dimensional structure of Asef was solved in its autoinhibited state. The crystal structure revealed that the SH3 domain binds intramolecularly to the DH domain, thus blocking the Rac-binding site. Furthermore, the RT-loop and the C-terminal region of the SH3 domain interact with the DH domain in a manner completely different from those for the canonical binding to a polyproline-peptide motif. These results demonstrate that the blocking of the Rac-binding site by the SH3 domain is essential for Asef autoinhibition. This may be a common mechanism in other proteins that possess an SH3 domain adjacent to a DH-PH module.

Crystal structure of the human receptor activity-modifying protein 1 extracellular domain

Receptor activity‐modifying protein (RAMP) 1 forms a heterodimer with calcitonin receptor‐like receptor (CRLR) and regulates its transport to the cell surface. The CRLR·RAMP1 heterodimer functions as a specific receptor for calcitonin gene‐related peptide (CGRP). Here, we report the crystal structure of the human RAMP1 extracellular domain. The RAMP1 structure is a three‐helix bundle that is stabilized by three disulfide bonds. The RAMP1 residues important for cell‐surface expression of the CRLR·RAMP1 heterodimer are clustered to form a hydrophobic patch on the molecular surface. The hydrophobic patch is located near the tryptophan residue essential for binding of the CGRP antagonist, BIBN4096BS. These results suggest that the hydrophobic patch participates in the interaction with CRLR and the formation of the ligand‐binding pocket when it forms the CRLR·RAMP1 heterodimer.

Interaction and Stoichiometry of the Peripheral Stalk Subunits NtpE and NtpF and the N-terminal Hydrophilic Domain of NtpI of Enterococcus hirae V-ATPase

The vacuolar ATPase (V-ATPase) is composed of a soluble catalytic domain and an integral membrane domain connected by a central stalk and a few peripheral stalks. The number and arrangement of the peripheral stalk subunits remain controversial. The peripheral stalk of Na+-translocating V-ATPase from Enterococcus hirae is likely to be composed of NtpE and NtpF (corresponding to subunit G of eukaryotic V-ATPase) subunits together with the N-terminal hydrophilic domain of NtpI (corresponding to subunit a of eukaryotic V-ATPase). Here we purified NtpE, NtpF, and the N-terminal hydrophilic domain of NtpI (NtpINterm) as separate recombinant His-tagged proteins and examined interactions between these three subunits by pulldown assay using one tagged subunit, CD spectroscopy, surface plasmon resonance, and analytical ultracentrifugation. NtpINterm directly bound NtpF, but not NtpE. NtpE bound NtpF tightly. NtpINterm bound the NtpE-F complex stronger than NtpF only, suggesting that NtpE increases the binding affinity between NtpINterm and NtpF. Purified NtpE-F-INterm complex appeared to be monodisperse, and the molecular masses estimated from analytical ultracentrifugation and small-angle x-ray scattering (SAXS) indicated that the ternary complex is formed with a 1:1:1 stoichiometry. A low resolution structure model of the complex produced from the SAXS data showed an elongated “L” shape.

Reconstitution in vitro of the catalytic portion (NtpA3-B3-D-G complex) of Enterococcus hirae V-type Na+-ATPase.

Enterococcus hirae vacuolar ATPase (V-ATPase) is composed of a soluble catalytic domain (V(1); NtpA(3)-B(3)-D-G) and an integral membrane domain (V(0); NtpI-K(10)) connected by a central and peripheral stalk(s) (NtpC and NtpE-F). Here we examined the nucleotide binding of NtpA monomer, NtpB monomer or NtpD-G heterodimer purified by using Escherichia coli expression system in vivo or in vitro, and the reconstitution of the V(1) portion with these polypeptides. The affinity of nucleotide binding to NtpA was 6.6 microM for ADP or 3.1 microM for ATP, while NtpB or NtpD-G did not show any binding. The NtpA and NtpB monomers assembled into NtpA(3)-B(3) heterohexamer in nucleotide binding-dependent manner. NtpD-G bound NtpA(3)-B(3) forming V(1) (NtpA(3)-B(3)-D-G) complex independent of nucleotides. The V(1) formation from individual NtpA and NtpB monomers with NtpD-G heterodimer was absolutely dependent on nucleotides. The ATPase activity of reconstituted V(1) complex was as high as that of native V(1)-ATPase purified from the V(0)V(1) complex by EDTA treatment of cell membrane. This in vitro reconstitution system of E. hirae V(1) complex will be valuable for characterizing the subunit-subunit interactions and assembly mechanism of the V(1)-ATPase complex.

