Inactivation of Beta1 Integrin Induces Proteasomal Degradation of Myc Oncoproteins

Overview

Journal Oncotarget

Specialty Oncology

Date 2019 Aug 28

PMID 31452837

Citations 6

Authors

Manabu Sasada

Takuya Iyoda

Tatsufumi Asayama

Yusuke Suenaga

Shunsuke Sakai

Naoya Kase

Hiroaki Kodama

Sana Yokoi

Yoichiro Isohama

Fumio Fukai

Affiliations

Soon will be listed here.

Abstract

The family oncogenes (, , and ) contribute to the genesis of many human cancers. Among them, amplification of the gene and over-expression of N-Myc protein are the most reliable risk factors in neuroblastoma patients. On the other hand, we previously found that a peptide derived from fibronectin, termed FNIII14, is capable of inducing functional inactivation in β1-integrins. Here, we demonstrate that inactivation of β1-integrin by FNIII14 induced proteasomal degradation in N-Myc of neuroblastoma cells with amplification. This N-Myc degradation by FNIII14 reduced the malignant properties, including the anchorage-independent proliferation and invasive migration, of neuroblastoma cells. An experiment using a mouse xenograft model showed that the administration of FNIII14 can inhibit tumor growth, and concomitantly a remarkable decrease in N-Myc levels in tumor tissues. Of note, the activation of proteasomal degradation based on β1-integrin inactivation is applicable to another Myc family oncoprotein, c-myc, which also reverses cancer-associated properties in pancreatic cancer cells. Collectively, β1-integrin inactivation could be a new chemotherapeutic strategy for cancers with highly expressed Myc. FNIII14, which is a unique pharmacological agent able to induce β1-integrin inactivation, may be a promising drug targeting Myc oncoproteins for cancer chemotherapy.

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