Baranyai Zsolt, Reich Dominik, Vágner Adrienn, Weineisen Martina, Tóth Imre, Wester Hans-Jürgen, Notni Johannes
Department of Inorganic and Analytical Chemistry, University of Debrecen, Egyetem tér 1, Debrecen, H-4032, Hungary.
Dalton Trans. 2015 Jun 28;44(24):11137-46. doi: 10.1039/c5dt00576k. Epub 2015 May 22.
Due to its 3 carbonic acid groups being available for bioconjugation, the TRAP chelator (1,4,7-triazacyclononane-1,4,7-tris(methylene(2-carboxyethylphosphinic acid))) is chosen for the synthesis of trimeric bioconjugates for radiolabelling. We optimized a protocol for bio-orthogonal TRAP conjugation via Cu(I)-catalyzed Huisgen-cycloaddition of terminal azides and alkynes (CuAAC), including a detailed investigation of kinetic properties of Cu(II)-TRAP complexes. TRAP building blocks for CuAAC, TRAP(alkyne)3 and TRAP(azide)3 were obtained by amide coupling of propargylamine/3-azidopropyl-1-amine, respectively. For Cu(II) complexes of neat and triply amide-functionalized TRAP, the equilibrium properties as well as pseudo-first-order Cu(II)-transchelation, using 10 to 30 eq. of NOTA and EDTA, were studied by UV-spectrophotometry. Dissociation of any Cu(II)-TRAP species was found to be independent on the nature or excess of a competing chelator, confirming a proton-driven two-step mechanism. The respective thermodynamic stability constants (log K(ML): 19.1 and 17.6) and dissociation rates (k: 38 × 10(-6) and 7 × 10(-6) s(-1), 298 K, pH 4) show that the Cu(II) complex of the TRAP-conjugate possesses lower thermodynamic stability but higher kinetic inertness. At pH 2-3, its demetallation with NOTA was complete within several hours/days at room temperature, respectively, enabling facile Cu(II) removal after click coupling by direct addition of NOTA trihydrochloride to the CuAAC reaction mixture. Notwithstanding this, an extrapolated dissociation half life of >100 h at 37 °C and pH 7 confirms the suitability of TRAP-bioconjugates for application in Cu-64 PET (cf. t(1/2)(Cu-64) = 12.7 h). To showcase advantages of the method, TRAP(DUPA-Pep)3, a trimer of the PSMA inhibitor DUPA-Pep, was synthesized using 1 eq. TRAP(alkyne)3, 3.3 eq. DUPA-Pep-azide, 10 eq. Na ascorbate, and 1.2 eq. Cu(II)-acetate. Its PSMA affinity (IC50), determined by the competition assay on LNCaP cells, was 18-times higher than that of the corresponding DOTAGA monomer (IC50: 2 ± 0.1 vs. 36 ± 4 nM), resulting in markedly improved contrast in Ga-68-PET imaging. In conclusion, the kinetic inertness profile of Cu(II)-TRAP conjugates allows for simple Cu(II) removal after click functionalisation by means of transchelation, but also confirms their suitability for Cu-64-PET as demonstrated previously (Dalton Trans., 2012, 41, 13803).
由于其三碳酸基团可用于生物共轭,因此选择TRAP螯合剂(1,4,7-三氮杂环壬烷-1,4,7-三(亚甲基(2-羧乙基次膦酸)))来合成用于放射性标记的三聚体生物共轭物。我们通过末端叠氮化物和炔烃的铜(I)催化的惠斯根环加成反应(CuAAC)优化了生物正交TRAP共轭的方案,包括对铜(II)-TRAP配合物动力学性质的详细研究。通过炔丙胺/3-叠氮基丙基-1-胺的酰胺偶联分别获得用于CuAAC的TRAP构建块TRAP(炔烃)3和TRAP(叠氮化物)3。对于纯的和三重酰胺官能化的TRAP的铜(II)配合物,使用10至30当量的NOTA和EDTA,通过紫外分光光度法研究了平衡性质以及准一级铜(II)-转螯合作用。发现任何铜(II)-TRAP物种的解离都与竞争螯合剂的性质或过量无关,证实了质子驱动的两步机制。各自的热力学稳定性常数(log K(ML):19.1和17.6)和解离速率(k:38×10(-6)和7×10(-6)s(-1),298 K,pH 4)表明TRAP共轭物的铜(II)配合物具有较低的热力学稳定性但较高的动力学惰性。在pH 2-3时,其与NOTA的脱金属反应在室温下分别在数小时/天内完成,通过将三盐酸NOTA直接添加到CuAAC反应混合物中,点击偶联后能够轻松去除铜(II)。尽管如此,在37°C和pH 7下推断的解离半衰期>100小时,证实了TRAP生物共轭物适用于Cu-64 PET(参见t(1/2)(Cu-64)= 12.7小时)。为了展示该方法的优势,使用1当量的TRAP(炔烃)3、3.3当量的DUPA-Pep-叠氮化物、10当量的抗坏血酸钠和1.2当量的醋酸铜(II)合成了PSMA抑制剂DUPA-Pep的三聚体TRAP(DUPA-Pep)3。通过对LNCaP细胞的竞争试验测定,其PSMA亲和力(IC50)比相应的DOTAGA单体高18倍(IC50:2±0.1对36±4 nM),从而在Ga-68-PET成像中显著提高了对比度。总之,铜(II)-TRAP共轭物的动力学惰性特征使得点击功能化后通过转螯合作用简单去除铜(II)成为可能,同时也证实了它们适用于Cu-64-PET,如先前所示(《道尔顿汇刊》,2012年,41卷,13803页)。
