Targeting the SUMO pathway as a novel treatment for anaplastic thyroid cancer.

James P De Andrade,Anna C Beck,Claire M Sevenich,Robert A Robinson,Vivian W Gu,Vincent T Wu,Mikhail V Kulak,Ronald J Weigel,Allison W Lorenzen,Maria V Bogachek,Jung M Park,Geeta Lal,Victoria C Cassady

doi:10.18632/oncotarget.21954

Abstract

Cancer stem cells (CSCs) are expanded in anaplastic thyroid cancer (ATC) and standard treatment approaches have failed to improve survival, suggesting a need to specifically target the CSC population. Recent studies in breast and colorectal cancer demonstrated that inhibition of the SUMO pathway repressed CD44 and cleared the CSC population, mediated through SUMO-unconjugated TFAP2A. We sought to evaluate effects of inhibiting the SUMO pathway in ATC. ATC cell lines and primary ATC tumor samples were evaluated. The SUMO pathway was inhibited by knockdown of PIAS1 and use of SUMO inhibitors anacardic acid and PYR-41. The expression of TFAP2A in primary ATC was examined by immunohistochemistry. All ATC cell lines expressed TFAP2A but only 8505C expressed SUMO-conjugated TFAP2A. In 8505C only, inhibition of the SUMO pathway by knockdown of PIAS1 or treatment with SUMO inhibitors repressed expression of CD44 with a concomitant loss of SUMO-conjugated TFAP2A. The effect of SUMO inhibition on CD44 expression was dependent upon TFAP2A. Treatment with SUMO inhibitors resulted in a statistically improved tumor-free survival in mice harboring 8505C xenografts. An examination of primary ATC tissue determined that TFAP2A was expressed in 4 of 11 tumors surveyed. We conclude that inhibition of the SUMO pathway repressed the CSC population, delaying the outgrowth of tumor xenografts in ATC. The effect of SUMO inhibition was dependent upon expression of SUMO-conjugated TFAP2A, which may serve as a molecular marker for therapeutic effects of SUMO inhibitors. The findings provide pre-clinical evidence for development of SUMO inhibitors for the treatment of ATC.

Highlights

It has been proposed that all cancers share a set of six physiologic alterations: autonomous growth signaling, resistance to growth inhibitory signals, circumvention of apoptosis, immortalization, angiogenesis, and the potential for invasion and metastasis [1]
With transfection of NT small interfering RNA (siRNA), anacardic acid (AA) repressed CD44 (Figure 6B); repression of CD44 by AA was abrogated by knockdown of Transcription factor AP2-alpha (TFAP2A). These findings indicated that repression of CD44 by small ubiquitin-like modifier (SUMO) inhibition was dependent upon SUMO conjugated TFAP2A in 8505C anaplastic thyroid cancer (ATC) cells
We previously demonstrated that basal breast cancer xenografts developing in AA treated mice had a significant reduction in the cancer stem cell (CSC)/ tumor-initiating cell (TIC) subpopulation as determined by Fluorescence activated cell sorting (FACS) analysis [13]

Summary

Introduction

It has been proposed that all cancers share a set of six physiologic alterations: autonomous growth signaling, resistance to growth inhibitory signals, circumvention of apoptosis, immortalization, angiogenesis, and the potential for invasion and metastasis [1]. With a greater understanding of the biology of cancer, targeted therapy for a variety of malignancies heralds an era of cancer treatment based on greater predictability of effectiveness, lower risks of complications, and lower costs. The current reality is that targeted cancer therapy is limited www.impactjournals.com/oncotarget to a minority of cancers, can have significant toxicity, is associated with high costs, and is often accompanied by the development of drug-resistant recurrences [2]. It has been proposed that future development of novel cancer therapies should focus on low-toxicity, “broadspectrum” approaches that target key pathways common to cancers [2]. The concept of a cancer stem cell (CSC) population has gained greater acceptance in a variety of malignancies. Models of breast cancer have proved to be a valuable resource to develop paradigms for the biology of CSCs in solid tumors. It is hypothesized that the CSC population is, largely responsible for cancer recurrence, metastasis and resistance to chemotherapy; durable treatments for cancer require effective elimination of the CSC population to prevent cancer recurrence

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Conclusion