Abstract
Simple SummaryDespite remarkable advances in breast cancer treatment, few strategies other than standard cytotoxic chemotherapy are available for patients with triple-negative breast cancer (TNBC) due to the lack of therapeutic target molecules. TNBC is still the most aggressive subtype, with a high risk of recurrence and metastasis within 2 years after initial treatment. Thus, there is an unmet medical need to develop new treatments for metastatic and recurrent TNBC patients. In this study we tested a new antibody, targeting extracellular periostin protein alternative splicing variants, which are induced by conventional chemotherapy or during the process of endothelial mesenchymal transition. This antibody reduced periostin-secreting TNBC in a mouse xenograft model, accompanied by a decrease in the number of M2 tumor-associated macrophages and tumor vessels. Periostin alternative splicing variants might be a specific and safe therapeutic target in patients with TNBC.Periostin (Pn) is involved in multiple processes of cancer progression. Previously, we reported that Pn expression is correlated with mesenchymal tumor markers and poor prognosis in triple-negative breast cancer (TNBC). In the TNBC xenograft model, chemotherapy increased expression of a Pn alternative splicing variant (ASV) with exon 21, and administration of the neutralizing antibody against Pn with exon 21 (Pn-21 Ab) overcame chemoresistance with a reduction in the mesenchymal cancer cell fraction. In the present study, the role of Pn ASV with exon 21 in TNBC progression has been addressed. We first established a stable cell line carrying a fluorescence-based splicing reporter. Pn-positive TNBC has higher expression of genes related to tumor-associated macrophage (TAM) recruitment and ECM-receptor interaction than Pn-negative cells. In a xenograft model, only Pn-positive cells initiated tumor formation, and the Pn-21 Ab suppressed tumor cell growth, accompanied by decreased M2 TAM polarization and the number of tumor vessels. These data suggest that cancer cell-derived Pn ASV educates TAMs and regulates angiogenesis, which in turn establishes a microenvironmental niche that is supportive of TNBC.
Highlights
Despite remarkable advances in cancer treatment approaches, breast cancer is still the main cause of cancer-related death among females worldwide, with an estimated2.1 million new cases and 626,679 deaths in 2018 [1]
We previously showed that extracellular matrix periostin (Pn) protein expression is associated with the epithelial-to-mesenchymal transition (EMT) gene signature, especially in breast cancer cells [5]
In this study, using a Pn splicing reporter, we found that SUM159PT triple-negative breast cancer (TNBC) cells contain two populations: (1) a population expressing higher levels of Pn (Pn-positive cells), including an alternative splicing variant (ASV) with exon 21, and genes related to extracellular matrix proteins, focal adhesion proteins, and inflammatory cytokines recruiting tumor-associated macrophages (TAMs), and (2) a population secreting much less Pn (Pn-negative cells)
Summary
Despite remarkable advances in cancer treatment approaches, breast cancer is still the main cause of cancer-related death among females worldwide, with an estimated. A chemotherapy-induced cancer-specific ASV of Pn, which contains Pn exon 21, is secreted into the extracellular space, and the application of the neutralizing antibody targeting Pn exon 21 overcomes. In this study, using a Pn splicing reporter, we found that SUM159PT TNBC cells contain two populations: (1) a population expressing higher levels of Pn (Pn-positive cells), including an ASV with exon 21, and genes related to extracellular matrix proteins, focal adhesion proteins, and inflammatory cytokines recruiting tumor-associated macrophages (TAMs), and (2) a population secreting much less Pn (Pn-negative cells). Application of a neutralizing antibody targeting Pn exon 21 halts disease progression without toxicity This favorable effect is accompanied by reduced M2 TAM accumulation and tumor vessels. TAM polarization and tumor vessel formation, establishing a microenvironmental niche supportive of breast cancer
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