Your search keyword '"Ka Man Tse"' showing total 21 results

1. IRAK1-dependent Regnase-1-14-3-3 complex formation controls Regnase-1-mediated mRNA decay

Author

Kotaro Akaki, Kosuke Ogata, Yuhei Yamauchi, Noriki Iwai, Ka Man Tse, Fabian Hia, Atsushi Mochizuki, Yasushi Ishihama, Takashi Mino, and Osamu Takeuchi

Subjects

post-transcriptional regulation, inflammation, 14-3-3, phosphorylation, RNase, interactome, Medicine, Science, Biology (General), QH301-705.5

Abstract

Regnase-1 is an endoribonuclease crucial for controlling inflammation by degrading mRNAs encoding cytokines and inflammatory mediators in mammals. However, it is unclear how Regnase-1-mediated mRNA decay is controlled in interleukin (IL)-1β- or Toll-like receptor (TLR) ligand-stimulated cells. Here, by analyzing the Regnase-1 interactome, we found that IL-1β or TLR stimulus dynamically induced the formation of Regnase-1-β-transducin repeat-containing protein (βTRCP) complex. Importantly, we also uncovered a novel interaction between Regnase-1 and 14-3-3 in both mouse and human cells. In IL-1R/TLR-stimulated cells, the Regnase-1-14-3-3 interaction is mediated by IRAK1 through a previously uncharacterized C-terminal structural domain. Phosphorylation of Regnase-1 at S494 and S513 is critical for Regnase-1-14-3-3 interaction, while a different set of phosphorylation sites of Regnase-1 is known to be required for the recognition by βTRCP and proteasome-mediated degradation. We found that Regnase-1-14-3-3 and Regnase-1-βTRCP interactions are not sequential events. Rather, 14-3-3 protects Regnase-1 from βTRCP-mediated degradation. On the other hand, 14-3-3 abolishes Regnase-1-mediated mRNA decay by inhibiting Regnase-1-mRNA association. In addition, nuclear-cytoplasmic shuttling of Regnase-1 is abrogated by 14-3-3 interaction. Taken together, the results suggest that a novel inflammation-induced interaction of 14-3-3 with Regnase-1 stabilizes inflammatory mRNAs by sequestering Regnase-1 in the cytoplasm to prevent mRNA recognition.

Published

2021

2. Innate immune sensing of pathogens and its post-transcriptional regulations by RNA-binding proteins

Author

Ka Man Tse and Osamu Takeuchi

Subjects

Organic Chemistry, Drug Discovery, Molecular Medicine

Published

2023

3. Enhancement of Regnase-1 expression with stem loop–targeting antisense oligonucleotides alleviates inflammatory diseases

Author

Ka Man Tse, Alexis Vandenbon, Xiaotong Cui, Takashi Mino, Takuya Uehata, Keiko Yasuda, Ayuko Sato, Tohru Tsujimura, Fabian Hia, Masanori Yoshinaga, Makoto Kinoshita, Tatsusada Okuno, and Osamu Takeuchi

Subjects

Inflammation, Mice, Endoribonucleases, Animals, Humans, RNA, Messenger, General Medicine, Oligonucleotides, Antisense, 3' Untranslated Regions, Autoimmune Diseases

Abstract

Regnase-1 is an ribonuclease that plays essential roles in restricting inflammation through degrading messenger RNAs (mRNAs) involved in immune reactions via the recognition of stem-loop (SL) structures in the 3′ untranslated regions (3′UTRs). Dysregulated expression of Regnase-1 is associated with the pathogenesis of inflammatory and autoimmune diseases in mice and humans. Here, we developed a therapeutic strategy to suppress inflammatory responses by blocking Regnase-1 self-regulation, which was mediated by the simultaneous use of two antisense phosphorodiamidate morpholino oligonucleotides (MOs) to alter the binding of Regnase-1 toward the SL structures in its 3′UTR. Regnase-1–targeting MOs not only enhanced Regnase-1 expression by stabilizing mRNAs but also effectively reduced the expression of multiple proinflammatory transcripts that were controlled by Regnase-1 in macrophages. Intratracheal administration of Regnase-1–targeting MOs ameliorated acute respiratory distress syndrome and chronic fibrosis through suppression of inflammatory cascades. In addition, intracranial treatment with Regnase-1–targeting MOs attenuated the development of experimental autoimmune encephalomyelitis by promoting the expansion of homeostatic microglia and regulatory T cell populations. Regnase-1 expression was inversely correlated with disease severity in patients with multiple sclerosis, and MOs targeting human Regnase-1 SL structures were effective in mitigating cytokine production in human immune cells. Collectively, MO-mediated disruption of the Regnase-1 self-regulation pathway is a potential therapeutic strategy to enhance Regnase-1 abundance, which, in turn, provides therapeutic benefits for treating inflammatory diseases by suppressing inflammation.

