基于结构的 Mdm2/Mdmx-p53 抑制剂的设计变得越来越重要。
The structure-based design of Mdm2/Mdmx-p53 inhibitors gets serious.
机构信息
Max Planck Institute for Biochemistry, Martinsried, Germany.
出版信息
Angew Chem Int Ed Engl. 2011 Mar 14;50(12):2680-8. doi: 10.1002/anie.201003863. Epub 2011 Feb 21.
Abstract
The p53 protein is the cell's principal bastion of defense against tumor-associated DNA damage. Commonly referred as a "guardian of the genome", p53 is responsible for determining the fate of the cell when the integrity of its genome is damaged. The development of tumors requires breaching this defense line. All known tumor cells either mutate the p53 gene, or in a similar number of cases, use internal cell p53 modulators, Mdm2 and Mdmx proteins, to disable its function. The release of functional p53 from the inhibition by Mdm2 and Mdmx should in principle provide an efficient, nongenotoxic means of cancer therapy. In recent years substantial progress has been made in developing novel p53-activating molecules thanks to several reported crystal structures of Mdm2/x in complex with p53-mimicking peptides and nonpeptidic drug candidates. Understanding the structural attributes of ligand binding holds the key to developing novel, highly effective, and selective drug candidates. Two low-molecular-weight compounds have just recently progressed into early clinical studies.
摘要
p53 蛋白是细胞抵抗肿瘤相关 DNA 损伤的主要防御机制。通常被称为“基因组的守护者”,p53 负责在基因组完整性受到损伤时决定细胞的命运。肿瘤的发展需要突破这道防线。所有已知的肿瘤细胞要么突变 p53 基因,要么在大量情况下,利用细胞内的 p53 调节剂 Mdm2 和 Mdmx 蛋白使其功能失活。从 Mdm2 和 Mdmx 的抑制中释放出功能性 p53,原则上可以为癌症治疗提供一种有效的非遗传毒性手段。近年来,由于报道了 Mdm2/x 与 p53 模拟肽和非肽类药物候选物复合物的几个晶体结构,在开发新型 p53 激活分子方面取得了重大进展。了解配体结合的结构属性是开发新型、高效和选择性药物候选物的关键。最近有两种低分子量化合物刚刚进入早期临床研究。
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