Naoya Tochio

Reduced native state stability in crowded cellular environment due to protein-protein interactions.

The effect of cellular crowding environments on protein structure and stability is a key issue in molecular and cellular biology. The classical view of crowding emphasizes the volume exclusion effect that generally favors compact, native states. Here, results from molecular dynamics simulations and NMR experiments show that protein crowders may destabilize native states via protein-protein interactions. In the model system considered here, mixtures of villin head piece and protein G at high concentrations, villin structures become increasingly destabilized upon increasing crowder concentrations. The denatured states observed in the simulation involve partial unfolding as well as more subtle conformational shifts. The unfolded states remain overall compact and only partially overlap with unfolded ensembles at high temperature and in the presence of urea. NMR measurements on the same systems confirm structural changes upon crowding based on changes of chemical shifts relative to dilute conditions. An analysis of protein-protein interactions and energetic aspects suggests the importance of enthalpic and solvation contributions to the crowding free energies that challenge an entropic-centered view of crowding effects.

Contribution of E3-ubiquitin ligase activity to HIV-1 restriction by TRIM5alpha(rh): structure of the RING domain of TRIM5alpha.

ABSTRACT TRIM5αrh is a cytosolic protein that potently restricts HIV-1 before reverse transcription. TRIM5αrh is composed of four different domains: RING, B-box 2, coiled coil, and B30.2(SPRY). The contribution of each of these domains to restriction has been extensively studied, with the exception of the RING domain. The RING domain of TRIM5α exhibits E3-ubiquitin ligase activity, but the contribution of this activity to the restriction of HIV-1 is not known. To test the hypothesis that the E3-ubiquitin ligase activity of the RING domain modulates TRIM5αrh restriction of HIV-1, we correlated the E3-ubiquitin ligase activity of a panel of TRIM5αrh RING domain variants with the ability of these mutant proteins to restrict HIV-1. For this purpose, we first solved the nuclear magnetic resonance structure of the RING domain of TRIM5α and defined potential functional regions of the RING domain by homology to other RING domains. With this structural information, we performed a systematic mutagenesis of the RING domain regions and tested the TRIM5α RING domain variants for the ability to undergo self-ubiquitylation. Several residues, particularly the ones on the E2-binding region of the RING domain, were defective in their self-ubiquitylation ability. To correlate HIV-1 restriction to self-ubiquitylation, we used RING domain mutant proteins that were defective in self-ubiquitylation but preserve important properties required for potent restriction by TRIM5αrh, such as capsid binding and higher-order self-association. From these investigations, we found a set of residues that when mutated results in TRIM5α molecules that lost both the ability to potently restrict HIV-1 and their self-ubiquitylation activity. Remarkably, all of these changes were in residues located in the E2-binding region of the RING domain. Overall, these results demonstrate a role for TRIM5α self-ubiquitylation in the ability of TRIM5α to restrict HIV-1.

Solution structure of the RWD domain of the mouse GCN2 protein

GCN2 is the α‐subunit of the only translation initiation factor (eIF2α) kinase that appears in all eukaryotes. Its function requires an interaction with GCN1 via the domain at its N‐terminus, which is termed the RWD domain after three major RWD‐containing proteins: RING finger‐containing proteins, WD‐repeat‐containing proteins, and yeast DEAD (DEXD)‐like helicases. In this study, we determined the solution structure of the mouse GCN2 RWD domain using NMR spectroscopy. The structure forms an α + β sandwich fold consisting of two layers: a four‐stranded antiparallel β‐sheet, and three side‐by‐side α‐helices, with an αββββαα topology. A characteristic YPXXXP motif, which always occurs in RWD domains, forms a stable loop including three consecutive β‐turns that overlap with each other by two residues (triple β‐turn). As putative binding sites with GCN1, a structure‐based alignment allowed the identification of several surface residues in α‐helix 3 that are characteristic of the GCN2 RWD domains. Despite the apparent absence of sequence similarity, the RWD structure significantly resembles that of ubiquitin‐conjugating enzymes (E2s), with most of the structural differences in the region connecting β‐strand 4 and α‐helix 3. The structural architecture, including the triple β‐turn, is fundamentally common among various RWD domains and E2s, but most of the surface residues on the structure vary. Thus, it appears that the RWD domain is a novel structural domain for protein‐binding that plays specific roles in individual RWD‐containing proteins.