Published

2022

4. Author response: IRAK1-dependent Regnase-1-14-3-3 complex formation controls Regnase-1-mediated mRNA decay

Author

Fabian Hia, Kosuke Ogata, Kotaro Akaki, Ka Man Tse, Osamu Takeuchi, Yasushi Ishihama, Yuhei Yamauchi, Noriki Iwai, Takashi Mino, and Atsushi Mochizuki

Subjects

Chemistry, Complex formation, MRNA Decay, IRAK1, Cell biology

Published

2021

5. IRAK1-dependent Regnase-1-14-3-3 complex formation controls Regnase-1-mediated mRNA decay

Author

Yuhei Yamauchi, Kosuke Ogata, Kotaro Akaki, Noriki Iwai, Fabian Hia, Atsushi Mochizuki, Takashi Mino, Yasushi Ishihama, Ka Man Tse, and Osamu Takeuchi

Subjects

Mouse, QH301-705.5, RNA Stability, Science, Endoribonuclease, interactome, Inflammation, General Biochemistry, Genetics and Molecular Biology, Mice, Ribonucleases, Immunology and Inflammation, medicine, Animals, RNase, RNA, Messenger, Biology (General), Beta (finance), Receptor, Post-transcriptional regulation, 14-3-3, Messenger RNA, General Immunology and Microbiology, phosphorylation, Chemistry, General Neuroscience, Interleukin, IRAK1, General Medicine, Cell biology, Interleukin-1 Receptor-Associated Kinases, inflammation, Cytoplasm, Multiprotein Complexes, Medicine, Phosphorylation, medicine.symptom, Research Article, Human, post-transcriptional regulation

Abstract

Regnase-1 is an endoribonuclease crucial for controlling inflammation by degrading mRNAs encoding cytokines and inflammatory mediators in mammals. However, it is unclear how Regnase-1-mediated mRNA decay is controlled in interleukin (IL)-1β- or Toll-like receptor (TLR) ligand-stimulated cells. Here, by analyzing the Regnase-1 interactome, we found that IL-1β or TLR stimulus dynamically induced the formation of Regnase-1-β-transducin repeat-containing protein (βTRCP) complex. Importantly, we also uncovered a novel interaction between Regnase-1 and 14-3-3 in both mouse and human cells. In IL-1R/TLR-stimulated cells, the Regnase-1-14-3-3 interaction is mediated by IRAK1 through a previously uncharacterized C-terminal structural domain. Phosphorylation of Regnase-1 at S494 and S513 is critical for Regnase-1-14-3-3 interaction, while a different set of phosphorylation sites of Regnase-1 is known to be required for the recognition by βTRCP and proteasome-mediated degradation. We found that Regnase-1-14-3-3 and Regnase-1-βTRCP interactions are not sequential events. Rather, 14-3-3 protects Regnase-1 from βTRCP-mediated degradation. On the other hand, 14-3-3 abolishes Regnase-1-mediated mRNA decay by inhibiting Regnase-1-mRNA association. In addition, nuclear-cytoplasmic shuttling of Regnase-1 is abrogated by 14-3-3 interaction. Taken together, the results suggest that a novel inflammation-induced interaction of 14-3-3 with Regnase-1 stabilizes inflammatory mRNAs by sequestering Regnase-1 in the cytoplasm to prevent mRNA recognition., 炎症が制御される新たなメカニズムの解明 --タンパク質「14-3-3」を介した新たなRegnase-1の抑制機序--. 京都大学プレスリリース. 2021-10-19.

Published

2021

6. My Race Is My Gender : Portraits of Nonbinary People of Color

Author

Stephanie Hsu, Ka-Man Tse, Stephanie Hsu, and Ka-Man Tse

Subjects

Minorities--Race identity, Gender-nonconforming people--Identity, Transgender people--Identity

Abstract

Genderqueer and nonbinary people of color often experience increased marginalization, belonging to an ethnic group that seldom recognizes their gender identity and a queer community that subscribes to white norms. Yet for this very reason, they have a lot to teach about how racial, sexual, and gender identities intersect. Their experiences of challenging social boundaries demonstrate how queer communities can become more inclusive and how the recognition of nonbinary genders can be an anti-racist practice. My Race is My Gender is the first anthology by nonbinary writers of color to include photography and visual portraits, centering their everyday experiences of negotiating intersectional identities. While informed by queer theory and critical race theory, the authors share their personal stories in accessible language. Bringing together Black, Indigenous, Latine, and Asian perspectives, its six contributors present an intergenerational look at what it means to belong to marginalized queer communities in the U.S. and feel solidarity with a global majority at the same time. They also provide useful insights into how genderqueer and nonbinary activism can both energize and be fueled by such racial justice movements as Black Lives Matter.

