ABSTRACT
Human Cep57 is a coiled-coil scaffold at the pericentriolar matrix (PCM), controlling centriole duplication and centrosome maturation for faithful cell division. Genetic truncation mutations of Cep57 are associated with the mosaic-variegated aneuploidy (MVA) syndrome. During interphase, Cep57 forms a complex with Cep63 and Cep152, serving as regulators for centrosome maturation. However, the molecular interplay of Cep57 with these essential scaffolding proteins remains unclear. Here, we demonstrate that Cep57 undergoes liquid-liquid phase separation (LLPS) driven by three critical domains (NTD, CTD, and polybasic LMN). In vitro Cep57 condensates catalyze microtubule nucleation via the LMN motif-mediated tubulin concentration. In cells, the LMN motif is required for centrosomal microtubule aster formation. Moreover, Cep63 restricts Cep57 assembly, expansion, and microtubule polymerization activity. Overexpression of competitive constructs for multivalent interactions, including an MVA mutation, leads to excessive centrosome duplication. In Cep57-depleted cells, self-assembly mutants failed to rescue centriole disengagement and PCM disorganization. Thus, Cep57's multivalent interactions are pivotal for maintaining the accurate structural and functional integrity of human centrosomes.
Subject(s)
Centrosome , Microtubule-Associated Proteins , Microtubules , Humans , Cell Cycle Proteins/metabolism , Cell Cycle Proteins/genetics , Centrioles/metabolism , Centrioles/genetics , Centrosome/metabolism , Microtubule-Associated Proteins/metabolism , Microtubule-Associated Proteins/genetics , Microtubules/metabolism , Mutation , Nuclear Proteins , Protein Binding , Tubulin/metabolism , Tubulin/geneticsABSTRACT
RAS, the most frequently mutated oncogene that drives tumorigenesis by promoting cell proliferation, survival, and motility, has been perceived as undruggable for the past three decades. However, intense research in the past has mainly focused on KRAS mutations, and targeted therapy for NRAS mutations remains an unmet medical need. NRAS mutation is frequently observed in several cancer types, including melanoma (15-20%), leukemia (10%), and occasionally other cancer types. Here, we report using miRNA-708, which targets the distinct 3' untranslated region (3'UTR) of NRAS, to develop miRNA-based precision medicine to treat NRAS mutation-driven cancers. We first confirmed that NRAS is a direct target of miRNA-708. Overexpression of miRNA-708 successfully reduced NRAS protein levels in melanoma, leukemia, and lung cancer cell lines with NRAS mutations, resulting in suppressed cell proliferation, anchorage-independent growth, and promotion of reactive oxygen species-induced apoptosis. Consistent with the functional data, the activities of NRAS-downstream effectors, the PI3K-AKT-mTOR or RAF-MEK-ERK signaling pathway, were impaired in miR-708 overexpressing cells. On the other hand, cell proliferation was not disturbed by miRNA-708 in cell lines carrying wild-type NRAS. Collectively, our data unveil the therapeutic potential of using miRNA-708 in NRAS mutation-driven cancers through direct depletion of constitutively active NRAS and thus inhibition of its downstream effectors to decelerate cancer progression. Harnessing the beneficial effects of miR-708 may therefore offer a potential avenue for small RNA-mediated precision medicine in cancer treatment.
Subject(s)
Leukemia , Melanoma , MicroRNAs , Humans , Phosphatidylinositol 3-Kinases/metabolism , Signal Transduction/genetics , Melanoma/metabolism , MicroRNAs/genetics , Mutation , Cell Line, Tumor , Proto-Oncogene Proteins B-raf/genetics , Membrane Proteins/genetics , GTP Phosphohydrolases/genetics , GTP Phosphohydrolases/metabolismABSTRACT
Glucocorticoids (GCs) are widely prescribed as adjuvant therapy for breast cancer patients. Unlike other steroid hormone receptors, the GC receptor is not considered an oncogene. Research in the past few years has revealed the complexity of GC-mediated signaling, but it remains puzzling whether GCs promote or inhibit tumor progression in different cancer types. Here we evaluated the potential of using a synthetic GC, dexamethasone (DEX), in the treatment of breast cancer. We found that the administration of low-dose DEX suppressed tumor growth and distant metastasis in the MCF-7 and MDA-MB-231 xenograft mouse model, whereas treatment with high-dose DEX enhanced tumor growth and metastasis, respectively. Treatment of breast cancer cells with DEX inhibited cell adhesion, migration, and invasion in a dose-dependent manner. The DEX-mediated inhibition of cell adhesion, migration, and invasion is partly through induction of microRNA-708 and subsequent Rap1B-mediated signaling in MDA-MB-231 cells. On the other hand, in MCF-7 cells, DEX-suppressed cell migration is independent from microRNA-708 mediated signaling. Overall, our data reveal that DEX acts as a double-edged sword during breast-cancer progression and metastasis: Lower concentrations inhibit breast cancer tumor growth and metastasis, whereas higher concentrations may play an undesired role to promote breast cancer progression.