Multiple Post-translational Modifications Affect Heterologous Protein Synthesis

Background: Post-translational modifications (PTMs) affect protein folding. Results: Statistically significant correlations are revealed between the yield of heterologous protein expression and the presence of multiple PTM sites bioinformatically predicted in the expressed sequences. Conclusion: Predicting potential PTMs in polypeptide sequences can help optimize heterologous protein synthesis. Significance: Correlations revealed provide insights into the role of specific PTMs in protein stability and solubility. Post-translational modifications (PTMs) are required for proper folding of many proteins. The low capacity for PTMs hinders the production of heterologous proteins in the widely used prokaryotic systems of protein synthesis. Until now, a systematic and comprehensive study concerning the specific effects of individual PTMs on heterologous protein synthesis has not been presented. To address this issue, we expressed 1488 human proteins and their domains in a bacterial cell-free system, and we examined the correlation of the expression yields with the presence of multiple PTM sites bioinformatically predicted in these proteins. This approach revealed a number of previously unknown statistically significant correlations. Prediction of some PTMs, such as myristoylation, glycosylation, palmitoylation, and disulfide bond formation, was found to significantly worsen protein amenability to soluble expression. The presence of other PTMs, such as aspartyl hydroxylation, C-terminal amidation, and Tyr sulfation, did not correlate with the yield of heterologous protein expression. Surprisingly, the predicted presence of several PTMs, such as phosphorylation, ubiquitination, SUMOylation, and prenylation, was associated with the increased production of properly folded soluble proteins. The plausible rationales for the existence of the observed correlations are presented. Our findings suggest that identification of potential PTMs in polypeptide sequences can be of practical use for predicting expression success and optimizing heterologous protein synthesis. In sum, this study provides the most compelling evidence so far for the role of multiple PTMs in the stability and solubility of heterologously expressed recombinant proteins.

Comprehensive bioinformatics analysis of cell-free protein synthesis: identification of multiple protein properties that correlate with successful expression

High‐throughput cell‐free protein synthesis is being used increasingly in structural/functional genomics projects. However, the factors determining expression success are poorly understood. Here, we evaluated the expression of 3066 human proteins and their domains in a bacterial cell‐free system and analyzed the correlation of protein expression with 39 physicochemical and structural properties of proteins. As a result of the bioinformatics analysis performed, we determined the 18 most influential features that affect protein amenability to cell‐free expression. They include protein length;hydrophobicity;pI;content of charged, nonpolar, and aromatic residues;, cysteine content;solvent accessibility,presence of coiled coil;content of intrinsically disordered and structured (α‐helix and β‐sheet) sequence;number of disulfide bonds and functional domains;presence of transmembrane regions;PEST motifs;and signaling sequences. This study represents the first comprehensive bioinformatics analysis of heterologous protein synthesis in a cell‐free system. The rules and correlations revealed here provide a plethora of important insights into rationalization of cell‐free protein production and can be of practical use for protein engineering with the aim of increasing expression success.—Kurotani, A., Takagi, T., Toyama, M., Shirouzu, M., Yokoyama, S., Fukami, Y., Tokmakov, A. A. Comprehensive bioinformatics analysis of cell‐free protein synthesis: identification of multiple protein properties that correlate with successful expression. FASEB J. 24, 1095–1104 (2010). www.fasebj.org

Expression, purification and characterization of isoforms of peripheral stalk subunits of human V-ATPase.

The vacuolar-type H+-ATPase (V-ATPase) is a multi-subunit proton pump that is involved in both intra- and extracellular acidification processes throughout human body. Subunits constituting the peripheral stalk of the V-ATPase are known to have several isoforms responsible for tissue/cell specific different physiological roles. To study the different interaction of these isoforms, we expressed and purified the isoforms of human V-ATPase peripheral stalk subunits using Escherichia coli cell-free protein synthesis system: E1, E2, G1, G2, G3, C1, C2, H and N-terminal soluble part of a1 and a2 isoforms. The purification conditions were different depending on the isoforms, maybe reflecting the isoform specific biochemical characteristics. The purified proteins are expected to facilitate further experiments to study about the cell specific interaction and regulation and thus provide insight into physiological meaning of the existence of several isoforms of each subunit in V-ATPase.