Published

2024

7. Crystallographic study of dioxygen chemistry in a copper-containing nitrite reductase fromGeobacillus thermodenitrificans

Author

Eiichi Mizohata, Tsuyoshi Inoue, Yohta Fukuda, Michael E. P. Murphy, Takuro Matsusaki, and Ka Man Tse

Subjects

0301 basic medicine, Nitrite Reductases, Crystallography, X-Ray, Ligands, 010402 general chemistry, 01 natural sciences, Peroxide, Catalysis, 03 medical and health sciences, chemistry.chemical_compound, Structural Biology, Oxidoreductase, Catalytic Domain, Nitrite, Hydrogen peroxide, chemistry.chemical_classification, Chemistry, Ligand, Thermophile, Geobacillus, Water, Hydrogen Peroxide, Nitrite reductase, 0104 chemical sciences, Oxygen, Crystallography, 030104 developmental biology, Synchrotrons, Protein Binding

Abstract

Copper-containing nitrite reductases (CuNIRs) are multifunctional enzymes that catalyse the one-electron reduction of nitrite (NO2−) to nitric oxide (NO) and the two-electron reduction of dioxygen (O2) to hydrogen peroxide (H2O2). In contrast to the mechanism of nitrite reduction, that of dioxygen reduction is poorly understood. Here, results from anaerobic synchrotron-radiation crystallography (SRX) and aerobic in-house radiation crystallography (iHRX) with a CuNIR from the thermophileGeobacillus thermodenitrificans(GtNIR) support the hypothesis that the dioxygen present in an aerobically manipulated crystal can bind to the catalytic type 2 copper (T2Cu) site ofGtNIR during SRX experiments. The anaerobic SRX structure showed a dual conformation of one water molecule as an axial ligand in the T2Cu site, while previous aerobic SRXGtNIR structures were refined as diatomic molecule-bound states. Moreover, an SRX structure of the C135A mutant ofGtNIR with peroxide bound to the T2Cu atom was determined. The peroxide molecule was mainly observed in a side-on binding manner, with a possible minor end-on conformation. The structures provide insights into dioxygen chemistry in CuNIRs and hence help to unmask the other face of CuNIRs.

Published

2018

8. Intrinsic Cleavage of RNA Polymerase II Adopts a Nucleobase-independent Mechanism Assisted by Transcript Phosphate

Author

Hoi Yee Chow, Xuhui Huang, Shenglong Wang, Jun Xu, Peter Pak-Hang Cheung, Yingkai Zhang, Xin Gao, Dong Wang, Xuechen Li, Liang Xu, Fu Kit Sheong, and Carmen Ka Man Tse

Subjects

Nuclease, biology, Chemistry, Guanine, Process Chemistry and Technology, Active site, Bioengineering, RNA polymerase II, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Cleavage (embryo), Phosphate, 01 natural sciences, Biochemistry, Molecular mechanics, Catalysis, Article, 0104 chemical sciences, Nucleobase, chemistry.chemical_compound, biology.protein, Biophysics, 0210 nano-technology

Abstract

RNA polymerase II (Pol II) utilises the same active site for polymerization and intrinsic cleavage. Pol II proofreads the nascent transcript by its intrinsic nuclease activity to maintain high transcriptional fidelity critical for cell growth and viability. The detailed catalytic mechanism of intrinsic cleavage remains unknown. Here, we combined ab initio quantum mechanics/molecular mechanics studies and biochemical cleavage assays to show that Pol II utilises downstream phosphate oxygen to activate the attacking nucleophile in hydrolysis, while the newly formed 3'-end is protonated through active-site water without a defined general acid. Experimentally, alteration of downstream phosphate oxygen either by 2'-5' sugar linkage or stereo-specific thio-substitution of phosphate oxygen drastically reduced cleavage rate. We showed by N7-modification that guanine nucleobase does not directly involve as acid-base catalyst. Our proposed mechanism provides important insights into the understanding of intrinsic transcriptional cleavage reaction, an essential step of transcriptional fidelity control.

