Department of Chemistry, Organic and Bioorganic Chemistry, Bielefeld University, Universitätsstraße 25, 33615, Bielefeld, Germany.
Department of Chemistry, Physical Chemistry, Bielefeld University, Universitätsstraße 25, 33615, Bielefeld, Germany.
Chemistry. 2020 Dec 9;26(69):16357-16364. doi: 10.1002/chem.202002454. Epub 2020 Oct 29.
Mild reaction conditions are highly desirable for bio-orthogonal side chain derivatizations of amino acids, peptides or proteins due to the sensitivity of these substrates. Transition metal catalysed cross-couplings such as Suzuki-Miyaura reactions are highly versatile, but usually require unfavourable reaction conditions, in particular, when applied with aryl bromides. Ligand-free solvent-stabilised Pd-nanoparticles represent an efficient and sustainable alternative to conventional phosphine-based catalysts, because the cross-coupling can be performed at considerably lower temperature. We report on the application of such a highly reactive heterogeneous catalyst for the Suzuki-Miyaura cross-coupling of brominated tryptophan derivatives. The solvent-stabilised Pd-nanoparticles are even more efficient than the literature-known ADHP-Pd precatalyst. Interestingly, the latter also leads to the formation of quasi-homogeneous Pd-nanoparticles as the catalytic species. One advantage of our approach is the compatibility with aqueous and aerobic conditions at near-ambient temperatures and short reaction times of only 2 h. The influence of different N -protecting groups, boronic acids as well as the impact of different amino acid side chains in bromotryptophan-containing peptides has been studied. Notably, a surprising acceleration of the catalysis was observed when palladium-coordinating side chains were present in proximal positions.
由于这些底物的敏感性,生物正交侧链衍生化氨基酸、肽或蛋白质非常需要温和的反应条件。过渡金属催化的交叉偶联反应,如 Suzuki-Miyaura 反应,具有很高的通用性,但通常需要不利的反应条件,特别是在与芳基溴化物应用时。无配体的溶剂稳定化 Pd 纳米粒子是传统膦基催化剂的有效且可持续的替代方案,因为可以在低得多的温度下进行交叉偶联。我们报告了这种高反应性的多相催化剂在溴代色氨酸衍生物的 Suzuki-Miyaura 交叉偶联中的应用。溶剂稳定化 Pd 纳米粒子比文献中已知的 ADHP-Pd 前催化剂更有效。有趣的是,后者也导致准均相 Pd 纳米粒子作为催化物种的形成。我们方法的一个优点是与近环境温度下的水相和需氧条件以及仅 2 小时的短反应时间兼容。已经研究了不同 N-保护基、硼酸以及在含有溴色氨酸的肽中的不同氨基酸侧链的影响。值得注意的是,当钯配位侧链处于邻近位置时,观察到催化的惊人加速。