Project description:The circadian clock drives daily rhythms of gene expression and physiological functions across tissues throughout the body. Advances in next-generation DNA sequencing have provided extensive insights into gene expression at the RNA level, but more functional information at the protein level with sufficient depth has been limited by technical challenges. Recently, the next-generation mass spectrometer Orbitrap Astral was developed, allowing us to quantify protein abundance with greater sensitivity and accuracy. In this study, we generated a comprehensive mouse circadian proteome atlas (available in URL) by analyzing protein abundance in 32 tissues including the suprachiasmatic nucleus (SCN) across the day using Orbitrap Astral. Data-independent acquisition of 500 samples including developmental samples revealed the spatiotemporal profiles of 18,751 proteins, accounting for 73% of all proteins registered in UniProt. Proteome and phospho-proteome analyses of whole-cell and nuclear proteins in the liver uncovered circadian profiles not only in protein abundance but also in subcellular localization and post-translational modification. Notably, proteome analysis revealed global changes in protein phosphorylation status in hPER2-S662G mutant mice, a genetic model of human familial advanced sleep phase (FASP). This multi-tissue circadian proteome atlas provides a fundamental resource for understanding when, where, and which proteins are expressed and function.

Project description:The circadian clock drives daily rhythms of gene expression and physiological functions across tissues throughout the body. Advances in next-generation DNA sequencing have provided extensive insights into gene expression at the RNA level, but more functional information at the protein level with sufficient depth has been limited by technical challenges. Recently, the next-generation mass spectrometer Orbitrap Astral was developed, allowing us to quantify protein abundance with greater sensitivity and accuracy. In this study, we generated a comprehensive mouse circadian proteome atlas (available in URL) by analyzing protein abundance in 32 tissues including the suprachiasmatic nucleus (SCN) across the day using Orbitrap Astral. Data-independent acquisition of 500 samples including developmental samples revealed the spatiotemporal profiles of 18,751 proteins, accounting for 73% of all proteins registered in UniProt. Proteome and phospho-proteome analyses of whole-cell and nuclear proteins in the liver uncovered circadian profiles not only in protein abundance but also in subcellular localization and post-translational modification. Notably, proteome analysis revealed global changes in protein phosphorylation status in hPER2-S662G mutant mice, a genetic model of human familial advanced sleep phase (FASP). This multi-tissue circadian proteome atlas provides a fundamental resource for understanding when, where, and which proteins are expressed and function.

Project description:The circadian clock drives daily rhythms of gene expression and physiological functions across tissues throughout the body. Advances in next-generation DNA sequencing have provided extensive insights into gene expression at the RNA level, but more functional information at the protein level with sufficient depth has been limited by technical challenges. Recently, the next-generation mass spectrometer Orbitrap Astral was developed, allowing us to quantify protein abundance with greater sensitivity and accuracy. In this study, we generated a comprehensive mouse circadian proteome atlas (available in URL) by analyzing protein abundance in 32 tissues including the suprachiasmatic nucleus (SCN) across the day using Orbitrap Astral. Data-independent acquisition of 500 samples including developmental samples revealed the spatiotemporal profiles of 18,751 proteins, accounting for 73% of all proteins registered in UniProt. Proteome and phospho-proteome analyses of whole-cell and nuclear proteins in the liver uncovered circadian profiles not only in protein abundance but also in subcellular localization and post-translational modification. Notably, proteome analysis revealed global changes in protein phosphorylation status in hPER2-S662G mutant mice, a genetic model of human familial advanced sleep phase (FASP). This multi-tissue circadian proteome atlas provides a fundamental resource for understanding when, where, and which proteins are expressed and function.

Project description:The circadian clock drives daily rhythms of gene expression and physiological functions across tissues throughout the body. Advances in next-generation DNA sequencing have provided extensive insights into gene expression at the RNA level, but more functional information at the protein level with sufficient depth has been limited by technical challenges. Recently, the next-generation mass spectrometer Orbitrap Astral was developed, allowing us to quantify protein abundance with greater sensitivity and accuracy. In this study, we generated a comprehensive mouse circadian proteome atlas (available in URL) by analyzing protein abundance in 32 tissues including the suprachiasmatic nucleus (SCN) across the day using Orbitrap Astral. Data-independent acquisition of 500 samples including developmental samples revealed the spatiotemporal profiles of 18,751 proteins, accounting for 73% of all proteins registered in UniProt. Proteome and phospho-proteome analyses of whole-cell and nuclear proteins in the liver uncovered circadian profiles not only in protein abundance but also in subcellular localization and post-translational modification. Notably, proteome analysis revealed global changes in protein phosphorylation status in hPER2-S662G mutant mice, a genetic model of human familial advanced sleep phase (FASP). This multi-tissue circadian proteome atlas provides a fundamental resource for understanding when, where, and which proteins are expressed and function.

