Hashimoto Hiroki, Kawamura Kazunori, Takei Makoto, Igarashi Nobuyuki, Fujishiro Tomoya, Shiomi Satoshi, Watanabe Ryuji, Muto Masatoshi, Furutsuka Kenji, Ito Takehito, Yamasaki Tomoteru, Yui Joji, Nemoto Kazuyoshi, Kimura Yasuyuki, Higuchi Makoto, Zhang Ming-Rong
Molecular Imaging Center, National Institute of Radiological Sciences, Chiba, Japan.
Molecular Imaging Center, National Institute of Radiological Sciences, Chiba, Japan.
Nucl Med Biol. 2015 Dec;42(12):905-10. doi: 10.1016/j.nucmedbio.2015.08.006. Epub 2015 Sep 2.
[(11)C]PBB3 is a clinically used positron emission tomography (PET) probe for in vivo imaging of tau pathology in the brain. Our previous study showed that [(11)C]PBB3 was rapidly decomposed to a polar radiometabolite in the plasma of mice. For the pharmacokinetic evaluation of [(11)C]PBB3 it is important to elucidate the characteristics of radiometabolites. In this study, we identified the chemical structure of a major radiometabolite of [(11)C]PBB3 and proposed the metabolic pathway of [(11)C]PBB3.
Carrier-added [(11)C]PBB3 was injected into a mouse for in vivo metabolite analysis. The chemical structure of a major radiometabolite was identified using LC-MS. Mouse and human liver microsomes and liver S9 samples were incubated with [(11)C]PBB3 in vitro. In silico prediction software was used to assist in the determination of the metabolite and metabolic pathway of [(11)C]PBB3.
In vivo analysis showed that the molecular weight of a major radiometabolite of [(11)C]PBB3, which was called as [(11)C]M2, was m/z 390 [M+H(+)]. In vitro analysis assisted by in silico prediction showed that [(11)C]M2, which was not generated by cytochrome P450 enzymes (CYPs), was generated by sulfated conjugation mediated by a sulfotransferase.
The major radiometabolite, [(11)C]M2, was identified as a sulfated conjugate of [(11)C]PBB3. [(11)C]PBB3 was metabolized mainly by a sulfotransferase and subsidiarily by CYPs.
[(11)C]PBB3是一种临床使用的正电子发射断层扫描(PET)探针,用于大脑中tau蛋白病理学的体内成像。我们之前的研究表明,[(11)C]PBB3在小鼠血浆中迅速分解为一种极性放射性代谢物。对于[(11)C]PBB3的药代动力学评估,阐明放射性代谢物的特征很重要。在本研究中,我们确定了[(11)C]PBB3主要放射性代谢物的化学结构,并提出了[(11)C]PBB3的代谢途径。
将添加载体的[(11)C]PBB3注射到小鼠体内进行体内代谢物分析。使用液相色谱-质谱联用(LC-MS)鉴定主要放射性代谢物的化学结构。将小鼠和人肝微粒体以及肝S9样品与[(11)C]PBB3在体外孵育。使用计算机预测软件辅助确定[(11)C]PBB3的代谢物和代谢途径。
体内分析表明,[(11)C]PBB3的主要放射性代谢物,称为[(11)C]M2,分子量为m/z 390 [M+H(+)]。计算机预测辅助的体外分析表明,[(11)C]M2不是由细胞色素P450酶(CYPs)产生的,而是由硫酸转移酶介导的硫酸化结合产生的。
主要放射性代谢物[(11)C]M2被鉴定为[(11)C]PBB3的硫酸化结合物。[(11)C]PBB3主要通过硫酸转移酶代谢,其次通过CYPs代谢。