Solution structure of the PWWP domain of the hepatoma-derived growth factor family

Among the many PWWP‐containing proteins, the largest group of homologous proteins is related to hepatoma‐derived growth factor (HDGF). Within a well‐conserved region at the extreme N‐terminus, HDGF and five HDGF‐related proteins (HRPs) always have a PWWP domain, which is a module found in many chromatin‐associated proteins. In this study, we determined the solution structure of the PWWP domain of HDGF‐related protein‐3 (HRP‐3) by NMR spectroscopy. The structure consists of a five‐stranded β‐barrel with a PWWP‐specific long loop connecting β2 and β3 (PR‐loop), followed by a helical region including two α‐helices. Its structure was found to have a characteristic solvent‐exposed hydrophobic cavity, which is composed of an abundance of aromatic residues in the β1/β2 loop (β‐β arch) and the β3/β4 loop. A similar ligand binding cavity occurs at the corresponding position in the Tudor, chromo, and MBT domains, which have structural and probable evolutionary relationships with PWWP domains. These findings suggest that the PWWP domains of the HDGF family bind to some component of chromatin via the cavity.

Solution structure of the catalytic domain of the mitochondrial protein ICT1 that is essential for cell vitality

The ICT1 protein was recently reported to be a component of the human mitoribosome and to have codon-independent peptidyl-tRNA hydrolysis activity via its conserved GGQ motif, although little is known about the detailed mechanism. Here, using NMR spectroscopy, we determined the solution structure of the catalytic domain of the mouse ICT1 protein that lacks an N-terminal mitochondrial targeting signal and an unstructured C-terminal basic-residue-rich extension, and we examined the effect of ICT1 knockdown (mediated by small interfering RNA) on mitochondria in HeLa cells using flow cytometry. The catalytic domain comprising residues 69-162 of the 206-residue full-length protein forms a structure with a β1-β2-α1-β3-α2 topology and a structural framework that resembles the structure of GGQ-containing domain 3 of class 1 release factors (RFs). Half of the structure, including the GGQ-containing loop, has essentially the same sequence and structure as those in RFs, consistent with the peptidyl-tRNA hydrolysis activity of ICT1 on the mitoribosome, which is analogous to RFs. However, the other half of the structure differs in shape from the corresponding part of RF domain 3 in that in ICT1, an α-helix (α1), instead of a β-turn, is inserted between strand β2 and strand β3. A characteristic groove formed between α1 and the three-stranded antiparallel β-sheet was identified as a putative ICT1-specific functional site by a structure-based alignment. In addition, the structured domain that recognizes stop codons in RFs is replaced in ICT1 by a C-terminal basic-residue-rich extension. It appears that these differences are linked to a specific function of ICT1 other than the translation termination mediated by RFs. Flow cytometry analysis showed that the knockdown of ICT1 results in apoptotic cell death with a decrease in mitochondrial membrane potential and mass. In addition, cytochrome c oxidase activity in ICT1 knockdown cells was decreased by 35% compared to that in control cells. These results indicate that ICT1 function is essential for cell vitality and mitochondrial function.

Solution structure of the kinase-associated domain 1 of mouse microtubule-associated protein/microtubule affinity-regulating kinase 3.

Microtubule‐associated protein/microtubule affinity‐regulating kinases (MARKs)/PAR‐1 are common regulators of cell polarity that are conserved from nematode to human. All of these kinases have a highly conserved C‐terminal domain, which is termed the kinase‐associated domain 1 (KA1), although its function is unknown. In this study, we determined the solution structure of the KA1 domain of mouse MARK3 by NMR spectroscopy. We found that ∼50 additional residues preceding the previously defined KA1 domain are required for its proper folding. The newly defined KA1 domain adopts a compact α+β structure with a βαββββα topology. We also found a characteristic hydrophobic, concave surface surrounded by positively charged residues. This concave surface includes the highly conserved Glu‐Leu‐Lys‐Leu motif at the C terminus, indicating that it is important for the function of the KA1 domain.