Published

2019

9. 8-Oxo-guanine DNA damage induces transcription errors by escaping two distinct fidelity control checkpoints of RNA polymerase II

Author

Dong Wang, Juntaek Oh, Kirill A. Konovalov, Xuhui Huang, Carmen Ka Man Tse, and Fátima Pardo-Avila

Subjects

0301 basic medicine, Guanine, Saccharomyces cerevisiae Proteins, DNA damage, RNA polymerase II, Saccharomyces cerevisiae, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Adenosine Triphosphate, Transcription (biology), Catalytic Domain, Molecular Biology, 030102 biochemistry & molecular biology, biology, Chemistry, Active site, RNA, Cell Biology, In vitro transcription, 030104 developmental biology, Models, Chemical, biology.protein, Biophysics, RNA Polymerase II, Molecular Biophysics, DNA Damage

Abstract

RNA polymerase II (Pol II) has an intrinsic fidelity control mechanism to maintain faithful genetic information transfer during transcription. 8-Oxo-guanine (8OG), a commonly occurring damaged guanine base, promotes misincorporation of adenine into the RNA strand. Recent structural work has shown that adenine can pair with the syn conformation of 8OG directly upstream of the Pol II active site. However, it remains unknown how 8OG is accommodated in the active site as a template base for the incoming ATP. Here, we used molecular dynamics (MD) simulations to investigate two consecutive steps that may contribute to the adenine misincorporation by Pol II. First, the mismatch is located in the active site, contributing to initial incorporation of adenine. Second, the mismatch is in the adjacent upstream position, contributing to extension from the mismatched bp. These results are supported by an in vitro transcription assay, confirming that 8OG can induce adenine misincorporation. Our simulations further suggest that 8OG forms a stable bp with the mismatched adenine in both the active site and the adjacent upstream position. This stability predominantly originates from hydrogen bonding between the mismatched adenine and 8OG in a noncanonical syn conformation. Interestingly, we also found that an unstable bp present directly upstream of the active site, such as adenine paired with 8OG in the canonical anti conformation, largely disrupts the stability of the active site. Our findings have uncovered two main factors contributing to how 8OG induces transcriptional errors and escapes Pol II transcriptional fidelity control checkpoints.

Published

2018

10. Redox-coupled structural changes in nitrite reductase revealed by serial femtosecond and microfocus crystallography

Author

Makina Yabashi, Yasumasa Joti, So Iwata, Hiroyoshi Matsumura, Ka Man Tse, Takaki Hatsui, Yohta Fukuda, Takashi Kameshima, Changyong Song, Tsuyoshi Inoue, Eriko Nango, Eiichi Mizohata, Kunio Hirata, K. Tono, Kay Diederichs, Mamoru Suzuki, Takanori Nakane, Osamu Nureki, and Michihiro Sugahara

Subjects

0301 basic medicine, Reaction mechanism, serial femtosecond crystallography, Nitrite Reductases, chemistry.chemical_element, 010402 general chemistry, 01 natural sciences, Biochemistry, Redox, 03 medical and health sciences, chemistry.chemical_compound, Electron transfer, Bacterial Proteins, Oxidoreductase, ddc:570, Catalytic Domain, Nitrite, Molecular Biology, chemistry.chemical_classification, Chemistry, Resolution (electron density), Regular Papers, Geobacillus, General Medicine, Nitrite reductase, electron transfer, Copper, 0104 chemical sciences, Crystallography, enzyme, 030104 developmental biology, copper, X-ray free-electron laser

Abstract

Serial femtosecond crystallography (SFX) has enabled the damage-free structural determination of metalloenzymes and filled the gaps of our knowledge between crystallographic and spectroscopic data. Crystallographers, however, scarcely know whether the rising technique provides truly new structural insights into mechanisms of metalloenzymes partly because of limited resolutions. Copper nitrite reductase (CuNiR), which converts nitrite to nitric oxide in denitrification, has been extensively studied by synchrotron radiation crystallography (SRX). Although catalytic Cu (Type 2 copper (T2Cu)) of CuNiR had been suspected to tolerate X-ray photoreduction, we here showed that T2Cu in the form free of nitrite is reduced and changes its coordination structure in SRX. Moreover, we determined the completely oxidized CuNiR structure at 1.43 Å resolution with SFX. Comparison between the high-resolution SFX and SRX data revealed the subtle structural change of a catalytic His residue by X-ray photoreduction. This finding, which SRX has failed to uncover, provides new insight into the reaction mechanism of CuNiR. published

Published

2016

11. Insights into unknown foreign ligand in copper nitrite reductase

Author

Tsuyoshi Inoue, Eiichi Mizohata, Yuji Kado, Ka Man Tse, Hiroyoshi Matsumura, and Yohta Fukuda

Subjects

Nitrite Reductases, Protein Conformation, Ligand, Biophysics, chemistry.chemical_element, Cell Biology, Crystallography, X-Ray, Ligands, Photochemistry, Nitrite reductase, Biochemistry, Copper, Catalysis, Nitric oxide, chemistry.chemical_compound, chemistry, Spectrophotometry, Ultraviolet, Nitrite, Bifunctional, Hydrogen peroxide, Molecular Biology

Abstract

Bifunctional copper nitrite reductase (CuNIR) catalyzes nitrite reduction to nitric oxide and dioxygen reduction to hydrogen peroxide. In contrast to the well-researched nitrite reduction mechanism, the oxygen reduction mechanism in CuNIR has been totally unknown, because mononuclear copper-oxygen complexes decompose so readily that their visualization has been challenging. Here, we provide spectroscopic evidence that a foreign ligand binds to the catalytic copper (T2Cu) site of CuNIR, and determine CuNIR structures displaying a diatomic molecule on T2Cu. This unknown ligand can be interpreted as dioxygen and may provide insights into the oxygen reduction mechanism of CuNIR.

