Your search keyword '"Muto, Yutaka"' showing total 9 results

1. Novel RNA recognition motif domain in the cytoplasmic polyadenylation element binding protein 3.

Author

Tsuda, Kengo, Kuwasako, Kanako, Nagata, Takashi, Takahashi, Mari, Kigawa, Takanori, Kobayashi, Naohiro, Güntert, Peter, Shirouzu, Mikako, Yokoyama, Shigeyuki, and Muto, Yutaka

Abstract

ABSTRACT The family of cytoplasmic polyadenylation element binding proteins CPEB1, CPEB2, CPEB3, and CPEB4 binds to the 3′-untranslated region (3′-UTR) of mRNA, and plays significant roles in mRNA metabolism and translation regulation. They have a common domain organization, involving two consecutive RNA recognition motif (RRM) domains followed by a zinc finger domain in the C-terminal region. We solved the solution structure of the first RRM domain (RRM1) of human CPEB3, which revealed that CPEB3 RRM1 exhibits structural features distinct from those of the canonical RRM domain. Our structural data provide important information about the RNA binding ability of CPEB3 RRM1. Proteins 2014; 82:2879-2886. © 2014 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2014

2. Solution structures of the double-stranded RNA-binding domains from rna helicase A.

Author

Nagata, Takashi, Tsuda, Kengo, Kobayashi, Naohiro, Shirouzu, Mikako, Kigawa, Takanori, Güntert, Peter, Yokoyama, Shigeyuki, and Muto, Yutaka

Abstract

RNA helicase A (RHA) is a highly conserved protein with multifaceted functions in the gene expression of cellular and viral mRNAs. RHA recognizes highly structured nucleotides and catalytically rearranges the various interactions between RNA, DNA, and protein molecules to provide a platform for the ribonucleoprotein complex. We present the first solution structures of the double-stranded RNA-binding domains (dsRBDs), dsRBD1 and dsRBD2, from mouse RHA. We discuss the binding mode of the dsRBDs of RHA, in comparison with the known dsRBD structures in their complexes. Our structural data provide important information for the elucidation of the molecular reassembly mediated by RHA. Proteins 2012;. © 2012 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2012

3. Solution structure of the splicing factor motif of the human Prp18 protein.

Author

He, Fahu, Inoue, Makoto, Kigawa, Takanori, Takahashi, Mari, Kuwasako, Kanako, Tsuda, Kengo, Kobayashi, Naohiro, Terada, Takaho, Shirouzu, Mikako, Güntert, Peter, Yokoyama, Shigeyuki, and Muto, Yutaka

Published

2012

4. AU-rich RNA-binding induces changes in the quaternary structure of AUH.

Author

Kurimoto, Kazuki, Kuwasako, Kanako, Sandercock, Alan M., Unzai, Satoru, Robinson, Carol V., Muto, Yutaka, and Yokoyama, Shigeyuki

Abstract

The human AU RNA binding protein/enoyl-Coenzyme A hydratase (AUH) is a 3-hydroxy-3-methylglutaconyl-CoA dehydratase in the leucine degradation pathway. It also possesses an RNA-binding activity to AUUU repeats, which involves no known conserved RNA-binding domains and is seemingly unrelated to the enzymatic activity. In this study, we performed mass spectrometric analyses to elucidate the oligomeric states of AUH in the presence and absence of RNA. With a short RNA (AUUU) or without RNA, AUH mainly exists as a trimer in solution. On the other hand, the AUH trimer dimerizes upon binding to one molecule of a long RNA containing 24 repeats of the AUUU motif, (AUUU)24A. AUH was crystallized with the long RNA. Although the RNA was disordered in the crystalline lattice, the AUH structure was determined as an asymmetric dimer of trimers with a kink in the alignment of the trimer axes, resulting in the formation of two clefts with significantly different sizes. Proteins 2009. © 2008 Wiley-Liss, Inc. [ABSTRACT FROM AUTHOR]

Published

2009

5. Solution structure of the GUCT domain from human RNA helicase II/Guβ reveals the RRM fold, but implausible RNA interactions.

