Publications by authors named "Mitsunori Ikeguchi"

Toll-like receptors (TLRs) play central roles in innate immune defense against infection by binding to microbial molecules. TLR7 and TLR8 are highly homologous sensors with an RNA ligand preference for single-stranded RNA (ssRNA). Recent works reveal that these TLR sense degradation products of RNA at two distinct binding sites, designated 1st site and 2nd site, rather than long ssRNA.

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Vancomycin-resistant Enterococcus faecium (VRE) is a major cause of nosocomial infections, particularly endocarditis and sepsis. With the diminishing effectiveness of antibiotics against VRE, new antimicrobial agents are urgently needed. Our previous research demonstrated the crucial role of Na-transporting V-ATPase in Enterococcus hirae for growth under alkaline conditions.

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Macaque restricts hepatitis B virus (HBV) infection because its receptor homologue, NTCP (mNTCP), cannot bind preS1 on viral surface. To reveal how mNTCP loses the viral receptor function, we here solve the cryo-electron microscopy structure of mNTCP. Superposing on the human NTCP (hNTCP)-preS1 complex structure shows that Arg158 of mNTCP causes steric clash to prevent preS1 from embedding onto the bile acid tunnel of NTCP.

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  • The study investigates how changes in protein structure, such as mutations, affect the binding of drug inhibitors, specifically methotrexate (MTX), to dihydrofolate reductase (DHFR).
  • Molecular dynamics simulations and Markov state modeling were used to analyze the binding thermodynamics and kinetics for both wild-type and mutant DHFR variants.
  • Findings reveal that mutations can destabilize the primary binding site, leading to increased binding at secondary sites, challenging traditional models of drug sensitivity and suggesting a more complex binding landscape.
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  • Privalov and colleagues studied how hydration enthalpy and entropy change when the protein ubiquitin unfolds, using measurements from various model compounds transitioning from gas to water.
  • They applied statistical-mechanics theory with molecular and atomistic models to estimate these changes, finding their results align well with Privalov's estimates.
  • The study emphasizes the importance of the hydrophobic effect in protein folding and presents new insights into understanding its weakening at lower temperatures, while also addressing issues with measuring changes in enthalpy and entropy at low pH and proposing methods for calculations at neutral pH.
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Nanohoops, an exciting class of fluorophores with supramolecular binding abilities, have the potential to become innovative tools within biological imaging and sensing. Given the biological importance of cell membranes, incorporation of macrocyclic materials with the dual capability of fluorescence emission and supramolecular complexation would be particularly interesting. A series of different-sized nanohoops-ethylene glycol-decorated []cyclo--pyrenylenes (CPYs) ( = 4-8)-were synthesised an alternate synthetic route which implements a stannylation-based precursor, producing purer material than the previous borylation approach, enabling the growth of single-crystals of the Pt-macrocycle.

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Mechanical stress significantly affects the physiological functions of cells, including tissue homeostasis, cytoskeletal alterations, and intracellular transport. As a major cytoskeletal component, microtubules respond to mechanical stimulation by altering their alignment and polymerization dynamics. Previously, we reported that microtubules may modulate cargo transport by one of the microtubule-associated motor proteins, dynein, under compressive mechanical stress.

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Epidermal growth factor receptor (EGFR) activation is accompanied by dimerization. During the activation of the intracellular kinase domain, two EGFR kinases form an asymmetric dimer, and one side of the dimer (receiver) is activated. Using the string method and Markov state model (MSM), we performed a computational analysis of the structural changes in the activation of the EGFR dimer in this study.

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  • Interleukin-2-inducible T-cell kinase (ITK) plays a crucial role in T-cell receptor signaling and is a potential target for drugs that address inflammatory and immune diseases.
  • Compounds that bind to the inactive form of ITK show high selectivity, while those binding to the active form tend to have low selectivity, highlighting the need for computational methods to predict this selectivity.
  • The study employed absolute binding free-energy perturbation (ABFEP) simulations on 11 compounds, with successful predictions of binding preferences for 10 compounds and insights into structural stabilization that inform guidelines for designing selective ITK inhibitors.
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Hydroxycarboxylic acid receptors (HCAR1, HCAR2, and HCAR3) transduce G signaling upon biding to molecules such as lactic acid, butyric acid and 3-hydroxyoctanoic acid, which are associated with lipolytic and atherogenic activity, and neuroinflammation. Although many reports have elucidated the function of HCAR2 and its potential as a therapeutic target for treating not only dyslipidemia but also neuroimmune disorders such as multiple sclerosis and Parkinson's disease, the structural basis of ligand recognition and ligand-induced G-coupling remains unclear. Here we report three cryo-EM structures of the human HCAR2-G signaling complex, each bound with different ligands: niacin, acipimox or GSK256073.

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Tubulin has been recently reported to form a large family consisting of various gene isoforms; however, the differences in the molecular features of tubulin dimers composed of a combination of these isoforms remain unknown. Therefore, we attempted to elucidate the physical differences in the molecular motility of these tubulin dimers using the method of measurable pico-meter-scale molecular motility, diffracted X-ray tracking (DXT) analysis, regarding characteristic tubulin dimers, including neuronal TUBB3 and ubiquitous TUBB5. We first conducted a DXT analysis of neuronal (TUBB3-TUBA1A) and ubiquitous (TUBB5-TUBA1B) tubulin dimers and found that the molecular motility around the vertical axis of the neuronal tubulin dimer was lower than that of the ubiquitous tubulin dimer.

