Low C M, Black J W, Broughton H B, Buck I M, Davies J M, Dunstone D J, Hull R A, Kalindjian S B, McDonald I M, Pether M J, Shankley N P, Steel K I
James Black Foundation, 68 Half Moon Lane, London SE24 9JE, U.K.
J Med Chem. 2000 Sep 21;43(19):3505-17. doi: 10.1021/jm000937a.
The two hormones cholecystokinin and gastrin share the same C-terminal sequence of amino acids, namely Gly(29)-Trp(30)-Met(31)-Asp(32)-Phe(33)-NH(2). Nevertheless, this congruence has not precluded using this structure to develop selective ligands for either CCK(1) or CCK(2) receptors. Manipulation of the hydrophobic residues at positions 31 and 33 gave a series of CCK(1) tripeptide antagonists, typified by N-t-BOC-Trp-2-Nal-Asp-2-(phenyl)ethylamide (pK(B) 6.8 +/- 0.3). Molecular modeling was used to identify the bioactive conformation of these CCK(1)-selective compounds and prompted the design of new peptoid structures. We aimed to maintain the conformation of the parent series by exploiting patterns of hydrogen-bonding and pi-stacking interactions present in the original molecule, rather than introducing additional covalent bonds. The prototype, N-(succinyl-D-Asp-2-phenylethylamido)-L-Trp-2-(2-naphthyl)ethylami de, was a potent and selective CCK(1) antagonist (pK(B) 7.2 +/- 0.3). Furthermore, the new series showed patterns of biological activity that mirrored those of the parent tripeptides. These compounds contain elements of both peptide primary and secondary structure and represent a novel approach to designing peptidomimetics. Interesting results were obtained from comparing models of a representative tripeptide CCK(1) antagonist with a conformation of CCK(30)(-)(33) that others have proposed to be responsible for its activity at the CCK(2) receptor. The results suggest that CCK(1) and CCK(2) receptors recognize enatiomeric dispositions of the Trp(30) indole, Asp(32) carboxylic acid, and C-terminal phenyl groups arrayed about a common backbone configuration. This "functional chirality" may underpin the mechanism by which these closely related receptor systems bind CCK(30)(-)(33) and explain patterns of selectivity observed with optical isomers of a number of peptoid and nonpeptide ligands.
胆囊收缩素和胃泌素这两种激素具有相同的C末端氨基酸序列,即甘氨酸(29)-色氨酸(30)-甲硫氨酸(31)-天冬氨酸(32)-苯丙氨酸(33)-NH₂。然而,这种一致性并不妨碍利用该结构开发针对CCK(1)或CCK(2)受体的选择性配体。对第31位和第33位的疏水残基进行操作得到了一系列CCK(1)三肽拮抗剂,以N-t-BOC-色氨酸-2-萘丙氨酸-天冬氨酸-2-(苯基)乙酰胺(pK(B) 6.8 ± 0.3)为代表。分子建模用于确定这些CCK(1)选择性化合物的生物活性构象,并促使设计新的类肽结构。我们旨在通过利用原始分子中存在的氢键和π-堆积相互作用模式来维持母体系列的构象,而不是引入额外的共价键。原型N-(琥珀酰-D-天冬氨酸-2-苯乙酰胺基)-L-色氨酸-2-(2-萘基)乙酰胺是一种强效且选择性的CCK(1)拮抗剂(pK(B) 7.2 ± 0.3)。此外,新系列显示出与母体三肽相似的生物活性模式。这些化合物包含肽一级和二级结构的元素,代表了一种设计拟肽的新方法。通过将代表性三肽CCK(1)拮抗剂的模型与其他人提出的CCK(30)(-)(33)的一种构象进行比较,获得了有趣的结果,该构象被认为是其在CCK(2)受体上发挥活性的原因。结果表明,CCK(1)和CCK(2)受体识别围绕共同主链构型排列的色氨酸(30)吲哚、天冬氨酸(32)羧酸和C末端苯基的对映体排列。这种“功能手性”可能是这些密切相关的受体系统结合CCK(30)(-)(33)的机制基础,并解释了在许多类肽和非肽配体的光学异构体中观察到的选择性模式。
