Raboisson Pierre, Manthey Carl L, Chaikin Margery, Lattanze Jennifer, Crysler Carl, Leonard Kristi, Pan Wenxi, Tomczuk Bruce E, Marugán Juan José
Department of Medicinal Chemistry, Johnson & Johnson Pharmaceutical Research and Development, LLC, Exton, PA 19341, USA.
Eur J Med Chem. 2006 Jul;41(7):847-61. doi: 10.1016/j.ejmech.2006.03.008. Epub 2006 May 11.
The binding of lead compounds and drugs to human serum albumin (HSA) is a ubiquitous problem in drug discovery since it modulates the availability of the leads and drugs to their intended target, which is linked to biological efficacy. In our continuing efforts to identify small molecule alpha(V)beta(3) and alpha(V)beta(5) dual antagonists, we recently reported indoles 2-4 as potent and selective alpha(V)beta(3)/alpha(V)beta(5) antagonists with good oral bioavailability profile. In spite of subnanomolar binding affinity of these compounds to human alpha(V)beta(3) and alpha(V)beta(5) integrins, high HSA binding (96.5-97.3%) emerged as a limiting feature for these leads. Structure-activity HSA binding data of organic acids reported in the literature have demonstrated that the incorporation of polar groups into a given molecule can dramatically decrease the affinity toward HSA. We sought to apply this strategy by examining the effects of such modifications in both the central core constrain and the substituent beta to the carboxylate. Most of these derivatives were prepared in good yields through a cesium fluoride-catalyzed coupling reaction. This reaction was successful with a variety of nitrogen-containing scaffolds (20, 33, and 43) and selected acetylenic derivatives (16, 19, and 34). Among the compounds synthesized, the 3-[5-[2-(5,6,7,8-tetrahydro [1,8]naphthyridin-2-yl)ethoxy]indol-1-yl]-3-[5-(N,N-dimethylaminomethyl)-3-pyridyl]propionic acid (25) was found to be the most promising derivative within this novel series with a subnanomolar affinity for both alpha(v)beta(3) and alpha(v)beta(5) (IC(50) = 0.29 and 0.16 nM, respectively), similar to our initial lead receptor antagonists 2-4, and exhibiting a low HSA protein binding (40% bound, K(d) = 1.1+/-0.4 x 10(3) microM) and an improved in vitro stability profile toward human and mouse microsomes (99.9% and 98.7% remaining after 10 min). Moreover, the selectivity of 25 toward alpha(5)beta(1) and IIbIIIa integrins was perfectly maintained when compared to the parent leads 2-4. Thus, compound 25 was selected as a new lead with improved drug-like properties for further evaluations in the field of oncology and osteoporosis.
铅化合物和药物与人血清白蛋白(HSA)的结合是药物研发中普遍存在的问题,因为它会调节先导化合物和药物到达其预期靶点的可用性,而这与生物疗效相关。在我们持续努力鉴定小分子α(V)β(3)和α(V)β(5)双重拮抗剂的过程中,我们最近报道了吲哚2 - 4作为具有良好口服生物利用度的强效且选择性的α(V)β(3)/α(V)β(5)拮抗剂。尽管这些化合物对人α(V)β(3)和α(V)β(5)整合素具有亚纳摩尔级的结合亲和力,但高HSA结合率(96.5 - 97.3%)成为了这些先导化合物的一个限制因素。文献中报道的有机酸的构效HSA结合数据表明,在给定分子中引入极性基团可显著降低对HSA的亲和力。我们试图通过研究在中心核心结构和羧酸根基团β位取代基上进行此类修饰的效果来应用这一策略。这些衍生物大多通过氟化铯催化的偶联反应以良好的产率制备。该反应对多种含氮骨架(20、33和43)以及选定的炔烃衍生物(16、19和34)均成功。在合成的化合物中,3 - [5 - [2 - (5,6,7,8 - 四氢[1,8]萘啶 - 2 - 基)乙氧基]吲哚 - 1 - 基] - 3 - [5 - (N,N - 二甲基氨基甲基) - 3 - 吡啶基]丙酸(25)被发现是这个新系列中最有前景的衍生物,对α(v)β(3)和α(v)β(5)均具有亚纳摩尔级亲和力(IC(50)分别为0.29和0.16 nM),与我们最初的先导受体拮抗剂2 - 4相似,并且显示出低HSA蛋白结合率(40%结合,K(d)=1.1±0.4×10(3) microM)以及对人和小鼠微粒体具有改善的体外稳定性(10分钟后分别剩余99.9%和98.7%)。此外,与母体先导化合物2 - 4相比,25对α(5)β(1)和IIbIIIa整合素的选择性得以完美保持。因此,化合物25被选为具有改善的类药性质的新先导化合物,用于肿瘤学和骨质疏松领域的进一步评估。
