Circadian Alterations Increase with Progression in a Patient-Derived Cell Culture Model of Breast Cancer.
Hui-Hsien LinStephanie R TaylorMichelle E FarkasPublished in: Clocks & sleep (2021)
Circadian rhythm disruption can elicit the development of various diseases, including breast cancer. While studies have used cell lines to study correlations between altered circadian rhythms and cancer, these models have different genetic backgrounds and do not mirror the changes that occur with disease development. Isogenic cell models can recapitulate changes across cancer progression. Hence, in this study, a patient-derived breast cancer model, the 21T series, was used to evaluate changes to circadian oscillations of core clock protein transcription as cells progress from normal to malignant states. Three cell lines were used: H16N2 (normal breast epithelium), 21PT (atypical ductal hyperplasia), and 21MT-1 (invasive metastatic carcinoma). The cancerous cells are both HER2+. We assessed the transcriptional profiles of two core clock proteins, BMAL1 and PER2, which represent a positive and negative component of the molecular oscillator. In the normal H16N2 cells, both genes possessed rhythmic mRNA oscillations with close to standard periods and phases. However, in the cancerous cells, consistent changes were observed: both genes had periods that deviated farther from normal and did not have an anti-phase relationship. In the future, mechanistic studies should be undertaken to determine the oncogenic changes responsible for the circadian alterations found.
Keyphrases
- induced apoptosis
- cell cycle arrest
- transcription factor
- squamous cell carcinoma
- genome wide
- gene expression
- signaling pathway
- oxidative stress
- blood pressure
- atrial fibrillation
- working memory
- mesenchymal stem cells
- heart rate
- copy number
- squamous cell
- childhood cancer
- single molecule
- current status
- bioinformatics analysis
- protein protein