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寻找错误地方的药物:GCPII 抑制剂在大脑外的应用。

Looking for Drugs in All the Wrong Places: Use of GCPII Inhibitors Outside the Brain.

机构信息

Johns Hopkins Drug Discovery, Johns Hopkins School of Medicine, Baltimore, MD, 21205, USA.

Department of Neurology, Johns Hopkins School of Medicine, Baltimore, MD, 21205, USA.

出版信息

Neurochem Res. 2020 Jun;45(6):1256-1267. doi: 10.1007/s11064-019-02909-y. Epub 2019 Nov 20.

Abstract

In tribute to our friend and colleague Michael Robinson, we review his involvement in the identification, characterization and localization of the metallopeptidase glutamate carboxypeptidase II (GCPII), originally called NAALADase. While Mike was characterizing NAALADase in the brain, the protein was independently identified by other laboratories in human prostate where it was termed prostate specific membrane antigen (PSMA) and in the intestines where it was named Folate Hydrolase 1 (FOLH1). It was almost a decade to establish that NAALADase, PSMA, and FOLH1 are encoded by the same gene. The enzyme has emerged as a therapeutic target outside of the brain, with the most notable progress made in the treatment of prostate cancer and inflammatory bowel disease (IBD). PSMA-PET imaging with high affinity ligands is proving useful for the clinical diagnosis and staging of prostate cancer. A molecular radiotherapy based on similar ligands is in trials for metastatic castration-resistant prostate cancer. New PSMA inhibitor prodrugs that preferentially block kidney and salivary gland versus prostate tumor enzyme may improve the clinical safety of this radiotherapy. The wide clinical use of PSMA-PET imaging in prostate cancer has coincidentally led to clinical documentation of GCPII upregulation in a wide variety of tumors and inflammatory diseases, likely associated with angiogenesis. In IBD, expression of the FOLH1 gene that codes for GCPII is strongly upregulated, as is the enzymatic activity in diseased patient biopsies. In animal models of IBD, GCPII inhibitors show substantial efficacy, suggesting potential theranostic use of GCPII ligands for IBD.

摘要

为了向我们的朋友和同事迈克尔·罗宾逊致敬,我们回顾了他在鉴定、表征和定位金属肽酶谷氨酸羧肽酶 II(GCPII)中的作用,该酶最初被称为 NAALADase。当 Mike 在大脑中表征 NAALADase 时,其他实验室独立地在人类前列腺中鉴定出该蛋白,将其命名为前列腺特异性膜抗原(PSMA),并在肠道中命名为叶酸水解酶 1(FOLH1)。花了将近十年的时间才确定 NAALADase、PSMA 和 FOLH1 是由同一个基因编码的。该酶已成为大脑以外的治疗靶点,在治疗前列腺癌和炎症性肠病(IBD)方面取得了最显著的进展。具有高亲和力配体的 PSMA-PET 成像已被证明可用于前列腺癌的临床诊断和分期。基于类似配体的分子放射疗法正在转移性去势抵抗性前列腺癌的临床试验中进行。优先阻断肾脏和唾液腺与前列腺肿瘤酶的新型 PSMA 抑制剂前药可能会提高这种放射疗法的临床安全性。PSMA-PET 成像在前列腺癌中的广泛临床应用巧合地导致了在广泛的肿瘤和炎症性疾病中 GCPII 上调的临床记录,这可能与血管生成有关。在 IBD 中,编码 GCPII 的 FOLH1 基因的表达强烈上调,患病患者活检中的酶活性也上调。在 IBD 的动物模型中,GCPII 抑制剂显示出显著的疗效,这表明 GCPII 配体在 IBD 中有潜在的治疗应用。

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