Influential Force: from Higgs to the novel immune checkpoint KYNU
##article.authors##
- Mori, Tsutomu Department of Human Lifesciences, Fukushima Medical University School of Nursing
- Takashi Kawamura Department of Human Lifesciences, Fukushima Medical University School of Nursing
- Daisuke Ikeda Kitajima-cho, Itano-gun
- Susumu Goyama Division of Molecular Oncology, Department of Computational Biology and Medical Sciences, Graduate School of Frontier Sciences, The University of Tokyo
- Hiroshi Haeno Medical Mathematical Modelling Laboratory, Department of Computational Biology and Medical Sciences, Graduate School of Frontier Sciences, The University of Tokyo
- Kazuhiko Ikeda Division of Blood Transfusion and Transplantation Immunology, Fukushima Medical University
-
Yoshiki Yamaguchi
Division of Structural Glycobiology, Institute of Molecular Biomembrane and Glycobiology, Tohoku Medical and Pharmaceutical University
https://researchmap.jp/yoshikiyamaguchi
-
Tsuyoshi Shirai
Department of Frontier Bioscience, Faculty of Bioscience, Nagahama Institute of Bio-Science and Technology
https://researchmap.jp/read0184084
- Katsue Adachi Chi Co., Ltd.
- Yoshihiko Saito Chi Co., Ltd.
- Tomoyoshi Horisawa Chi Co., Ltd.
- Junzo Suzuki Fukushima Preservative Service Association of Health
- Seiichi Takenoshita Fukushima Medical University
DOI:
https://doi.org/10.51094/jxiv.156キーワード:
influential force、 unified theory、 Higgs mechanism、 exchange interaction、 dark energy、 inflation、 equivalence principle、 hierarchy problem、 systems biology、 ab initio genetic orbital method、 bioinformatics、 population genetics、 immune checkpoint KYNU抄録
Nature has a tendency to evolve to a more probable state, and we regard this tendency as a force of probability. All fundamental interactions are transmitted by mediator particles, and their unification has long been attempted. However, no theory has fully unified the interactions into a single simple formula. Here, we show that fundamental interactions are unified by a novel “influential force” driven by probability under the canonical distribution of the transmitted information. This force affects the information distance denoting transmission difficulty, based on a universal gauge symmetry within information coordinate spacetime. We develop statistical mechanics of mutual information and reveal that the influential force exists in both physical and biological systems, offering clues to solve many intractable problems. In the field of physics, the influential force provides a coherent explanation of the spontaneous symmetry breaking of the Higgs field and its relationship with gravity, inflation, quantum entanglement entropy, and the hierarchy problem. In the field of biology, the force endows genes with huge network information, which leads to the development of the ab initio genetic orbital method and identification of a novel, potentially targetable immune checkpoint, KYNU / kynureninase. Our findings demonstrate that the influential force acts between highly divergent beings, thereby shaping the essential properties of nature.
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The authors declare no potential conflict of interests.ダウンロード *前日までの集計結果を表示します
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投稿日時: 2022-09-05 15:16:26 UTC
公開日時: 2022-09-07 23:26:28 UTC — 2023-04-24 07:15:47 UTCに更新
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改版理由
In this revision, the title was changed. We added an in silico method to evaluate the therapeutic targetability of an immune checkpoint of interest, demonstrating that KYNU has a promising therapeutic targetability.ライセンス
Copyright(c)2022
Mori, Tsutomu
Takashi Kawamura
Daisuke Ikeda
Susumu Goyama
Hiroshi Haeno
Kazuhiko Ikeda
Yoshiki Yamaguchi
Tsuyoshi Shirai
Katsue Adachi
Yoshihiko Saito
Tomoyoshi Horisawa
Junzo Suzuki
Seiichi Takenoshita
この作品は、Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International Licenseの下でライセンスされています。
