cGAS regulates metabolic reprogramming independently of STING pathway in colorectal cancer

Background

Cyclic GMP-AMP synthase (cGAS) is widely acknowledged for detecting cytosolic chromatin fragments and triggering innate immune responses through the production of the second messenger cGAMP, which subsequently activates the adaptor protein STING. However, the role of cGAS in regulating metabolic reprogramming independently of STING activation has not yet been explored.

Methods

Gene set enrichment pathway analysis (GSEA) based on TCGA transcriptomics, combined with Seahorse metabolic analysis of CRC cell lines and human normal colonic mucosa cell line FHC, was performed to profile the metabolic features in CRC. cGAS doxycycline- (dox) inducible knockout (iKO) CRC sublines were generated to investigate the role of cGAS in CRC. Transcriptome and proteome data from COAD cohorts were utilized to evaluate the RNA and protein expression levels of cGAS in COAD tissues and normal colon tissues. Overall survival information of patients with COAD was used to evaluate the prognostic value of cGAS expression. Colony formation assays were conducted to evaluate the clonogenicity of CRC cells under different situations. Flow cytometry detecting the signal of fluorogenic reactive oxygen species (ROS) probes was performed to evaluate the total cellular and mitochondrial oxidative stress level in CRC cells. A propidium iodide (PI) staining assay was used to evaluate the cell death level in CRC cells. Quantitative PCR (qPCR) was conducted to detect the RNA level of STING pathway downstream target genes. Mass spectrometry was used for the identification of novel binding partners of cGAS in CRC cells. Co-immunoprecipitation (co-IP) was conducted to confirm the interaction between cGAS and NDUFA4L2.

Results

By integrating metabolic pathway analysis based on TCGA transcriptomics with Seahorse metabolic analysis of a panel CRC cell lines and the human normal colonic mucosa cell line FHC, we demonstrated that CRC cells exhibit typical characteristics of metabolic reprogramming, characterized by a shift from oxidative phosphorylation (OXPHOS) to glycolysis. We found that cGAS is critical for CRC cells to maintain this metabolic switch. Specifically, the suppression of cGAS through siRNA-mediated knockdown or doxycycline-inducible knockout reversed this metabolic switch, resulting in increased OXPHOS activity, elevated production of OXPHOS byproduct reactive oxygen species (ROS), and consequently caused oxidative stress. This disruption induced oxidative stress, ultimately resulting in cell death and reduced cell viability. Moreover, significant upregulation of cGAS in CRC tissues and cell lines and its association with poor prognosis in CRC patients was observed. Subsequently, we demonstrated that the role of cGAS in regulating metabolic reprogramming does not rely on the canonical cGAS-STING pathway. Co-immunoprecipitation combined with mass spectrometry identified NDUFA4L2 as a novel interactor of cGAS. Subsequent functional experiments, including mitochondrial respiration and oxidative stress assays, demonstrated that cGAS plays a crucial role in sustaining elevated levels of NDUFA4L2 protein expression. The increased expression of NDUFA4L2 is essential for cGAS-mediated regulation of metabolic reprogramming and cell survival in CRC cells.

Conclusion

cGAS regulates metabolic reprogramming and promotes cell survival in CRC cells through its interaction with NDUFA4L2, independently of the canonical cGAS-STING pathway.