Published

2015

12. Molecular mechanisms of RNA polymerase II transcription elongation elucidated by kinetic network models

Author

Ilona Christy Unarta, Lizhe Zhu, Peter Pak-Hang Cheung, Xuhui Huang, Carmen Ka Man Tse, and Jin Yu

Subjects

0301 basic medicine, Transcription Elongation, Genetic, Transcription elongation, TEC, education, RNA polymerase II, Computational biology, Saccharomyces cerevisiae, Molecular Dynamics Simulation, 03 medical and health sciences, chemistry.chemical_compound, Sequence dependent, Structural Biology, Animals, Humans, Molecular Biology, Network model, State model, Messenger RNA, biology, hemic and immune systems, Markov Chains, Kinetics, 030104 developmental biology, chemistry, Nucleoside triphosphate, biology.protein, RNA Polymerase II, tissues

Abstract

Transcription elongation cycle (TEC) of RNA polymerase II (Pol II) is a process of adding a nucleoside triphosphate to the growing messenger RNA chain. Due to the long timescale events in Pol II TEC, an advanced computational technique, such as Markov State Model (MSM), is needed to provide atomistic mechanism and reaction rates. The combination of MSM and experimental results can be used to build a kinetic network model (KNM) of the whole TEC. This review provides a brief protocol to build MSM and KNM of the whole TEC, along with the latest findings of MSM and other computational studies of Pol II TEC. Lastly, we offer a perspective on potentially using a sequence dependent KNM to predict genome-wide transcription error.

Published

2017

13. Active site geometry of a novel aminopropyltransferase for biosynthesis of hyperthermophile-specific branched-chain polyamine

Author

Tadayuki Imanaka, Ka Man Tse, Shinsuke Fujiwara, Masaru Niitsu, Tairo Oshima, Junso Fujita, Eiichi Mizohata, Naoki Umezawa, Seigo Kimura, Tsuyoshi Inoue, Tsunehiko Higuchi, Yuhei Horai, and Ryota Hidese

Subjects

0301 basic medicine, Stereochemistry, Spermine, Biochemistry, Spermidine Synthase, 03 medical and health sciences, chemistry.chemical_compound, Catalytic Domain, Polyamines, Molecular Biology, Ternary complex, biology, Norspermidine, Active site, Cell Biology, biology.organism_classification, Thermococcus kodakarensis, Spermidine, Thermococcus, Kinetics, 030104 developmental biology, chemistry, biology.protein, Putrescine, Biocatalysis, Mutagenesis, Site-Directed, Polyamine

Abstract

Branched-chain polyamines are found exclusively in thermophilic bacteria and Euryarchaeota and play essential roles in survival at high temperatures. In the present study, kinetic analyses of a branched-chain polyamine synthase from the hyperthermophilic archaeon Thermococcus kodakarensis (Tk-BpsA) were conducted, showing that N4-bis(aminopropyl)spermidine was produced by sequential additions of decarboxylated S-adenosylmethionine (dcSAM) aminopropyl groups to spermidine, through bifunctional catalytic action. Tk-BpsA catalyzed the aminopropylation of the linear-chain polyamines spermidine, spermine, norspermidine, and the tertiary-branched polyamines N4-aminopropylspermidine and N4-aminopropylnorspermidine, but not of short-chain diamines, putrescine, and cadaverine, suggesting that Tk-BpsA does not catalyze the aminopropylation of primary amino groups of diamines. X-ray structural analyses of Tk-BpsA in the presence or absence of the substrates spermidine and dcSAM revealed that a large, negatively charged cavity is responsible for the binding of branched-chain substrates. The binding is different from that in the active site of linear polyamine spermidine/spermine synthases, and loop-closures occur upon the binding of spermidine. Based on structural analyses, further kinetic studies were carried out for various mutants, revealing that Asp159, positioned between the reactive secondary amino group of the substrate polyamine and a sulfur atom of the product 5ʹ-methylthioadenosine and in a Gly-Asp-Asp-Asp motif, functions as a catalytic center, with reactions proceeding via a ping-pong mechanism. Our study provides a novel aminopropyltransfer reaction mechanism, distinct from the SN2 displacement mechanism found in other known linear spermidine/spermine synthases. Database Atomic coordinates and structure factors have been deposited in the Protein Data Bank with PDB codes 5XNF for apo-Tk-BpsA, 5XNH for the binary complex, and 5XNC for the ternary complex.

