Bag‐1‐mediated HSF1 phosphorylation regulates expression of heat shock proteins in breast cancer cells

According to the World Health Organization in 2022, 2.3 million women were diagnosed with breast cancer. Investigating the interaction networks between Bcl‐2‐associated athanogene (Bag)‐1 and other chaperone proteins may further the current understanding of the regulation of protein homeostasis in breast cancer cells and contribute to the development of treatment options. The present study aimed to determine the interactions between Bag‐1 and heat shock proteins (HSPs); namely, HSP90, HSP70 and HSP27, to elucidate their role in promoting heat shock factor‐1 (HSF1)‐dependent survival of breast cancer cells. HER2‐negative (MCF‐7) and HER2‐positive (BT‐474) cell lines were used to examine the impact of Bag‐1 expression on HSF1 and HSPs. We demonstrated that Bag‐1 overexpression promoted HER2 expression in breast cancer cells, thereby resulting in the concurrent constitutive activation of the HSF1–HSP axis. The activation of HSP results in the stabilization of several tumor‐promoting HSP clients such as AKT, mTOR and HSF1 itself, which substantially accelerates tumor development. Our results suggest that Bag‐1 can modulate the chaperone activity of HSPs, such as HSP27, by directly or indirectly regulating the phosphorylation of HSF1. This modulation of chaperone activity can influence the activation of genes involved in cellular homeostasis, thereby protecting cells against stress. We demonstrate that Bcl‐2‐associated athanogene (Bag)‐1 overexpression promotes human epidermal growth factor receptor 2 expression, thereby resulting in the activation of the heat shock factor‐1 (HSF1)–heat shock protein (HSP) axis. Our results suggest that Bag‐1 can modulate the chaperone activity of HSPs, by directly or indirectly regulating the phosphorylation of HSF1. This modulation of chaperone activity can influence the activation of genes involved in cellular homeostasis, thereby protecting cells against stress.