Human endotrophin as a driver of malignant tumor growth
Dawei Bu, Clair Crewe, Christine M. Kusminski, Ruth Gordillo, Alexandra L. Ghaben, Min Kim, Jiyoung Park, Hui Deng, Wei Xiong, Xiao-Zheng Liu, Per Eystein Lønning, Nils Halberg, Adan Rios, Yujun Chang, Anneliese Gonzalez, Ningyan Zhang, Zhiqiang An, Philipp E. Scherer
Dawei Bu, Clair Crewe, Christine M. Kusminski, Ruth Gordillo, Alexandra L. Ghaben, Min Kim, Jiyoung Park, Hui Deng, Wei Xiong, Xiao-Zheng Liu, Per Eystein Lønning, Nils Halberg, Adan Rios, Yujun Chang, Anneliese Gonzalez, Ningyan Zhang, Zhiqiang An, Philipp E. Scherer
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Research Article Endocrinology Oncology

Human endotrophin as a driver of malignant tumor growth

Abstract

We have previously reported that the carboxy-terminal proteolytic cleavage product of the COL6α3 chain that we refer to as “endotrophin” has potent effects on transformed mammary ductal epithelial cells in rodents. Endotrophin (ETP) is abundantly expressed in adipose tissue. It is a chemoattractant for macrophages, exerts effects on endothelial cells and through epithelial-mesenchymal transition (EMT) enhances progression of tumor cells. In a recombinant form, human endotrophin exerts similar effects on human macrophages and endothelial cells as its rodent counterpart. It enhances EMT in human breast cancer cells and upon overexpression in tumor cells, the cells become chemoresistant. Here, we report the identification of endotrophin from human plasma. It is circulating at higher levels in breast cancer patients. We have developed neutralizing monoclonal antibodies against human endotrophin and provide evidence for the effectiveness of these antibodies to curb tumor growth and enhance chemosensitivity in a nude mouse model carrying human tumor cell lesions. Combined, the data validate endotrophin as a viable target for anti-tumor therapy for human breast cancer and opens the possibility for further use of these new reagents for anti-fibrotic approaches in liver, kidney, bone marrow and adipose tissue.

Authors

Dawei Bu, Clair Crewe, Christine M. Kusminski, Ruth Gordillo, Alexandra L. Ghaben, Min Kim, Jiyoung Park, Hui Deng, Wei Xiong, Xiao-Zheng Liu, Per Eystein Lønning, Nils Halberg, Adan Rios, Yujun Chang, Anneliese Gonzalez, Ningyan Zhang, Zhiqiang An, Philipp E. Scherer

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Figure 4

The in vivo effects of endotrophin overexpressing MCF-7 cells.

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The in vivo effects of endotrophin overexpressing MCF-7 cells. (A) GFP-M...
(A) GFP-MCF-7 cells (2 × 106 cells) (control) and ETP transfected MCF-7 cells (2 × 106 cells) were implanted into nude mice for 6-weeks. Tumor volume was determined by caliper measurement. Data was represented as mean ± SEM (n = 8/group) and **P < 0.001, ***P < 0.0001 by calculated by using 2-way ANOVA with Sidak’s correction for multiple comparisons. (B) H&E staining of tumor lesions from MCF-7 and ETP-transfected MCF-7 tumors. Endomucin immunofluorescence staining of tumor tissues from MCF-7 and ETP-transfected MCF-7 tumors. Mac2 immunofluorescence staining for tumor tissues from MCF-7 and ETP- transfected MCF-7 tumors. E-CAD immunofluorescence staining for tumor tissues from MCF-7 and ETP-transfected MCF-7 tumors. Scale bars: 50 μm. (C) Total RNA was extracted from implanted MCF-7 and ETP-MCF-7 tumors. Expression of the EMT marker genes Twist, Snail, Cdh2, and Cdh1 was determined by qRT-PCR, then normalized to GAPDH. Mean ± SEM, n = 3, and statistical significance (***P < 0.0001) was calculated using unpaired, 2-tailed t-test w/Holm-Sidak correction for multiple comparisons. (D) Half-life determination of ETPmAb4 in the mouse.