基于 p53 的癌症治疗。

p53-based cancer therapy.

机构信息

p53 Laboratory (A-Star) 8A Biomedical Grove Immunos Singapore 138648.

出版信息

Cold Spring Harb Perspect Biol. 2010 Sep;2(9):a001222. doi: 10.1101/cshperspect.a001222. Epub 2010 May 12.

DOI:10.1101/cshperspect.a001222

PMID:20463003

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2926755/

Abstract

Inactivation of p53 functions is an almost universal feature of human cancer cells. This has spurred a tremendous effort to develop p53 based cancer therapies. Gene therapy using wild-type p53, delivered by adenovirus vectors, is now in widespread use in China. Other biologic approaches include the development of oncolytic viruses designed to replicate and kill only p53 defective cells and also the development of siRNA and antisense RNA's that activate p53 by inhibiting the function of the negative regulators Mdm2, MdmX, and HPV E6. The altered processing of p53 that occurs in tumor cells can elicit T-cell and B-cell responses to p53 that could be effective in eliminating cancer cells and p53 based vaccines are now in clinical trial. A number of small molecules that directly or indirectly activate the p53 response have also reached the clinic, of which the most advanced are the p53 mdm2 interaction inhibitors. Increased understanding of the p53 response is also allowing the development of powerful drug combinations that may increase the selectivity and safety of chemotherapy, by selective protection of normal cells and tissues.

摘要

p53 功能失活是人类癌细胞的一个几乎普遍的特征。这促使人们大力开发基于 p53 的癌症治疗方法。使用腺病毒载体递送野生型 p53 的基因治疗现在在中国得到广泛应用。其他生物学方法包括开发仅复制和杀死 p53 缺陷细胞的溶瘤病毒，以及开发 siRNA 和反义 RNA，通过抑制负调节剂 Mdm2、MdmX 和 HPV E6 的功能来激活 p53。肿瘤细胞中发生的 p53 改变的加工可以引发针对 p53 的 T 细胞和 B 细胞反应，这可能有效地消除癌细胞，基于 p53 的疫苗现在正在临床试验中。一些直接或间接激活 p53 反应的小分子也已进入临床，其中最先进的是 p53-mdm2 相互作用抑制剂。对 p53 反应的理解的增加也允许开发强大的药物组合，通过选择性保护正常细胞和组织，可能增加化疗的选择性和安全性。

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