Author

Ohnishi, Satoshi, Pääkkönen, Kimmo, Koshiba, Seizo, Tochio, Naoya, Sato, Manami, Kobayashi, Naohiro, Harada, Takushi, Watanabe, Satoru, Muto, Yutaka, Güntert, Peter, Tanaka, Akiko, Kigawa, Takanori, and Yokoyama, Shigeyuki

Abstract

Human RNA helicase II/Guα (RH-II/Guα) and RNA helicase II/Guβ (RH-II/Guβ) are paralogues that share the same domain structure, consisting of the DEAD box helicase domain (DEAD), the helicase conserved C-terminal domain (helicase_C), and the GUCT domain. The N-terminal regions of the RH-II/Gu proteins, including the DEAD domain and the helicase_C domain, unwind double-stranded RNAs. The C-terminal tail of RH-II/Guα, which follows the GUCT domain, folds a single RNA strand, while that of RH-II/Guβ does not, and the GUCT domain is not essential for either the RNA helicase or foldase activity. Thus, little is known about the GUCT domain. In this study, we have determined the solution structure of the RH-II/Guβ GUCT domain. Structural calculations using NOE-based distance restraints and residual dipolar coupling-based angular restraints yielded a well-defined structure with β-α-α-β-β-α-β topology in the region for K585-A659, while the Pfam HMM algorithm defined the GUCT domain as G571-E666. This structure-based domain boundary revealed false positives in the sequence homologue search using the HMM definition. A structural homology search revealed that the GUCT domain has the RRM fold, which is typically found in RNA-interacting proteins. However, it lacks the surface-exposed aromatic residues and basic residues on the β-sheet that are important for the RNA recognition in the canonical RRM domains. In addition, the overall surface of the GUCT domain is fairly acidic, and thus the GUCT domain is unlikely to interact with RNA molecules. Instead, it may interact with proteins via its hydrophobic surface around the surface-exposed tryptophan. Proteins 2009. © 2008 Wiley-Liss, Inc. [ABSTRACT FROM AUTHOR]

Published

2009

6. Crystal structure of archaeal tRNA(m1G37)methyltransferase aTrm5.

Author

Goto-Ito, Sakurako, Ito, Takuhiro, Ishii, Ryohei, Muto, Yutaka, Bessho, Yoshitaka, and Yokoyama, Shigeyuki

Abstract

Methylation of the N1 atom of guanosine at position 37 in tRNA, the position 3′-adjacent to the anticodon, generates the modified nucleoside m1G37. In archaea and eukaryotes, m1G37 synthesis is catalyzed by tRNA(m1G37)methyltransferase (archaeal or eukaryotic Trm5, a/eTrm5). Here we report the crystal structure of archaeal Trm5 (aTrm5) from Methanocaldococcus jannaschii (formerly known as Methanococcus jannaschii) in complex with the methyl donor analogue at 2.2 Å resolution. The crystal structure revealed that the entire protein is composed of three structural domains, D1, D2, and D3. In the a/eTrm5 primary structures, D2 and D3 are highly conserved, while D1 is not conserved. The D3 structure is the Rossmann fold, which is the hallmark of the canonical class-I methyltransferases. The a/eTrm5-defining domain, D2, exhibits structural similarity to some class-I methyltransferases. In contrast, a DALI search with the D1 structure yielded no structural homologues. In the crystal structure, D3 contacts both D1 and D2. The residues involved in the D1:D3 interactions are not conserved, while those participating in the D2:D3 interactions are well conserved. D1 and D2 do not contact each other, and the linker between them is disordered. aTrm5 fragments corresponding to the D1 and D2-D3 regions were prepared in a soluble form. The NMR analysis of the D1 fragment revealed that D1 is well folded by itself, and it did not interact with either the D2-D3 fragment or the tRNA. The NMR analysis of the D2-D3 fragment revealed that it is well folded, independently of D1, and that it interacts with tRNA. Furthermore, the D2-D3 fragment was as active as the full-length enzyme for tRNA methylation. The positive charges on the surface of D2-D3 may be involved in tRNA binding. Therefore, these findings suggest that the interaction between D1 and D3 is not persistent, and that the D2-D3 region plays the major role in tRNA methylation. © 2008 Wiley-Liss, Inc. [ABSTRACT FROM AUTHOR]

Published

2008

7. Complex assembly mechanism and an RNA-binding mode of the human p14-SF3b155 spliceosomal protein complex identified by NMR solution structure and functional analyses.