Structural basis for mutual relief of the Rac guanine nucleotide exchange factor DOCK2 and its partner ELMO1 from their autoinhibited forms

DOCK2, a hematopoietic cell-specific, atypical guanine nucleotide exchange factor, controls lymphocyte migration through ras-related C3 botulinum toxin substrate (Rac) activation. Dedicator of cytokinesis 2–engulfment and cell motility protein 1 (DOCK2•ELMO1) complex formation is required for DOCK2-mediated Rac signaling. In this study, we identified the N-terminal 177-residue fragment and the C-terminal 196-residue fragment of human DOCK2 and ELMO1, respectively, as the mutual binding regions, and solved the crystal structure of their complex at 2.1-Å resolution. The C-terminal Pro-rich tail of ELMO1 winds around the Src-homology 3 domain of DOCK2, and an intermolecular five-helix bundle is formed. Overall, the entire regions of both DOCK2 and ELMO1 assemble to create a rigid structure, which is required for the DOCK2•ELMO1 binding, as revealed by mutagenesis. Intriguingly, the DOCK2•ELMO1 interface hydrophobically buries a residue which, when mutated, reportedly relieves DOCK180 from autoinhibition. We demonstrated that the ELMO-interacting region and the DOCK-homology region 2 guanine nucleotide exchange factor domain of DOCK2 associate with each other for the autoinhibition, and that the assembly with ELMO1 weakens the interaction, relieving DOCK2 from the autoinhibition. The interactions between the N- and C-terminal regions of ELMO1 reportedly cause its autoinhibition, and binding with a DOCK protein relieves the autoinhibition for ras homolog gene family, member G binding and membrane localization. In fact, the DOCK2•ELMO1 interface also buries the ELMO1 residues required for the autoinhibition within the hydrophobic core of the helix bundle. Therefore, the present complex structure reveals the structural basis by which DOCK2 and ELMO1 mutually relieve their autoinhibition for the activation of Rac1 for lymphocyte chemotaxis.

NMR solution structures of actin depolymerizing factor homology domains

Actin is one of the most conserved proteins in nature. Its assembly and disassembly are regulated by many proteins, including the family of actin‐depolymerizing factor homology (ADF‐H) domains. ADF‐H domains can be divided into five classes: ADF/cofilin, glia maturation factor (GMF), coactosin, twinfilin, and Abp1/drebrin. The best‐characterized class is ADF/cofilin. The other four classes have drawn much less attention and very few structures have been reported. This study presents the solution NMR structure of the ADF‐H domain of human HIP‐55‐drebrin‐like protein, the first published structure of a drebrin‐like domain (mammalian), and the first published structure of GMF β (mouse). We also determined the structures of mouse GMF γ, the mouse coactosin‐like domain and the C‐terminal ADF‐H domain of mouse twinfilin 1. Although the overall fold of the five domains is similar, some significant differences provide valuable insights into filamentous actin (F‐actin) and globular actin (G‐actin) binding, including the identification of binding residues on the long central helix. This long helix is stabilized by three or four residues. Notably, the F‐actin binding sites of mouse GMF β and GMF γ contain two additional β‐strands not seen in other ADF‐H structures. The G‐actin binding site of the ADF‐H domain of human HIP‐55‐drebrin‐like protein is absent and distorted in mouse GMF β and GMF γ.

A practical method for cell-free protein synthesis to avoid stable isotope scrambling and dilution.

During recent years, the targets of protein structure analysis using nuclear magnetic resonance spectroscopy have become larger and more complicated. As a result, a complete and precise stable isotope labeling technique has been desired. A cell-free protein synthesis system is appropriate for this purpose. In the current study, we achieved precise and complete (15)N and (2)H labeling using an Escherichia coli cell extract-based cell-free protein synthesis system by controlling the metabolic reactions in the system with their chemical inhibitors. The addition of aminooxyacetate, d-malate, l-methionine sulfoximine, S-methyl-l-cysteine sulfoximine, 6-diazo-5-oxo-l-norleucine, and 5-diazo-4-oxo-l-norvaline was quite effective for precise amino acid-selective (15)N labeling even for aspartic acid, asparagine, glutamic acid, and glutamine, which generally suffer from severe isotope scrambling and dilution when using the conventional cell-free system. For (2)H labeling, the back-protonation of the H(α) and H(β) positions, which commonly occurred in the conventional system, was dramatically suppressed by simply adding aminooxyacetate and d-malate to the cell-free system except for the H(α) positions in methionine and cysteine.

Solution structure of an atypical WW domain in a novel β-clam-like dimeric form

The WW domain is known as one of the smallest protein modules with a triple‐stranded β‐sheet fold. Here, we present the solution structure of the second WW domain from the mouse salvador homolog 1 protein. This WW domain forms a homodimer with a β‐clam‐like motif, as evidenced by size exclusion chromatography, analytical ultracentrifugation and NMR spectroscopy. While typical WW domains are believed to function as monomeric modules that recognize proline‐rich sequences, by using conserved aromatic and hydrophobic residues that are solvent‐exposed on the surface of the β‐sheet, this WW domain buries these residues in the dimer interface.