Your search keyword '"Yagi-Utsumi M"' showing total 5 results

1. Single-Molecule Kinetic Observation of Antibody Interactions with Growing Amyloid β Fibrils.

Author

Yagi-Utsumi M, Kanaoka Y, Miyajima S, Itoh SG, Yanagisawa K, Okumura H, Uchihashi T, and Kato K

Subjects

Kinetics, Humans, Amyloid chemistry, Amyloid metabolism, Alzheimer Disease metabolism, Single Molecule Imaging, Antibodies chemistry, Antibodies immunology, Molecular Dynamics Simulation, Amyloid beta-Peptides chemistry, Amyloid beta-Peptides metabolism, Microscopy, Atomic Force

Abstract

Understanding the dynamic assembly process of amyloid β (Aβ) during fibril formation is essential for developing effective therapeutic strategies against Alzheimer's disease. Here, we employed high-speed atomic force microscopy to observe the growth of Aβ fibrils at the single-molecule level, focusing specifically on their interaction with anti-Aβ antibodies. Our findings show that fibril growth consists of intermittent periods of elongation and pausing, which are dictated by the alternating addition of Aβ monomers to protofilaments. We highlight the distinctive interaction of antibody 4396C, which specifically binds to the fibril ends in the paused state, suggesting a unique mechanism to hinder fibril elongation. Through real-time visualization of fibril growth and antibody interactions combined with molecular simulation, this study provides a refined understanding of Aβ assembly during fibril formation and suggests novel strategies for Alzheimer's therapy aimed at inhibiting the fibril elongation.

Published

2024

2. Physical Isolation of Single Protein Molecules within Well-Defined Coordination Cages to Enhance Their Stability.

Author

Ebihara R, Nakama T, Morishima K, Yagi-Utsumi M, Sugiyama M, Fujita D, Sato S, and Fujita M

Abstract

Encapsulation of a single protein within a confined space can lead to distinct properties compared to bulk solutions, but controlling the number of encapsulated proteins and their environment remains challenging. This study demonstrates the encapsulation of single proteins within well-defined, tunable cavities of self-assembled coordination cages, thereby enhancing protein stability. Within uniform cavities of size-tunable coordination cages, 15 different proteins of varying sizes (3-6 nm in diameter) and properties (e.g., isoelectric points and hydrophobicity) were successfully confined. Various analytical techniques confirmed that the proteins maintained their secondary structures and enzymatic activities under denaturing conditions such as exposure to organic solvents, heat, and buffers. These findings suggest that such coordination cages have the potential to serve as synthetic hosts for precisely controlling protein functions within their customizable cavities., (© 2024 Wiley‐VCH GmbH.)

Published

2024

3. N -linked protein glycosylation in Nanobdellati (formerly DPANN) archaea and their hosts.

Author

Nakagawa S, Sakai HD, Shimamura S, Takamatsu Y, Kato S, Yagi H, Yanaka S, Yagi-Utsumi M, Kurosawa N, Ohkuma M, Kato K, and Takai K

Subjects

Glycosylation, Nanoarchaeota metabolism, Nanoarchaeota genetics, Glycoproteins metabolism, Glycoproteins genetics, Glycoproteins chemistry, Archaea metabolism, Archaea genetics, Polysaccharides metabolism, Membrane Glycoproteins, Archaeal Proteins metabolism, Archaeal Proteins genetics, Archaeal Proteins chemistry

Abstract

Members of the kingdom Nanobdellati , previously known as DPANN archaea, are characterized by ultrasmall cell sizes and reduced genomes. They primarily thrive through ectosymbiotic interactions with specific hosts in diverse environments. Recent successful cultivations have emphasized the importance of adhesion to host cells for understanding the ecophysiology of Nanobdellati . Cell adhesion is often mediated by cell surface carbohydrates, and in archaea, this may be facilitated by the glycosylated S-layer protein that typically coats their cell surface. In this study, we conducted glycoproteomic analyses on two co-cultures of Nanobdellati with their host archaea, as well as on pure cultures of both host and non-host archaea. Nanobdellati exhibited various glycoproteins, including archaellins and hypothetical proteins, with glycans that were structurally distinct from those of their hosts. This indicated that Nanobdellati autonomously synthesize their glycans for protein modifications probably using host-derived substrates, despite the high energy cost. Glycan modifications on Nanobdellati proteins consistently occurred on asparagine residues within the N-X-S/T sequon, consistent with patterns observed across archaea, bacteria, and eukaryotes. In both host and non-host archaea, S-layer proteins were commonly modified with hexose, N -acetylhexosamine, and sulfonated deoxyhexose. However, the N -glycan structures of host archaea, characterized by distinct sugars such as deoxyhexose, nonulosonate sugar, and pentose at the nonreducing ends, were implicated in enabling Nanobdellati to differentiate between host and non-host cells. Interestingly, the specific sugar, xylose, was eliminated from the N -glycan in a host archaeon when co-cultured with Nanobdella . These findings enhance our understanding of the role of protein glycosylation in archaeal interactions.IMPORTANCE Nanobdellati archaea, formerly known as DPANN, are phylogenetically diverse, widely distributed, and obligately ectosymbiotic. The molecular mechanisms by which Nanobdellati recognize and adhere to their specific hosts remain largely unexplored. Protein glycosylation, a fundamental biological mechanism observed across all domains of life, is often crucial for various cell-cell interactions. This study provides the first insights into the glycoproteome of Nanobdellati and their host and non-host archaea. We discovered that Nanobdellati autonomously synthesize glycans for protein modifications, probably utilizing substrates derived from their hosts. Additionally, we identified distinctive glycosylation patterns that suggest mechanisms through which Nanobdellati differentiate between host and non-host cells. This research significantly advances our understanding of the molecular basis of microbial interactions in extreme environments., Competing Interests: The authors declare no conflict of interest.

