Kaneko Kei, Ohkawa Yuki, Hashimoto Noboru, Ohmi Yuhsuke, Kotani Norihiro, Honke Koichi, Ogawa Mitsutaka, Okajima Tetsuya, Furukawa Keiko, Furukawa Koichi
From the Department of Biochemistry II, Nagoya University Graduate School of Medicine, Nagoya 466-0065.
Department of Life Biomedical Sciences, Chubu University College of Life and Health Sciences, Kasuigai, Aichi 487-8501.
J Biol Chem. 2016 Aug 5;291(32):16630-43. doi: 10.1074/jbc.M115.708834. Epub 2016 Jun 10.
To investigate mechanisms for increased malignant properties in malignant melanomas by ganglioside GD3, enzyme-mediated activation of radical sources and subsequent mass spectrometry were performed using an anti-GD3 antibody and GD3-positive (GD3+) and GD3-negative (GD3-) melanoma cell lines. Neogenin, defined as a GD3-neighbored molecule, was largely localized in lipid/rafts in GD3+ cells. Silencing of neogenin resulted in the reduction of cell growth and invasion activity. Physical association between GD3 and neogenin was demonstrated by immunoblotting of the immunoprecipitates with anti-neogenin antibody from GD3+ cell lysates. The intracytoplasmic domain of neogenin (Ne-ICD) was detected in GD3+ cells at higher levels than in GD3- cells when cells were treated by a proteasome inhibitor but not when simultaneously treated with a γ-secretase inhibitor. Exogenous GD3 also induced increased Ne-ICD in GD3- cells. Overexpression of Ne-ICD in GD3- cells resulted in the increased cell growth and invasion activity, suggesting that Ne-ICD plays a role as a transcriptional factor to drive malignant properties of melanomas after cleavage with γ-secretase. γ-Secretase was found in lipid/rafts in GD3+ cells. Accordingly, immunocyto-staining revealed that GD3, neogenin, and γ-secretase were co-localized at the leading edge of GD3+ cells. All these results suggested that GD3 recruits γ-secretase to lipid/rafts, allowing efficient cleavage of neogenin. ChIP-sequencing was performed to identify candidates of target genes of Ne-ICD. Some of them actually showed increased expression after expression of Ne-ICD, probably exerting malignant phenotypes of melanomas under GD3 expression.
为了研究神经节苷脂GD3增加恶性黑色素瘤恶性特性的机制,我们使用抗GD3抗体以及GD3阳性(GD3+)和GD3阴性(GD3-)黑色素瘤细胞系进行了酶介导的自由基源激活及随后的质谱分析。新生蛋白被定义为与GD3相邻的分子,在GD3+细胞中主要定位于脂筏。新生蛋白的沉默导致细胞生长和侵袭活性降低。通过用来自GD3+细胞裂解物的抗新生蛋白抗体对免疫沉淀物进行免疫印迹,证实了GD3与新生蛋白之间存在物理关联。当用蛋白酶体抑制剂处理细胞时,在GD3+细胞中检测到的新生蛋白胞质内结构域(Ne-ICD)水平高于GD3-细胞,但同时用γ-分泌酶抑制剂处理时则未检测到。外源性GD3也可诱导GD3-细胞中Ne-ICD增加。在GD3-细胞中过表达Ne-ICD导致细胞生长和侵袭活性增加,这表明Ne-ICD在被γ-分泌酶切割后作为转录因子发挥作用,驱动黑色素瘤的恶性特性。在GD3+细胞的脂筏中发现了γ-分泌酶。因此,免疫细胞化学染色显示GD3、新生蛋白和γ-分泌酶共定位于GD3+细胞的前缘。所有这些结果表明,GD3将γ-分泌酶募集到脂筏,从而使新生蛋白能够有效切割。进行了染色质免疫沉淀测序(ChIP-sequencing)以鉴定Ne-ICD的靶基因候选物。其中一些在Ne-ICD表达后实际上显示出表达增加,可能在GD3表达下发挥黑色素瘤的恶性表型。