Department of Pathology, Beth Israel Deaconess Medical Center, Harvard Medical School, Boston, MA, USA.
Department of Biochemistry and Molecular Biology, Research Center of Laboratory Medicine, School of Laboratory Medicine, Bengbu Medical College, Anhui, 233030, China.
Semin Cancer Biol. 2020 Dec;67(Pt 2):171-179. doi: 10.1016/j.semcancer.2020.02.006. Epub 2020 Feb 11.
Chemotherapeutic strategy has been widely used for treating malignance by targeting irregular expressed or mutant proteins with small molecular inhibitors (SMIs) or monoclonal antibodies (mAbs). However, most intracellular proteins lack of active sites or antigens where SMIs or mAbs bind with, and are called as non-druggable targets for a long time. From the first year of this century, PROteolysis-TArgeting Chimeras (PROTACs) has emerged to be a promising approach for proteins, including those non-druggable ones, such as transcriptional factors and scaffold proteins. The first generation of peptide-based PROTACs adopts β-TrCP and VHL as E3 ligases, but the cellular permeability and chemical stability issues restrict their clinical application. The second generation of small molecule-based PROTACs adopts MDM2, VHL, IAPs and Cereblon as E3 ligases have been tensely studied. To date, the targets of PROTACs including those overexpressed oncogenic proteins such as ER, AR and BRDs, disease-relevant fusion proteins such as NPM/EML4-ALK and BCR-ABL, cancer-driven mutant proteins such as EGFR, kinases such as CDKs and RTKs. The major disadvantage of PROTACs is the noncancer specificity and relative higher toxicity, due to its catalytic role. To overcome this, we and other have recently developed several similar light-controllable PROTACs, termed as the third generation controllable PROTACs. The degradation of targets by those PROTACs can be triggered by UVA or visible light, providing a tool box for further PROTACs design. Here in this review, we introduce the historical milestones and prospective for further PROTACs development in clinical use.
化疗策略已广泛用于通过小分子抑制剂 (SMIs) 或单克隆抗体 (mAbs) 靶向异常表达或突变蛋白来治疗恶性肿瘤。然而,大多数细胞内蛋白缺乏 SMIs 或 mAbs 结合的活性位点或抗原,长期以来被称为不可成药靶点。从本世纪初开始,PROteolysis-TArgeting Chimeras (PROTACs) 已成为一种有前途的蛋白质靶向方法,包括那些不可成药的蛋白质,如转录因子和支架蛋白。基于肽的第一代 PROTACs 采用β-TrCP 和 VHL 作为 E3 连接酶,但细胞通透性和化学稳定性问题限制了它们的临床应用。基于小分子的第二代 PROTACs 采用 MDM2、VHL、IAPs 和 Cereblon 作为 E3 连接酶已受到广泛研究。迄今为止,PROTACs 的靶点包括过度表达的致癌蛋白,如 ER、AR 和 BRDs,与疾病相关的融合蛋白,如 NPM/EML4-ALK 和 BCR-ABL,以及驱动癌症的突变蛋白,如 EGFR、激酶,如 CDKs 和 RTKs。PROTACs 的主要缺点是由于其催化作用,非癌症特异性和相对较高的毒性。为了克服这一问题,我们和其他研究人员最近开发了几种类似的光控 PROTACs,称为第三代可控 PROTACs。通过这些 PROTACs 降解靶标可以被 UVA 或可见光触发,为进一步的 PROTACs 设计提供了工具包。在这篇综述中,我们介绍了在临床应用中进一步开发 PROTACs 的历史里程碑和前景。