Published

2024

4. Structural basis of sugar recognition by SCF FBS2 ubiquitin ligase involved in NGLY1 deficiency.

Author

Satoh T, Yagi-Utsumi M, Ishii N, Mizushima T, Yagi H, Kato R, Tachida Y, Tateno H, Matsuo I, Kato K, Suzuki T, and Yoshida Y

Subjects

Animals, Cattle, Humans, Amino Acid Sequence, Binding Sites, Crystallography, X-Ray, F-Box Proteins metabolism, F-Box Proteins chemistry, F-Box Proteins genetics, Models, Molecular, Molecular Docking Simulation, Protein Binding, Peptide-N4-(N-acetyl-beta-glucosaminyl) Asparagine Amidase metabolism, Peptide-N4-(N-acetyl-beta-glucosaminyl) Asparagine Amidase genetics, Peptide-N4-(N-acetyl-beta-glucosaminyl) Asparagine Amidase chemistry

Abstract

The cytosolic peptide:N-glycanase (PNGase) is involved in the quality control of N-glycoproteins via the endoplasmic reticulum-associated degradation (ERAD) pathway. Mutations in the gene encoding cytosolic PNGase (NGLY1 in humans) cause NGLY1 deficiency. Recent findings indicate that the F-box protein FBS2 of the SCF FBS2 ubiquitin ligase complex can be a promising drug target for NGLY1 deficiency. Here, we determined the crystal structure of bovine FBS2 complexed with the adaptor protein SKP1 and a sugar ligand, Man 3 GlcNAc 2 , which corresponds to the core pentasaccharide of N-glycan. Our crystallographic data together with NMR data revealed the structural basis of disparate sugar-binding specificities in homologous FBS proteins and identified a potential druggable pocket for in silico docking studies. Our results provide a potential basis for the development of selective inhibitors against FBS2 in NGLY1 deficiency., (© 2024 Federation of European Biochemical Societies.)

Published

2024

5. Characterization of protein glycosylation in an Asgard archaeon.

Author

Nakagawa S, Imachi H, Shimamura S, Yanaka S, Yagi H, Yagi-Utsumi M, Sakai H, Kato S, Ohkuma M, Kato K, and Takai K

Abstract

Archaeal cells are typically enveloped by glycosylated S-layer proteins. Archaeal protein glycosylation provides valuable insights not only into their adaptation to their niches but also into their evolutionary trajectory. Notably, thermophilic Thermoproteota modify proteins with N -glycans that include two GlcNAc units at the reducing end, resembling the "core structure" preserved across eukaryotes. Recently, Asgard archaea, now classified as members of the phylum Promethearchaeota, have offered unprecedented opportunities for understanding the role of archaea in eukaryogenesis. Despite the presence of genes indicative of protein N -glycosylation in this archaeal group, these have not been experimentally investigated. Here we performed a glycoproteome analysis of the firstly isolated Asgard archaeon Promethearchaeum syntrophicum . Over 700 different proteins were identified through high-resolution LC-MS/MS analysis, however, there was no evidence of either the presence or glycosylation of putative S-layer proteins. Instead, N -glycosylation in this archaeon was primarily observed in an extracellular solute-binding protein, possibly related to chemoreception or transmembrane transport of oligopeptides. The glycan modification occurred on an asparagine residue located within the conserved N-X-S/T sequon, consistent with the pattern found in other archaea, bacteria, and eukaryotes. Unexpectedly, three structurally different N -glycans lacking the conventional core structure were identified in this archaeon, presenting unique compositions that included atypical sugars. Notably, one of these sugars was likely HexNAc modified with a threonine residue, similar to modifications previously observed in mesophilic methanogens within the Methanobacteriati . Our findings advance our understanding of Asgard archaea physiology and evolutionary dynamics., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2024 The Authors.)

Published

2024