Dysregulation of mitochondrial translation caused by CBFB deficiency cooperates with mutant PIK3CA and is a vulnerability in breast cancer.
Navdeep MalikYoung-Im KimHualong YanYu-Chou TsengWendy D DuboisGamze AyazAndy D TranLaura Vera RamírezHoward Hua YangAleksandra M MichalowskiMichael J KruhlakMaxwell Y LeeKent W HunterJing HuangPublished in: Cancer research (2023)
Understanding functional interactions between cancer mutations is an attractive strategy for discovering unappreciated cancer pathways and developing new combination therapies to improve personalized treatment. However, distinguishing driver gene pairs from passenger pairs remains challenging. Here, we designed an integrated omics approach to identify driver gene pairs by leveraging genetic interaction analyses of top mutated breast cancer genes and the proteomics interactome data of their encoded proteins. This approach identified that PIK3CA oncogenic gain-of-function (GOF) and CBFB loss-of-function (LOF) mutations cooperate to promote breast tumor progression in both mice and humans. The transcription factor CBFB localized to mitochondria and moonlighted in translating the mitochondrial genome. Mechanistically, CBFB enhanced the binding of mitochondrial mRNAs to TUFM, a mitochondrial translation elongation factor. Independent of mutant PI3K, mitochondrial translation defects caused by CBFB LOF led to multiple metabolic reprogramming events, including defective oxidative phosphorylation (OXPHOS), the Warburg effect, and autophagy/mitophagy addiction. Furthermore, autophagy and PI3K inhibitors synergistically killed breast cancer cells and impaired the growth of breast tumors, including patient-derived xenografts (PDXs) carrying CBFB LOF and PIK3CA GOF mutations. Thus, our study offers mechanistic insights into the functional interaction between mutant PI3K and mitochondrial translation dysregulation in breast cancer progression and provides a strong preclinical rationale for combining autophagy and PI3K inhibitors in precision medicine for breast cancer.
Keyphrases
- oxidative stress
- genome wide
- transcription factor
- cell death
- signaling pathway
- wild type
- endoplasmic reticulum stress
- papillary thyroid
- breast cancer cells
- copy number
- protein kinase
- genome wide identification
- mass spectrometry
- stem cells
- climate change
- squamous cell carcinoma
- type diabetes
- squamous cell
- electronic health record
- metabolic syndrome
- insulin resistance
- bone marrow
- dna binding
- machine learning
- cell therapy
- young adults
- skeletal muscle
- artificial intelligence
- endoplasmic reticulum
- binding protein
- smoking cessation
- label free