Project description:Differential protein interaction analysis following IP, LC-MS/MS, and label-free quantitation on an Orbitrap Astral

Project description:Meal timing is essential in synchronization of circadian rhythms in different organ systems through clock-dependent and -independent mechanisms. Adipose tissue is a critical metabolic and endocrine organ whose circadian clock and transcriptome can be reset by meal timing. However, it remains largely unexplored how circadian rhythms in adipose tissue are organized in time-restricted feeding that intervenes meal timing. Here, we applied quantitative phospho-proteomics to characterize circadian features associated with ad libitum feeding (ALF), day/inactive phase-restricted feeding (DRF) and night/active phase-restricted feeding (NRF) in female mice.

Project description:LC-MS based DIA label free analysis of trubo-ID driven interaction study

Project description:The circadian clock drives daily rhythms of gene expression and physiological functions across tissues throughout the body. Advances in next-generation DNA sequencing have provided extensive insights into gene expression at the RNA level, but more functional information at the protein level with sufficient depth has been limited by technical challenges. Recently, the next-generation mass spectrometer Orbitrap Astral was developed, allowing us to quantify protein abundance with greater sensitivity and accuracy. In this study, we generated a comprehensive mouse circadian proteome atlas (available in https://chiba1.dynacom.co.jp/mcp_atlas/) by analyzing protein abundance in 32 tissues including the suprachiasmatic nucleus (SCN) across the day using Orbitrap Astral. Data-independent acquisition of 584 samples including developmental samples revealed the spatiotemporal profiles of 18,956 proteins, accounting for 73.8% of all proteins registered in UniProt. Proteome and phospho-proteome analyses of whole-cell and nuclear proteins in the liver uncovered circadian profiles not only in protein abundance but also in subcellular localization and post-translational modification. Notably, proteome analysis revealed global changes in protein phosphorylation status in hPER2-S662G mutant mice, a genetic model of human familial advanced sleep phase (FASP). This multi-tissue circadian proteome atlas provides a fundamental resource for understanding when, where, and which proteins are expressed and function.

Project description:The circadian clock drives daily rhythms of gene expression and physiological functions across tissues throughout the body. Advances in next-generation DNA sequencing have provided extensive insights into gene expression at the RNA level, but more functional information at the protein level with sufficient depth has been limited by technical challenges. Recently, the next-generation mass spectrometer Orbitrap Astral was developed, allowing us to quantify protein abundance with greater sensitivity and accuracy. In this study, we generated a comprehensive mouse circadian proteome atlas (available in https://chiba1.dynacom.co.jp/mcp_atlas/) by analyzing protein abundance in 32 tissues including the suprachiasmatic nucleus (SCN) across the day using Orbitrap Astral. Data-independent acquisition of 584 samples including developmental samples revealed the spatiotemporal profiles of 18,956 proteins, accounting for 73.8% of all proteins registered in UniProt. Proteome and phospho-proteome analyses of whole-cell and nuclear proteins in the liver uncovered circadian profiles not only in protein abundance but also in subcellular localization and post-translational modification. Notably, proteome analysis revealed global changes in protein phosphorylation status in hPER2-S662G mutant mice, a genetic model of human familial advanced sleep phase (FASP). This multi-tissue circadian proteome atlas provides a fundamental resource for understanding when, where, and which proteins are expressed and function.

Project description:This study aims to investigate the protein expression profiles in a murine model of dextran sulfate sodium (DSS)-induced colitis using advanced Astral-DIA quantitative proteomics technology. A total of 12 colon tissue samples were analyzed, including 6 from healthy control mice and 6 from DSS-treated mice with induced colitis. Experimental Design Species: Mus musculus (C57BL/6 strain). Tissue Source: Colon tissues were dissected, snap-frozen in liquid nitrogen, and homogenized to extract proteins. Groups: Control Group: Healthy mice without intervention. DSS Group: Mice subjected to 2.5% DSS administration for 7 days to induce colitis, validated by histopathological assessment.