Hyperleptinemia in obese state renders luminal breast cancers refractory to tamoxifen by coordinating a crosstalk between Med1, miR205 and ErbB.
Arumugam NagalingamSumit SiddharthSheetal ParidaNethaji MunirajDimiter AvtanskiPanjamurthy KuppusamyJustin ElseyJack L ArbiserBalázs GyőrffyDipali SharmaPublished in: NPJ breast cancer (2021)
Obese women with hormone receptor-positive breast cancer exhibit poor response to therapy and inferior outcomes. However, the underlying molecular mechanisms by which obesity/hyperleptinemia may reduce the efficacy of hormonal therapy remain elusive. Obese mice with hyperleptinemia exhibit increased tumor progression and respond poorly to tamoxifen compared to non-obese mice. Exogenous leptin abrogates tamoxifen-mediated growth inhibition and potentiates breast tumor growth even in the presence of tamoxifen. Mechanistically, leptin induces nuclear translocation of phosphorylated-ER and increases the expression of ER-responsive genes, while reducing tamoxifen-mediated gene repression by abrogating tamoxifen-induced recruitment of corepressors NCoR, SMRT, and Mi2 and potentiating coactivator binding. Furthermore, in silico analysis revealed that coactivator Med1 potentially associates with 48 (out of 74) obesity-signature genes. Interestingly, leptin upregulates Med1 expression by decreasing miR-205, and increases its functional activation via phosphorylation, which is mediated by activation of Her2 and EGFR. It is important to note that Med1 silencing abrogates the negative effects of leptin on tamoxifen efficacy. In addition, honokiol or adiponectin treatment effectively inhibits leptin-induced Med1 expression and improves tamoxifen efficacy in hyperleptinemic state. These studies uncover the mechanistic insights how obese/hyperleptinemic state may contribute to poor response to tamoxifen implicating leptin-miR205-Med1 and leptin-Her2-EGFR-Med1 axes, and present bioactive compound honokiol and adipocytokine adiponectin as agents that can block leptin's negative effect on tamoxifen.
Keyphrases
- positive breast cancer
- breast cancer cells
- estrogen receptor
- metabolic syndrome
- poor prognosis
- weight loss
- long non coding rna
- cell proliferation
- type diabetes
- insulin resistance
- adipose tissue
- small cell lung cancer
- binding protein
- tyrosine kinase
- high glucose
- bariatric surgery
- stem cells
- obese patients
- weight gain
- bone marrow
- diabetic rats
- drug induced
- oxidative stress
- endothelial cells
- high fat diet induced
- case control
- genome wide analysis
- smoking cessation