Published

2017

14. QM/MM study of intrinsic cleavage mechanism in backtracked RNA polymerase II

Author

Ka Man Tse

Published

2017

15. Correction for Fukuda et al., Redox-coupled proton transfer mechanism in nitrite reductase revealed by femtosecond crystallography

Author

Toru Nakatsu, Osamu Nureki, Tetsuya Masuda, Ka Man Tse, Kensuke Tono, Yohta Fukuda, Takashi Kameshima, Eiichi Mizohata, Makina Yabashi, Takaki Hatsui, Naohiro Matsugaki, Fumiaki Yumoto, Yasumasa Joti, Michihiro Sugahara, Shigeyuki Inoue, So Iwata, Michael P. Murphy, Changyong Song, Tsuyoshi Inoue, Eriko Nango, Mamoru Suzuki, and Takanori Nakane

Subjects

Multidisciplinary, Proton, Chemistry, Transfer mechanism, Femtosecond, Biological Sciences, Nitrite reductase, Photochemistry, Redox

Abstract

Copper nitrite reductase (CuNiR) is involved in denitrification of the nitrogen cycle. Synchrotron X-rays rapidly reduce copper sites and decompose the substrate complex structure, which has made crystallographic studies of CuNiR difficult. Using femtosecond X-ray free electron lasers, we determined intact structures of CuNiR with and without nitrite. Based on the obtained structures, we proposed a redox-coupled proton switch model, which provides an explanation for proton-coupled electron transfer (PCET) in CuNiR. PCET is widely distributed through biogenic processes including respiratory and photosynthetic systems and is highly expected to be incorporated into bioinspired molecular devices. Our study also establishes the foundation for future studies on PCET in other systems.

Published

2016

16. Redox-coupled proton transfer mechanism in nitrite reductase revealed by femtosecond crystallography

Author

Tsuyoshi Inoue, Michihiro Sugahara, Toru Nakatsu, Eriko Nango, Tetsuya Masuda, Osamu Nureki, Mamoru Suzuki, Takanori Nakane, Naohiro Matsugaki, Michael E. P. Murphy, Ka Man Tse, Yasumasa Joti, Takaki Hatsui, Yohta Fukuda, Shigeyuki Inoue, Makina Yabashi, Fumiaki Yumoto, Changyong Song, Takashi Kameshima, So Iwata, K. Tono, and Eiichi Mizohata

Subjects

0301 basic medicine, Models, Molecular, Nitrite Reductases, Protein Conformation, Recombinant Fusion Proteins, Molecular Sequence Data, Mutation, Missense, Crystallography, X-Ray, Redox, Catalysis, 03 medical and health sciences, Electron transfer, chemistry.chemical_compound, Structure-Activity Relationship, Bacterial Proteins, Point Mutation, Amino Acid Sequence, Nitrite, Nitrites, Multidisciplinary, Binding Sites, Alcaligenes faecalis, Hydrogen bond, Substrate (chemistry), Correction, Hydrogen Bonding, Nitrite reductase, Crystallography, 030104 developmental biology, Catalytic cycle, chemistry, Amino Acid Substitution, Intramolecular force, Protons, Oxidation-Reduction, Copper

Abstract

Proton-coupled electron transfer (PCET), a ubiquitous phenomenon in biological systems, plays an essential role in copper nitrite reductase (CuNiR), the key metalloenzyme in microbial denitrification of the global nitrogen cycle. Analyses of the nitrite reduction mechanism in CuNiR with conventional synchrotron radiation crystallography (SRX) have been faced with difficulties, because X-ray photoreduction changes the native structures of metal centers and the enzyme–substrate complex. Using serial femtosecond crystallography (SFX), we determined the intact structures of CuNiR in the resting state and the nitrite complex (NC) state at 2.03- and 1.60-A resolution, respectively. Furthermore, the SRX NC structure representing a transient state in the catalytic cycle was determined at 1.30-A resolution. Comparison between SRX and SFX structures revealed that photoreduction changes the coordination manner of the substrate and that catalytically important His255 can switch hydrogen bond partners between the backbone carbonyl oxygen of nearby Glu279 and the side-chain hydroxyl group of Thr280. These findings, which SRX has failed to uncover, propose a redox-coupled proton switch for PCET. This concept can explain how proton transfer to the substrate is involved in intramolecular electron transfer and why substrate binding accelerates PCET. Our study demonstrates the potential of SFX as a powerful tool to study redox processes in metalloenzymes.