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  • * The structure of human NAP1 includes a core domain essential for binding H2A-H2B, and a flexible C-terminal domain (CTAD) that also engages with the histones, but the specific functions of these domains were previously unclear.
  • * Using various advanced techniques, the study reveals that the first H2A-H2B dimer attaches primarily to NAP1's core domain, while the second dimer interacts with both the core and CTAD, informing a new model
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Mutations of G protein-coupled receptors (GPCRs) cause various human diseases, but the mechanistic details are limited. Here, we establish p.E303K in the gene encoding the endothelin receptor type A (ETAR/EDNRA) as a recurrent mutation causing mandibulofacial dysostosis with alopecia (MFDA), with craniofacial changes similar to those caused by p.

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  • TLR3, part of the TLR family, is crucial for the innate immune system as it detects viral double-stranded RNA (dsRNA).
  • It has been found that TLR3 requires at least 40-50 base pairs of dsRNA to bind, but longer dsRNA is necessary for effective activation, though the mechanism behind this is still unclear.
  • Recent cryo-electron microscopy studies show that TLR3 can form larger multimeric complexes with longer dsRNA, which enhances its binding and signaling capabilities.
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Membrane permeability of cyclic peptides is an important factor in drug design. To investigate the membrane permeability of cyclic peptides using molecular dynamics (MD) simulations, the accurate force fields for unnatural amino acids present in the cyclic peptides are required. Therefore, we developed the CHARMM force fields of the unnatural amino acids present in cyclosporin A (CsA), a cyclic peptide used as an immune suppressor.

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  • The study focuses on the binding mechanism of a peptide substrate to the SARS-CoV-2 3C-like protease (3CL), a key target for COVID-19 treatments.
  • Using weighted ensemble simulation, researchers explored how the peptide changes shape during the binding process, revealing important steps in its folding.
  • Initial peptide movement involved surface diffusion on the protein, leading to the formation of hydrogen bonds in a specific order, crucial for the peptide's recognition by the protease.
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Unlabelled: SARS-CoV-2 3C-like protease (3CL), a potential therapeutic target for COVID-19, consists of a chymotrypsin fold and a C-terminal α-helical domain (domain III), the latter of which mediates dimerization required for catalytic activation. To gain further understanding of the functional dynamics of SARS-CoV-2 3CL, this review extends the scope to the comparative study of many crystal structures of proteases having the chymotrypsin fold (clan PA of the MEROPS database). First, the close correspondence between the zymogen-enzyme transformation in chymotrypsin and the allosteric dimerization activation in SARS-CoV-2 3CL is illustrated.

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Semaphorins constitute a large family of secreted and membrane-bound proteins that signal through cell-surface receptors, plexins. Semaphorins generally use low-affinity protein-protein interactions to bind with their specific plexin(s) and regulate distinct cellular processes such as neurogenesis, immune response, and organogenesis. Sema6D is a membrane-bound semaphorin that interacts with class A plexins.

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  • Hydration plays a key role in biological processes like protein folding and ligand binding, and its distribution around proteins can be calculated using methods like molecular dynamics simulations or the 3D-RISM theory, though these methods are time-consuming.
  • A new deep learning model has been developed to quickly estimate these water distribution functions, achieving results similar to those obtained from the traditional 3D-RISM method, with a coefficient of determination around 0.98.
  • This deep learning model, named "gr Predictor," can make predictions in under 1 minute using a graphics processing unit, making it over 100 times faster than standard calculations, and is freely available for use on GitHub.
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Hydration free energy (HFE) is a key factor in improving protein-ligand binding free energy (BFE) prediction accuracy. The HFE itself can be calculated using the three-dimensional reference interaction model (3D-RISM); however, the BFE predictions solely evaluated using 3D-RISM are not correlated to the experimental BFE for abundant protein-ligand pairs. In this study, to predict the BFE for multiple sets of protein-ligand pairs, we propose a machine learning approach incorporating the HFEs obtained using 3D-RISM, termed 3D-RISM-AI.

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The coronavirus membrane protein (M) is the most abundant viral structural protein and plays a central role in virus assembly and morphogenesis. However, the process of M protein-driven virus assembly are largely unknown. Here, we report the cryo-electron microscopy structure of the SARS-CoV-2 M protein in two different conformations.

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Inspired by mechanosensitive potassium channels found in nature, we developed a fluorinated amphiphilic cyclophane composed of fluorinated rigid aromatic units connected via flexible hydrophilic octa(ethylene glycol) chains. Microscopic and emission spectroscopic studies revealed that the cyclophane could be incorporated into the hydrophobic layer of the lipid bilayer membranes and self-assembled to form a supramolecular transmembrane ion channel. Current recording measurements using cyclophane-containing planer lipid bilayer membranes successfully demonstrated an efficient transmembrane ion transport.

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  • Low-resolution electron density maps can hinder accurate protein structure determination, impacting their use in research and applications.!
  • The new method, QAEmap, utilizes a deep learning approach to assess and enhance local protein structures derived from X-ray crystallography, even when using low-resolution maps.!
  • QAEmap predicts the correlation between local structures and high-resolution electron density maps, which can help correct errors and potentially assist in evaluating ligand binding as well.!
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  • * UHRF1, a protein that maintains DNA methylation, is overexpressed in many cancers; reducing its levels can reactivate tumor suppressor genes, indicating its potential as a therapeutic target.
  • * Researchers developed a new inhibitor, 5-amino-2,4-dimethylpyridine (5A-DMP), which effectively disrupts the interaction between UHRF1 and DNA ligase 1, offering a promising avenue for future cancer therapies.
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