Breaking down IgA: Tomasiella immunophila enlightens microbiome-immune interactions.

The recent discovery by Lu and colleagues of Tomasiella immunophila, a bacterium that degrades IgA, offers insights into microbial influences on mucosal immunity and evolutionary immune trade-offs. By modulating IgA titers, T. immunophila influences the dynamic interactions and balance between the host and pathogen.

Spermidine - an old molecule with a new age-defying immune function.

Polyamines - putrescine, spermidine, and spermine - are widely distributed aliphatic compounds known to regulate important biological processes in prokaryotic and eukaryotic cells. Therefore, spermidine insufficiency is associated with various physio-pathological processes, such as aging and cancers. Recent advances in immuno-metabolism and immunotherapy shed new light on the role of spermidine in immune cell regulation and anticancer responses.

Secreted immune metabolites that mediate immune cell communication and function.

Metabolites are emerging as essential factors for the immune system that are involved in both metabolic circuits and signaling cascades. Accumulated evidence suggests that altered metabolic programs initiated by the activation and maturation of immune cell types are accompanied by the delivery of various metabolites into the local environment. We propose that, in addition to protein/peptide ligands, secreted immune metabolites (SIMets) are essential components of immune communication networks that fine-tune immune responses under homeostatic and pathological conditions.

Spermidine activates mitochondrial trifunctional protein and improves antitumor immunity in mice.

Spermidine (SPD) delays age-related pathologies in various organisms. SPD supplementation overcame the impaired immunotherapy against tumors in aged mice by increasing mitochondrial function and activating CD8 T cells. Treatment of naïve CD8 T cells with SPD acutely enhanced fatty acid oxidation.