研究者業績

三木 隆司

MIKI TAKASHI

基本情報

所属
千葉大学 大学院医学研究院代謝生理学 教授
学位
博士(医学)(千葉大学)

J-GLOBAL ID
200901084204686804
researchmap会員ID
1000249299

研究キーワード

 3

学歴

 2

論文

 119
  • Junya Suzuki, Shunsuke Furuta, Yosuke Kameoka, Osamu Suzuki, Fuyu Ito, Kazuko Uno, Fukuko Kishi, Yoshio Yamakawa, Kazuyuki Matsushita, Takashi Miki, Hiroshi Nakajima, Kazuo Suzuki
    Microvascular Research 156 104720-104720 2024年11月  査読有り
  • Ryo Hatano, Xilin Zhang, Eunyoung Lee, Atsushi Kaneda, Tomoaki Tanaka, Takashi Miki
    iScience 110656-110656 2024年8月  査読有り最終著者責任著者
  • Ryo Hatano, Eunyoung Lee, Hiromi Sato, Masahiro Kiuchi, Kiyoshi Hirahara, Yoshimi Nakagawa, Hitoshi Shimano, Toshinori Nakayama, Tomoaki Tanaka, Takashi Miki
    Molecular Metabolism 101934-101934 2024年4月  査読有り最終著者責任著者
  • Ikki Sakuma, Hidekazu Nagano, Naoko Hashimoto, Masanori Fujimoto, Akitoshi Nakayama, Takahiro Fuchigami, Yuki Taki, Tatsuma Matsuda, Hiroyuki Akamine, Satomi Kono, Takashi Kono, Masataka Yokoyama, Motoi Nishimura, Koutaro Yokote, Tatsuki Ogasawara, Yoichi Fujii, Seishi Ogawa, Eunyoung Lee, Takashi Miki, Tomoaki Tanaka
    Communications biology 6(1) 787-787 2023年7月28日  査読有り
    Fructose-1,6-bisphosphatase (FBPase) deficiency, caused by an FBP1 mutation, is an autosomal recessive disorder characterized by hypoglycemic lactic acidosis. Due to the rarity of FBPase deficiency, the mechanism by which the mutations cause enzyme activity loss still remains unclear. Here we identify compound heterozygous missense mutations of FBP1, c.491G>A (p.G164D) and c.581T>C (p.F194S), in an adult patient with hypoglycemic lactic acidosis. The G164D and F194S FBP1 mutants exhibit decreased FBP1 protein expression and a loss of FBPase enzyme activity. The biochemical phenotypes of all previously reported FBP1 missense mutations in addition to G164D and F194S are classified into three functional categories. Type 1 mutations are located at pivotal residues in enzyme activity motifs and have no effects on protein expression. Type 2 mutations structurally cluster around the substrate binding pocket and are associated with decreased protein expression due to protein misfolding. Type 3 mutations are likely nonpathogenic. These findings demonstrate a key role of protein misfolding in mediating the pathogenesis of FBPase deficiency, particularly for Type 2 mutations. This study provides important insights that certain patients with Type 2 mutations may respond to chaperone molecules.
  • Hanna Deguchi-Horiuchi, Sawako Suzuki, Eun Young Lee, Takashi Miki, Noriko Yamanaka, Ichiro Manabe, Tomoaki Tanaka, Koutaro Yokote
    Scientific reports 13(1) 7291-7291 2023年5月5日  査読有り
    Glutaminase 2 (GLS2), a master regulator of glutaminolysis that is induced by p53 and converts glutamine to glutamate, is abundant in the liver but also exists in pancreatic β-cells. However, the roles of GLS2 in islets associated with glucose metabolism are unknown, presenting a critical issue. To investigate the roles of GLS2 in pancreatic β-cells in vivo, we generated β-cell-specific Gls2 conditional knockout mice (Gls2 CKO), examined their glucose homeostasis, and validated the findings using a human islet single-cell analysis database. GLS2 expression markedly increased along with p53 in β-cells from control (RIP-Cre) mice fed a high-fat diet. Furthermore, Gls2 CKO exhibited significant diabetes mellitus with gluconeogenesis and insulin resistance when fed a high-fat diet. Despite marked hyperglycaemia, impaired insulin secretion and paradoxical glucagon elevation were observed in high-fat diet-fed Gls2 CKO mice. GLS2 silencing in the pancreatic β-cell line MIN6 revealed downregulation of insulin secretion and intracellular ATP levels, which were closely related to glucose-stimulated insulin secretion. Additionally, analysis of single-cell RNA-sequencing data from human pancreatic islet cells also revealed that GLS2 expression was elevated in β-cells from diabetic donors compared to nondiabetic donors. Consistent with the results of Gls2 CKO, downregulated GLS2 expression in human pancreatic β-cells from diabetic donors was associated with significantly lower insulin gene expression as well as lower expression of members of the insulin secretion pathway, including ATPase and several molecules that signal to insulin secretory granules, in β-cells but higher glucagon gene expression in α-cells. Although the exact mechanism by which β-cell-specific GLS2 regulates insulin and glucagon requires further study, our data indicate that GLS2 in pancreatic β-cells maintains glucose homeostasis under the condition of hyperglycaemia.

MISC

 99

共同研究・競争的資金等の研究課題

 22