Abstract
CD4+ T cells provide adaptive immunity against pathogens and abnormal cells, and they are also associated with various immune-related diseases. CD4+ T cells’ metabolism is dysregulated in these pathologies and represents an opportunity for drug discovery and development. Genome-scale metabolic modeling offers an opportunity to accelerate drug discovery by providing high-quality information about possible target space in the context of a modeled disease. Here, we develop genome-scale models of naïve, Th1, Th2, and Th17 CD4+ T-cell subtypes to map metabolic perturbations in rheumatoid arthritis, multiple sclerosis, and primary biliary cholangitis. We subjected these models to in silico simulations for drug response analysis of existing FDA-approved drugs and compounds. Integration of disease-specific differentially expressed genes with altered reactions in response to metabolic perturbations identified 68 drug targets for the three autoimmune diseases. In vitro experimental validation, together with literature-based evidence, showed that modulation of fifty percent of identified drug targets suppressed CD4+ T cells, further increasing their potential impact as therapeutic interventions. Our approach can be generalized in the context of other diseases, and the metabolic models can be further used to dissect CD4+ T-cell metabolism.
Highlights
CD4+ T cells are essential components of the human immune system that fight against pathogenic invaders and abnormal cells by producing cytokines and stimulating other cells, such as B cells, macrophages, and neutrophils[1]
Identification of genes expressed in the CD4+ T cells We used the computational approach shown in Fig. 1 to construct metabolic models of naïve and effector CD4+ T cells
The analysis showed that between 675 and 836 metabolic genes were expressed depending on the CD4+ T-cell subtype (Supplementary Data 2)
Summary
CD4+ T cells are essential components of the human immune system that fight against pathogenic invaders and abnormal cells by producing cytokines and stimulating other cells, such as B cells, macrophages, and neutrophils[1]. CD4+ T cells are activated and proliferate, and their metabolism adjusts to fulfill increased bioenergetic and biosynthetic demands. Activated effector CD4+ T cells are highly glycolytic[2] and use aerobic glycolysis and oxidative phosphorylation (OXPHOS) for proliferation[3]. Naïve, resting, and regulatory CD4+ T cells are less glycolytic and use OXPHOS and fatty acid oxidation (FAO) for energy generation. Metabolically dysregulated CD4+ T cells were observed in several diseases such as diabetes[4], atherosclerosis[5], cancers[6], and autoimmune diseases such as rheumatoid arthritis (RA)[7,8], multiple sclerosis (MS)[9], primary biliary cholangitis (PBC)[10], and systemic lupus erythematosus (SLE)[11,12].
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