Chatterjee Jayanta, Gilon Chaim, Hoffman Amnon, Kessler Horst
Center for Integrated Protein Science, Department Chemie, Technische Universitat Munchen, Lichtenbergstrasse 4, Garching 85747, Germany.
Acc Chem Res. 2008 Oct;41(10):1331-42. doi: 10.1021/ar8000603. Epub 2008 Jul 18.
The potential of peptides as drug candidates is limited by their poor pharmacokinetic properties. Many peptides have a short half-life in vivo and a lack of oral availability. Inspired by the excellent pharmacokinetic profile of cyclosporine, a natural, multiply N-methylated cyclic peptide, we envisioned multiple N-methylation as a promising way to rationally improve key pharmacokinetic characteristics. In this Account, we summarize our efforts toward modulating the properties of peptides by multiple N-methylation. As a first step, we simplified the synthesis of N-methylated amino acids in solution, by employing very mild conditions that could be tolerated by the diverse protecting groups required when working with naturally occurring amino acids. We also report the rapid and inexpensive syntheses of N-methylated peptides on a solid support; this facilitated the N-methyl scanning of bioactive peptides. Because of a lack of information regarding the conformational behavior of multiply N-methylated peptides, a complete library of N-methylated cyclic alanine pentapeptides was synthesized. The library provided valuable insight into the conformational modulation of cyclic peptides by N-methylation. This information is extremely valuable for the design of bioactive peptides and spatial screening of cyclic N-methylated peptides. To demonstrate the applicability of N-methylation to highly active but poorly bioavailable peptides, we performed a full N-methyl scan of the cyclopeptidic somatostatin analog cyclo(-PFwKTF-), known as the Veber-Hirschmann peptide. We show here for the first time that the simple approach of multiple N-methylation can drastically improve the metabolic stability and intestinal permeability of peptides, for example, resulting in 10% oral bioavailability for a tri-N-methylated Veber-Hirschmann peptide analog. In addition, we also describe a designed approach to N-methylated peptide library synthesis, which can accelerate the screening of N-methylated bioactive peptides. Finally, we find that multiple N-methylation of a cyclic hexapeptide integrin antagonist of GPIIb-IIIa (alphaIIb beta3 integrin), cyclo(-GRGDfL-), increases the selectivity of this peptide toward different integrin subtypes. This result demonstrates the utility of multiple N-methylation in elucidating the bioactive conformation of peptides.
肽作为药物候选物的潜力受到其不良药代动力学性质的限制。许多肽在体内半衰期短且缺乏口服可用性。受天然的、多重N-甲基化环肽环孢素优异药代动力学特征的启发,我们设想多重N-甲基化是合理改善关键药代动力学特性的一种有前景的方法。在本综述中,我们总结了我们通过多重N-甲基化调节肽性质的工作。作为第一步,我们通过采用非常温和的条件简化了溶液中N-甲基化氨基酸的合成,这些条件能够被处理天然氨基酸时所需的多种保护基团所耐受。我们还报道了在固相载体上快速且廉价地合成N-甲基化肽;这促进了生物活性肽的N-甲基扫描。由于缺乏关于多重N-甲基化肽构象行为的信息,我们合成了一个完整的N-甲基化环丙氨酸五肽文库。该文库为通过N-甲基化对环肽进行构象调节提供了有价值的见解。这些信息对于生物活性肽的设计和环N-甲基化肽的空间筛选极其有价值。为了证明N-甲基化对高活性但生物利用度差的肽的适用性,我们对环肽生长抑素类似物环(-PFwKTF-),即所谓的维伯-赫希曼肽,进行了全N-甲基扫描。我们在此首次表明,多重N-甲基化的简单方法可以显著提高肽的代谢稳定性和肠道通透性,例如,一种三-N-甲基化的维伯-赫希曼肽类似物的口服生物利用度达到10%。此外,我们还描述了一种设计的N-甲基化肽文库合成方法,该方法可以加速对N-甲基化生物活性肽的筛选。最后,我们发现GPIIb-IIIa(αIIbβ3整合素)的环六肽整合素拮抗剂环(-GRGDfL-)的多重N-甲基化增加了该肽对不同整合素亚型的选择性。这一结果证明了多重N-甲基化在阐明肽的生物活性构象方面的实用性。
