大学院医学研究院

中山 哲俊

ナカヤマ アキトシ  (Akitoshi Nakayama)

基本情報

所属
千葉大学 大学院医学研究院分子病態解析学 特任助教
学位
博士(医学)(2016年3月 千葉大学)

J-GLOBAL ID
201801018195508008
researchmap会員ID
B000311195

外部リンク

千葉大学大学院 医学研究院 分子病態解析学講座で、癌抑制遺伝子p53の変異がもたらす"gain of function"に着目し、コレステロール合成経路を介したがん悪性化・休眠に関する研究を主に行っています。

また、フェロトーシスによる腫瘍抑制機構やp53誘導型lnc-RNAによる抗がん剤耐性のメカニズム、内分泌腫瘍を用いた機能解析・病理検体解析・初代培養による発症メカニズムの解明、ミトコンドリア超複合体解析・代謝Flux解析を用いたp53依存的エネルギー代謝制御に関する研究にも従事してきました。


現在は難治性乳がんの克服と新たな創薬標的の発掘を目指して、3次元培養条件下でのSingle Cellを含めたNGS解析やnon-target proteomicsを行い、変異p53依存的な悪性化・転移機構の分子基盤の解明を目指しています。


研究キーワード

 4

論文

 17
  • 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.
  • Azusa Yamato, Hidekazu Nagano, Yue Gao, Tatsuma Matsuda, Naoko Hashimoto, Akitoshi Nakayama, Kazuyuki Yamagata, Masataka Yokoyama, Yingbo Gong, Xiaoyan Shi, Siti Nurul Zhahara, Takashi Kono, Yuki Taki, Naoto Furuki, Motoi Nishimura, Kentaro Horiguchi, Yasuo Iwadate, Masaki Fukuyo, Bahityar Rahmutulla, Atsushi Kaneda, Yoshinori Hasegawa, Yusuke Kawashima, Osamu Ohara, Tetsuo Ishikawa, Eiryo Kawakami, Yasuhiro Nakamura, Naoko Inoshita, Shozo Yamada, Noriaki Fukuhara, Hiroshi Nishioka, Tomoaki Tanaka
    Communications biology 5(1) 1304-1304 2022年11月27日  査読有り
  • Alimasi Aersilan, Naoko Hashimoto, Kazuyuki Yamagata, Masataka Yokoyama, Akitoshi Nakayama, Xiaoyan Shi, Hidekazu Nagano, Ikki Sakuma, Nijiro Nohata, Takashi Kinoshita, Naohiko Seki, Bahityar Rahmutulla, Atsushi Kaneda, Siti Nurul Zhahara, Yingbo Gong, Motoi Nishimura, Shoichiro Kawauchi, Eiryo Kawakami, Tomoaki Tanaka
    Scientific reports 12(1) 18443-18443 2022年11月2日  査読有り
    The microRNA (miR) miR-874, a potential tumour suppressor, causes cell death via target gene suppression in various cancer types. Mevalonate pathway inhibition also causes cell death in breast cancer. However, the relationship between the mevalonate pathway and miR-874-induced apoptosis or its association with the tumour suppressor p53 has not been elucidated. We identified phosphomevalonate kinase (PMVK), a key mevalonate pathway enzyme, and sterol regulatory element-binding factor 2 (SREBF2), the master cholesterol biosynthesis regulator, as direct miR‑874 targets. Next-generation sequencing analysis revealed a significant miR-874-mediated downregulation of PMVK and SREBF2 gene expression and p53 pathway enrichment. Luciferase reporter assays showed that miR-874 directly regulated PMVK and SREBF2. miR-874-induced apoptosis was p53 dependent, and single-cell RNA sequencing analysis demonstrated that miR-874 transfection resulted in apoptosis and p53 pathway activation. Downregulation of PMVK expression also caused cell cycle arrest and p53 pathway activation, which was rescued by geranylgeranyl pyrophosphate (GGPP) supplementation. Analysis of The Cancer Genome Atlas (TCGA) database indicated a negative correlation between miR-874 and PMVK expression and between miR-874 and SREBF2 expression. These findings suggest that miR-874 suppresses the mevalonate pathway by targeting SREBF2 and PMVK, resulting in GGPP depletion, which activates the p53 pathway and promotes cycle arrest or apoptosis.
  • Masanori Fujimoto, Masataka Yokoyama, Masahiro Kiuchi, Hiroyuki Hosokawa, Akitoshi Nakayama, Naoko Hashimoto, Ikki Sakuma, Hidekazu Nagano, Kazuyuki Yamagata, Fujimi Kudo, Ichiro Manabe, Eunyoung Lee, Ryo Hatano, Atsushi Onodera, Kiyoshi Hirahara, Koutaro Yokote, Takashi Miki, Toshinori Nakayama, Tomoaki Tanaka
