TRIM59，一种用于肿瘤发生的免疫组织化学检测的新型多癌症生物标志物。

TRIM59, a novel multiple cancer biomarker for immunohistochemical detection of tumorigenesis.

机构信息

Department of Surgery, Lawson Health Research Institute, Western University, London, Ontario, Canada.

出版信息

BMJ Open. 2012 Oct 8;2(5). doi: 10.1136/bmjopen-2012-001410. Print 2012.

DOI:10.1136/bmjopen-2012-001410

PMID:23048060

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3488719/

Abstract

OBJECTIVES AND DESIGN

We identified a novel TRIM59 gene, as an early signal transducer in two (SV40Tag and Ras) oncogene pathways in murine prostate cancer (CaP) models. We explore its clinical applications as a multitumour marker detecting early tumorigenesis by immunohistochemistry (IHC).

SETTING AND PARTICIPANTS

88 CaP patients were from a tissue microarray (TMA) of radical prostatectomy specimen, 42 patients from a 35 multiple tumour TMA, 75 patients with renal cell carcinoma (RCC) and 92 patients from eight different tumour groups (breast, lung, parotid, gastrointestinal, female genital tract, bladder, kidney and prostate cancer).

RESULTS

TRIM59 upregulation specifically in tumour area was determined by IHC in 291 cases of 37 tumour types. To demonstrate that TRIM59 upregulation is 'tumour-specific', we characterised a significant correlation of TRIM59 IHC signals with tumorigenesis and progression, while in control and normal area, TRIM59 IHC signal was all negative or significantly low. TRIM59 protein upregulation in prostate and kidney cancers was detectable in both intensity and extent in early tumorigenesis of prostate intraepithelial neoplasia (p<0.05) and grade 1 of RCC (p<0.05), and stopped until high grades cancer. The results of the correlation in these two large cohorts of tumour types confirmed and repeated murine CaP model studies. Enhanced TRIM59 expression was identified in most of the 37 different tumours, while the highest intensities were in lung, breast, liver, skin, tongue and mouth (squamous cell cancer) and endometrial cancers. Multiple tumour upregulation was further confirmed by comparing relative scores of TRIM59 IHC signals in eight tumours with a larger patient population; and by a mouse whole-mount embryo (14.5 days post conception) test on the origin of TRIM59 upregulation in epithelial cells.

CONCLUSIONS

TRIM59 may be used a novel multiple tumour marker for immunohistochemical detecting early tumorigenesis and could direct a novel strategy for molecular-targeted diagnosis and therapy of cancer.

摘要

目的和设计

我们鉴定了一种新型的 TRIM59 基因，作为两种致癌基因途径（SV40Tag 和 Ras）在小鼠前列腺癌（CaP）模型中的早期信号转导物。我们通过免疫组织化学（IHC）探索其作为一种多肿瘤标志物用于检测早期肿瘤发生的临床应用。

设置和参与者

88 例 CaP 患者来自根治性前列腺切除术标本的组织微阵列（TMA），42 例来自 35 例多肿瘤 TMA，75 例肾细胞癌（RCC）患者和 92 例来自 8 个不同肿瘤组（乳腺、肺、腮腺、胃肠道、女性生殖道、膀胱、肾和前列腺癌）的患者。

结果

通过 37 种肿瘤类型的 291 例病例的 IHC 确定了 TRIM59 的上调特异性。为了证明 TRIM59 的上调是“肿瘤特异性的”，我们描述了 TRIM59 IHC 信号与肿瘤发生和进展之间的显著相关性，而在对照和正常区域，TRIM59 IHC 信号均为阴性或显著降低。在前列腺和肾癌中，TRIM59 蛋白的上调在前列腺上皮内瘤变（p<0.05）和 RCC 1 级（p<0.05）的早期肿瘤发生中在强度和程度上均可检测到，并在高等级癌症中停止。这两个大型肿瘤类型队列的相关性研究结果证实并重复了小鼠 CaP 模型研究的结果。在 37 种不同的肿瘤中，大多数肿瘤都鉴定到了增强的 TRIM59 表达，而在肺、乳腺、肝、皮肤、舌和口腔（鳞状细胞癌）和子宫内膜癌中，其表达最强。通过在更大的患者群体中比较 8 种肿瘤的 TRIM59 IHC 信号的相对评分，以及通过对上皮细胞中 TRIM59 上调起源的小鼠全胚胎（妊娠后 14.5 天）试验，进一步证实了多肿瘤的上调。

结论

TRIM59 可能作为一种新的多肿瘤标志物用于免疫组织化学检测早期肿瘤发生，并为癌症的分子靶向诊断和治疗提供新策略。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4248/3488719/16cd5bf1cf04/bmjopen2012001410f01.jpg

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本文引用的文献

Characterization of the oncogenic activity of the novel TRIM59 gene in mouse cancer models.鉴定新型 TRIM59 基因在鼠肿瘤模型中的致癌活性。

Mol Cancer Ther. 2011 Jul;10(7):1229-40. doi: 10.1158/1535-7163.MCT-11-0077. Epub 2011 May 18.

Molecular targeted enhanced ultrasound imaging of flk1 reveals diagnosis and prognosis potential in a genetically engineered mouse prostate cancer model.Flk1的分子靶向增强超声成像揭示了基因工程小鼠前列腺癌模型中的诊断和预后潜力。

Mol Imaging. 2009 Jul-Aug;8(4):209-20.

RING domain E3 ubiquitin ligases.环状结构域E3泛素连接酶

Annu Rev Biochem. 2009;78:399-434. doi: 10.1146/annurev.biochem.78.101807.093809.

nhl-2 Modulates microRNA activity in Caenorhabditis elegans.NHL-2调节秀丽隐杆线虫中的微小RNA活性。

Cell. 2009 Mar 6;136(5):926-38. doi: 10.1016/j.cell.2009.01.053.

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TRIM59，一种用于肿瘤发生的免疫组织化学检测的新型多癌症生物标志物。

TRIM59, a novel multiple cancer biomarker for immunohistochemical detection of tumorigenesis.

机构信息

出版信息

OBJECTIVES AND DESIGN

SETTING AND PARTICIPANTS

RESULTS

CONCLUSIONS

目的和设计

设置和参与者

结果

结论

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