Published

2016

17. Structural insights into the function of a thermostable copper-containing nitrite reductase

Author

Hideto Takami, Hiroyoshi Matsumura, Yohta Fukuda, Masaki Nojiri, Yoshifumi Fukunishi, Tsuyoshi Inoue, Eiichi Mizohata, Ka Man Tse, and Masami Lintuluoto

Subjects

Denitrification, Nitrite Reductases, Hydrogen bond, Stereochemistry, Inorganic chemistry, Molecular Sequence Data, Temperature, chemistry.chemical_element, General Medicine, Crystal structure, Nitrite reductase, Biochemistry, Copper, Nitric oxide, Catalysis, chemistry.chemical_compound, chemistry, Enzyme Stability, Thermodynamics, Electrophoresis, Polyacrylamide Gel, Aeromonas, Amino Acid Sequence, Nitrite, Molecular Biology, Sequence Alignment

Abstract

Copper-containing nitrite reductase (CuNIR) catalyzes the reduction of nitrite (NO(-)2) to nitric oxide (NO) during denitrification. We determined the crystal structures of CuNIR from thermophilic gram-positive bacterium, Geobacillus thermodenitrificans (GtNIR) in chloride- and formate-bound forms of wild type at 1.15 A resolution and the nitrite-bound form of the C135A mutant at 1.90 A resolution. The structure of C135A with nitrite displays a unique η(1)-O coordination mode of nitrite at the catalytic copper site (T2Cu), which has never been observed at the T2Cu site in known wild-type CuNIRs, because the mobility of two residues essential to catalytic activity, Asp98 and His244, are sterically restricted in GtNIR by Phe109 on a characteristic loop structure that is found above Asp98 and by an unusually short CH-O hydrogen bond observed between His244 and water, respectively. A detailed comparison of the WT structure with the nitrite-bound C135A structure implies the replacement of hydrogen-bond networks around His244 and predicts the flow path of protons consumed by nitrite reduction. On the basis of these observations, the reaction mechanism of GtNIR through the η(1)-O coordination manner is proposed.

Published

2013

18. Redox-coupled structural changes in nitrite reductase revealed by serial femtosecond and microfocus crystallography.

Author

Yohta Fukuda, Ka Man Tse, Mamoru Suzuki, Diederichs, Kay, Kunio Hirata, Takanori Nakane, Michihiro Sugahara, Eriko Nango, Kensuke Tono, Yasumasa Joti, Takashi Kameshima, Changyong Song, Takaki Hatsui, Makina Yabashi, Osamu Nureki, Hiroyoshi Matsumura, Tsuyoshi Inoue, So Iwata, and Eiichi Mizohata

Subjects

*CHEMICAL reduction kinetics, *NITRITE reductase, *COPPER research, *CRYSTALLOGRAPHY, *CRYSTAL structure research

Abstract

Serial femtosecond crystallography (SFX) has enabled the damage-free structural determination of metalloenzymes and filled the gaps of our knowledge between crystallographic and spectroscopic data. Crystallographers, however, scarcely know whether the rising technique provides truly new structural insights into mechanisms of metalloenzymes partly because of limited resolutions. Copper nitrite reductase (CuNiR), which converts nitrite to nitric oxide in denitrification, has been extensively studied by synchrotron radiation crystallography (SRX). Although catalytic Cu (Type 2 copper (T2Cu)) of CuNiR had been suspected to tolerate X-ray photoreduction, we here showed that T2Cu in the form free of nitrite is reduced and changes its coordination structure in SRX. Moreover, we determined the completely oxidized CuNiR structure at 1.43 Å resolution with SFX. Comparison between the high-resolution SFX and SRX data revealed the subtle structural change of a catalytic His residue by X-ray photoreduction. This finding, which SRX has failed to uncover, provides new insight into the reaction mechanism of CuNiR. [ABSTRACT FROM AUTHOR]

Published

2016

19. Redox-coupled proton transfer mechanism in nitrite reductase revealed by femtosecond crystallography.

Author

Yohta Fukuda, Ka Man Tse, Takanori Nakane, Toru Nakatsu, Mamoru Suzuki, Michihiro Sugahara, Shigeyuki Inoue, Tetsuya Masuda, Fumiaki Yumoto, Naohiro Matsugaki, Eriko Nango, Kensuke Tono, Yasumasa Joti, Takashi Kameshima, Changyong Song, Takaki Hatsui, Makina Yabashi, Osamu Nureki, Murphy, Michael E. P., and Tsuyoshi Inoue

Subjects

*INTRAMOLECULAR charge transfer, *CRYSTALLOGRAPHY, *METALLOENZYMES, *ENZYME analysis, *PHOTOREDUCTION kinetics