    Nature communications 13(1) 5408-5408 2022年9月15日  査読有り
    The liver stores glycogen and releases glucose into the blood upon increased energy demand. Group 2 innate lymphoid cells (ILC2) in adipose and pancreatic tissues are known for their involvement in glucose homeostasis, but the metabolic contribution of liver ILC2s has not been studied in detail. Here we show that liver ILC2s are directly involved in the regulation of blood glucose levels. Mechanistically, interleukin (IL)-33 treatment induces IL-13 production in liver ILC2s, while directly suppressing gluconeogenesis in a specific Hnf4a/G6pc-high primary hepatocyte cluster via Stat3. These hepatocytes significantly interact with liver ILC2s via IL-13/IL-13 receptor signaling. The results of transcriptional complex analysis and GATA3-ChIP-seq, ATAC-seq, and scRNA-seq trajectory analyses establish a positive regulatory role for the transcription factor GATA3 in IL-13 production by liver ILC2s, while AP-1 family members are shown to suppress IL-13 release. Thus, we identify a regulatory role and molecular mechanism by which liver ILC2s contribute to glucose homeostasis.
  • Sawako Suzuki, Divya Venkatesh, Hiroaki Kanda, Akitoshi Nakayama, Hiroyuki Hosokawa, Eunyoung Lee, Takashi Miki, Brent R. Stockwell, Koutaro Yokote, Tomoaki Tanaka, Carol Prives
    Cancer Research 82(18) 3209-3222 2022年7月27日  査読有り
    Abstract Glutamine synthase 2 (GLS2) is a key regulator of glutaminolysis and has been previously implicated in activities consistent with tumor suppression. Here we generated Gls2 knockout (KO) mice that develop late-occurring B-cell lymphomas and hepatocellular carcinomas (HCC). Further, Gls2 KO mice subjected to the hepatocarcinogenic Stelic Animal Model (STAM) protocol produce larger HCC tumors than seen in wild-type (WT) mice. GLS2 has been shown to promote ferroptosis, a form of cell death characterized by iron-dependent accumulation of lipid peroxides. In line with this, GLS2 deficiency, either in cells derived from Gls2 KO mice or in human cancer cells depleted of GLS2, conferred significant resistance to ferroptosis. Mechanistically, GLS2, but not GLS1, increased lipid reactive oxygen species (ROS) production by facilitating the conversion of glutamate to α-ketoglutarate (αKG), thereby promoting ferroptosis. Ectopic expression of WT GLS2 in a human hepatic adenocarcinoma xenograft model significantly reduced tumor size; this effect was nullified by either expressing a catalytically inactive form of GLS2 or by blocking ferroptosis. Furthermore, analysis of cancer patient datasets supported a role for GLS2-mediated regulation of ferroptosis in human tumor suppression. These data suggest that GLS2 is a bona fide tumor suppressor and that its ability to favor ferroptosis by regulating glutaminolysis contributes to its tumor suppressive function. Significance: This study demonstrates that the key regulator of glutaminolysis, GLS2, can limit HCC in vivo by promoting ferroptosis through αKG-dependent lipid ROS, which in turn might lay the foundation for a novel therapeutic approach.

MISC

 206

書籍等出版物

 1
  • 中山 哲俊, 鈴木佐和子, 田中知明 (担当:分担執筆, 範囲:がん細胞における特異的細胞内代謝と治療抵抗性)
    ニュー・サイエンス社 2017年5月

講演・口頭発表等

 62

共同研究・競争的資金等の研究課題

 3