Author

Kuwasako, Kanako, Dohmae, Naoshi, Inoue, Mio, Shirouzu, Mikako, Taguchi, Seiichi, Güntert, Peter, Séraphin, Bertrand, Muto, Yutaka, and Yokoyama, Shigeyuki

Abstract

The spliceosomal protein p14, a component of the SF3b complex in the U2 small nuclear ribonucleoprotein (snRNP), is essential for the U2 snRNP to recognize the branch site adenosine. The elucidation of the dynamic process of the splicing machinery rearrangement awaited the solution structural information. We identified a suitable complex of human p14 and the SF3b155 fragment for the determination of its solution structure by NMR. In addition to the overall structure of the complex, which was recently reported in a crystallographic study (typical RNA recognition motif fold β1-α1-β2-β3-α2-β4 of p14, and αA-βA fold of the SF3b155 fragment), we identified three important features revealed by the NMR solution structure. First, the C-terminal extension and the nuclear localization signal of p14 (α3 and α4 in the crystal structure, respectively) were dispensable for the complex formation. Second, the proline-rich segment of SF3b155, following βA, closely approaches p14. Third, interestingly, the β1-α1 loop and the α2-β4 β-hairpin form a positively charged groove. Extensive mutagenesis analyses revealed the functional relevance of the residues involved in the protein-protein interactions: two aromatic residues of SF3b155 (Phe408 and Tyr412) play crucial roles in the complex formation, and two hydrophobic residues (Val414 and Leu415) in SF3b 155 serve as an anchor for the complex formation, by cooperating with the aromatic residues. These findings clearly led to the conclusion that SFb155 binds to p14 with three contact points, involving Phe408, Tyr412, and Val414/Leu415. Furthermore, to dissect the interactions between p14 and the branch site RNA, we performed chemical-shift-perturbation experiments, not only for the main-chain but also for the side-chain resonances, for several p14-SF3b155 complex constructs upon binding to RNA. These analyses identified a positively charged groove and the C-terminal extension of p14 as RNA-binding sites. Strikingly, an aromatic residue in the β1-α1 loop, Tyr28, and a positively charged residue in the α2-β4 β-hairpin, Agr85, are critical for the RNA-binding activity of the positively charged groove. The Tyr28Ala and Arg85Ala point mutants and a deletion mutant of the C-terminal extension clearly revealed that their RNA binding activities were independent of each other. Collectively, this study provides details for the protein-recognition mode of p14 and insight into the branch site recognition. Proteins 2008. © 2007 Wiley-Liss, Inc. [ABSTRACT FROM AUTHOR]

Published

2008

8. Solution structure of the GUCT domain from human RNA helicase II/Gu beta reveals the RRM fold, but implausible RNA interactions.

Author

Ohnishi S, Pääkkönen K, Koshiba S, Tochio N, Sato M, Kobayashi N, Harada T, Watanabe S, Muto Y, Güntert P, Tanaka A, Kigawa T, and Yokoyama S

Subjects

Algorithms, Humans, Magnetic Resonance Spectroscopy, Protein Structure, Tertiary, Structural Homology, Protein, DEAD-box RNA Helicases chemistry, DEAD-box RNA Helicases metabolism, RNA metabolism

