Fukami Maki, Wada Yuka, Okada Michiyo, Kato Fumiko, Katsumata Noriyuki, Baba Takashi, Morohashi Ken-ichirou, Laporte Jocelyn, Kitagawa Motoo, Ogata Tsutomu
Department of Endocrinology and Metabolism, National Research Institute for Child Health and Development, Tokyo 157-8535, Japan.
J Biol Chem. 2008 Feb 29;283(9):5525-32. doi: 10.1074/jbc.M703289200. Epub 2007 Dec 27.
Although chromosome X open reading frame 6 (CXorf6) has been shown to be a causative gene for hypospadias, its molecular function remains unknown. To clarify this, we first examined CXorf6 protein structure, identifying homology to mastermind-like 2 (MAML2) protein, which functions as a co-activator in canonical Notch signaling. Transactivation analysis for wild-type CXorf6 protein by luciferase assays showed that CXorf6 significantly transactivated the promoter of a noncanonical Notch target gene hairy/enhancer of split 3 (Hes3) without demonstrable DNA-binding capacity. Transactivation analysis was also performed for the previously described three apparently pathologic nonsense mutations, indicating that E124X and Q197X proteins had no transactivation function, whereas R653X protein retained a nearly normal transactivation function. Subcellular localization analysis revealed that wild-type and R653X proteins co-localized with MAML2 protein in nuclear bodies, whereas E124X and Q197X proteins were incapable of localizing to nuclear bodies. Thus, further studies were performed for R653X, revealing the occurrence of nonsense mediated mRNA decay in vivo. Next, transient knockdown of CXorf6 was performed using small interfering RNA, showing reduced testosterone production in mouse Leydig tumor cells. Furthermore, steroidogenic factor 1 (SF1) protein bound to a specific sequence in the upstream of the CXorf6 coding region and exerted a transactivation activity. These results suggest that CXorf6 transactivates the Hes3 promoter, augments testosterone production, and contains the SF1 target sequence, thereby providing the first clue to clarify the biological role of CXorf6. We designate CXorf6 as MAMLD1 (mastermind-like domain-containing 1) based on its characteristic structure.
尽管X染色体开放阅读框6(CXorf6)已被证明是尿道下裂的致病基因,但其分子功能仍不清楚。为了阐明这一点,我们首先研究了CXorf6蛋白结构,发现其与主调控分子样2(MAML2)蛋白具有同源性,后者在经典Notch信号通路中作为共激活因子发挥作用。通过荧光素酶检测对野生型CXorf6蛋白进行的反式激活分析表明,CXorf6能显著反式激活非经典Notch靶基因毛状分裂增强子3(Hes3)的启动子,且无明显的DNA结合能力。我们还对先前描述的三个明显的病理性无义突变进行了反式激活分析,结果表明E124X和Q197X蛋白没有反式激活功能,而R653X蛋白保留了近乎正常的反式激活功能。亚细胞定位分析显示,野生型和R653X蛋白与MAML2蛋白在核小体中共定位,而E124X和Q197X蛋白无法定位到核小体。因此,我们对R653X进行了进一步研究,发现其在体内发生了无义介导的mRNA降解。接下来,我们使用小干扰RNA对CXorf6进行瞬时敲低,结果显示小鼠睾丸间质细胞瘤细胞中的睾酮生成减少。此外,类固醇生成因子1(SF1)蛋白与CXorf6编码区上游的特定序列结合并发挥反式激活活性。这些结果表明,CXorf6能反式激活Hes3启动子,增加睾酮生成,并含有SF1靶序列,从而为阐明CXorf6的生物学作用提供了第一条线索。基于其特征结构,我们将CXorf6命名为MAMLD1(含主调控分子样结构域1)。