Abstract

Proton-coupled electron transfer (PCET), a ubiquitous phenomenon in biological systems, plays an essential role in copper nitrite reductase (CuNiR), the key metalloenzyme in microbial denitrification of the global nitrogen cycle. Analyses of the nitrite reduction mechanism in CuNiR with conventional synchrotron radiation crystallography (SRX) have been faced with difficulties, because X-ray photoreduction changes the native structures of metal centers and the enzyme-substrate complex. Using serial femtosecond crystallography (SFX), we determined the intact structures of CuNiR in the resting state and the nitrite complex (NC) state at 2.03- and 1.60-Å resolution, respectively. Furthermore, the SRX NC structure representing a transient state in the catalytic cycle was determined at 1.30-Å resolution. Comparison between SRX and SFX structures revealed that photoreduction changes the coordination manner of the substrate and that catalytically important His255 can switch hydrogen bond partners between the backbone carbonyl oxygen of nearby Glu279 and the side-chain hydroxyl group of Thr280. These findings, which SRX has failed to uncover, propose a redoxcoupled proton switch for PCET. This concept can explain how proton transfer to the substrate is involved in intramolecular electron transfer and why substrate binding accelerates PCET. Our study demonstrates the potential of SFX as a powerful tool to study redox processes in metalloenzymes. [ABSTRACT FROM AUTHOR]

Published

2016

20. 8-Oxo-guanine DNA damage induces transcription errors by escaping two distinct fidelity control checkpoints of RNA polymerase II.

Author

Konovalov, Kirill A., Pardo-Avila, Fátima, Carmen Ka Man Tse, Juntaek Oh, Dong Wang, and Xuhui Huang

Subjects

*RNA polymerases, *DNA damage, *RNA polymerase II, *ADENINE, *MOLECULAR dynamics, *LOYALTY

Abstract

RNA polymerase II (Pol II) has an intrinsic fidelity control mechanism to maintain faithful genetic information transfer during transcription. 8-Oxo-guanine (8OG), a commonly occurring damaged guanine base, promotes misincorporation of adenine into the RNA strand. Recent structural work has shown that adenine can pair with the syn conformation of 8OG directly upstream of the Pol II active site. However, it remains unknown how 8OG is accommodated in the active site as a template base for the incoming ATP. Here, we used molecular dynamics (MD) simulations to investigate two consecutive steps that may contribute to the adenine misincorporation by Pol II. First, the mismatch is located in the active site, contributing to initial incorporation of adenine. Second, the mismatch is in the adjacent upstream position, contributing to extension from the mismatched bp. These results are supported by an in vitro transcription assay, confirming that 8OG can induce adenine misincorporation. Our simulations further suggest that 8OG forms a stable bp with the mismatched adenine in both the active site and the adjacent upstream position. This stability predominantly originates from hydrogen bonding between the mismatched adenine and 8OG in a noncanonical syn conformation. Interestingly, we also found that an unstable bp present directly upstream of the active site, such as adenine paired with 8OG in the canonical anti conformation, largely disrupts the stability of the active site. Our findings have uncovered two main factors contributing to how 8OG induces transcriptional errors and escapes Pol II transcriptional fidelity control checkpoints. [ABSTRACT FROM AUTHOR]

Published

2019

21. Intrinsic Cleavage of RNA Polymerase II Adopts a Nucleobase-independent Mechanism Assisted by Transcript Phosphate.

Author

Ka Man Tse C, Xu J, Xu L, Sheong FK, Wang S, Chow HY, Gao X, Li X, Cheung PP, Wang D, Zhang Y, and Huang X

Abstract

RNA polymerase II (Pol II) utilises the same active site for polymerization and intrinsic cleavage. Pol II proofreads the nascent transcript by its intrinsic nuclease activity to maintain high transcriptional fidelity critical for cell growth and viability. The detailed catalytic mechanism of intrinsic cleavage remains unknown. Here, we combined ab initio quantum mechanics/molecular mechanics studies and biochemical cleavage assays to show that Pol II utilises downstream phosphate oxygen to activate the attacking nucleophile in hydrolysis, while the newly formed 3'-end is protonated through active-site water without a defined general acid. Experimentally, alteration of downstream phosphate oxygen either by 2'-5' sugar linkage or stereo-specific thio-substitution of phosphate oxygen drastically reduced cleavage rate. We showed by N7-modification that guanine nucleobase does not directly involve as acid-base catalyst. Our proposed mechanism provides important insights into the understanding of intrinsic transcriptional cleavage reaction, an essential step of transcriptional fidelity control., Competing Interests: Competing interests The authors declare no competing interests

Published

2019