Abstract

Human RNA helicase II/Gu alpha (RH-II/Gu alpha) and RNA helicase II/Gu beta (RH-II/Gu beta) are paralogues that share the same domain structure, consisting of the DEAD box helicase domain (DEAD), the helicase conserved C-terminal domain (helicase_C), and the GUCT domain. The N-terminal regions of the RH-II/Gu proteins, including the DEAD domain and the helicase_C domain, unwind double-stranded RNAs. The C-terminal tail of RH-II/Gu alpha, which follows the GUCT domain, folds a single RNA strand, while that of RH-II/Gu beta does not, and the GUCT domain is not essential for either the RNA helicase or foldase activity. Thus, little is known about the GUCT domain. In this study, we have determined the solution structure of the RH-II/Gu beta GUCT domain. Structural calculations using NOE-based distance restraints and residual dipolar coupling-based angular restraints yielded a well-defined structure with beta-alpha-alpha-beta-beta-alpha-beta topology in the region for K585-A659, while the Pfam HMM algorithm defined the GUCT domain as G571-E666. This structure-based domain boundary revealed false positives in the sequence homologue search using the HMM definition. A structural homology search revealed that the GUCT domain has the RRM fold, which is typically found in RNA-interacting proteins. However, it lacks the surface-exposed aromatic residues and basic residues on the beta-sheet that are important for the RNA recognition in the canonical RRM domains. In addition, the overall surface of the GUCT domain is fairly acidic, and thus the GUCT domain is unlikely to interact with RNA molecules. Instead, it may interact with proteins via its hydrophobic surface around the surface-exposed tryptophan., ((c) 2008 Wiley-Liss, Inc.)

Published

2009

9. Crystal structure of archaeal tRNA(m(1)G37)methyltransferase aTrm5.

Author

Goto-Ito S, Ito T, Ishii R, Muto Y, Bessho Y, and Yokoyama S

Subjects

Amino Acid Sequence, Animals, Catalytic Domain, Cloning, Molecular, Crystallization, Crystallography, X-Ray, Humans, Methylation, Molecular Sequence Data, Protein Structure, Tertiary, Sequence Alignment, Archaeal Proteins chemistry, Methanococcus enzymology, tRNA Methyltransferases chemistry

Abstract

Methylation of the N1 atom of guanosine at position 37 in tRNA, the position 3'-adjacent to the anticodon, generates the modified nucleoside m(1)G37. In archaea and eukaryotes, m(1)G37 synthesis is catalyzed by tRNA(m(1)G37)methyltransferase (archaeal or eukaryotic Trm5, a/eTrm5). Here we report the crystal structure of archaeal Trm5 (aTrm5) from Methanocaldococcus jannaschii (formerly known as Methanococcus jannaschii) in complex with the methyl donor analogue at 2.2 A resolution. The crystal structure revealed that the entire protein is composed of three structural domains, D1, D2, and D3. In the a/eTrm5 primary structures, D2 and D3 are highly conserved, while D1 is not conserved. The D3 structure is the Rossmann fold, which is the hallmark of the canonical class-I methyltransferases. The a/eTrm5-defining domain, D2, exhibits structural similarity to some class-I methyltransferases. In contrast, a DALI search with the D1 structure yielded no structural homologues. In the crystal structure, D3 contacts both D1 and D2. The residues involved in the D1:D3 interactions are not conserved, while those participating in the D2:D3 interactions are well conserved. D1 and D2 do not contact each other, and the linker between them is disordered. aTrm5 fragments corresponding to the D1 and D2-D3 regions were prepared in a soluble form. The NMR analysis of the D1 fragment revealed that D1 is well folded by itself, and it did not interact with either the D2-D3 fragment or the tRNA. The NMR analysis of the D2-D3 fragment revealed that it is well folded, independently of D1, and that it interacts with tRNA. Furthermore, the D2-D3 fragment was as active as the full-length enzyme for tRNA methylation. The positive charges on the surface of D2-D3 may be involved in tRNA binding. Therefore, these findings suggest that the interaction between D1 and D3 is not persistent, and that the D2-D3 region plays the major role in tRNA methylation., (2008 Wiley-Liss, Inc.)

Published

2008