Abstract
Pathogenic mycobacteria induce the formation of hypoxic granulomas during latent tuberculosis (TB) infection, in which the immune system contains, but fails to eliminate the mycobacteria. Fatty acid metabolism-related genes are relatively overrepresented in the mycobacterial genome and mycobacteria favor host-derived fatty acids as nutrient sources. However, whether and how mycobacteria modulate host fatty acid metabolism to drive granuloma progression remains unknown. Here, we report that mycobacteria under hypoxia markedly secrete the protein Rv0859/MMAR_4677 (Fatty-acid degradation A, FadA), which is also enriched in tuberculous granulomas. FadA acts as an acetyltransferase that converts host acetyl-CoA to acetoacetyl-CoA. The reduced acetyl-CoA level suppresses H3K9Ac-mediated expression of the host proinflammatory cytokine Il6, thus promoting granuloma progression. Moreover, supplementation of acetate increases the level of acetyl-CoA and inhibits the formation of granulomas. Our findings suggest an unexpected mechanism of a hypoxia-induced mycobacterial protein suppressing host immunity via modulation of host fatty acid metabolism and raise the possibility of a novel therapeutic strategy for TB infection.
Highlights
Tuberculosis (TB) caused by Mycobacterium tuberculosis (M. tuberculosis) is associated with 10 million active cases and 1.4 million deaths annually[1]
Since fatty acid metabolism-related genes are relatively “overrepresented” in the M. tuberculosis genome, and fatty acid metabolism plays an important role in M. tuberculosis infection[20,21], we focused on the five fatty acid metabolism-related genes Rv0824c, FadA, Rv0860, Rv1094, and Rv3774 for further study
These results demonstrate that FadA is a hypoxia-induced M. tuberculosis protein
Summary
Tuberculosis (TB) caused by Mycobacterium tuberculosis (M. tuberculosis) is associated with 10 million active cases and 1.4 million deaths annually[1]. Mycobacteria must adapt to hypoxia in order to survive within granulomas[6,7,8]. Hypoxia induces widespread transcriptional changes of mycobacterial genes that are associated with a metabolically altered state and cause the bacteria to enter into a non-replicating “quiescent” state that is tolerant of antibiotic treatment[7,9]. Mycobacteria utilize the ESX-1 type VII and SecA secretion system to transport effector proteins across their cell wall into host immune cells[10]. Whether and how the secreted mycobacterial proteins are induced under hypoxia to promote the adaption to the hostile environment remains unknown. The zebrafish-Mycobacterium marinum (M. marinum) platform has been used to study the role of mycobacterial components including early secretory
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