Lactate induces vascular permeability via disruption of VE-cadherin in endothelial cells during sepsis

Definitions of sepsis and septic shock were last revised in 2001. Considerable advances have since been made into the pathobiology (changes in organ function, morphology, cell biology, biochemistry, immunology, and circulation), management, and epidemiology of sepsis, suggesting the need for reexamination. Show more

The Warburg effect, originally describing augmented lactogenesis in cancer, is associated with diverse cellular processes such as angiogenesis, hypoxia, macrophage polarization, and T-cell activation. This phenomenon is intimately linked with multiple diseases including neoplasia, sepsis, and autoimmune diseases 1,2 . Lactate, a compound generated during Warburg effect, is widely known as an energy source and metabolic byproduct. However, its non-metabolic functions in physiology and disease remain unknown. Here we report lactate-derived histone lysine lactylation as a new epigenetic modification and demonstrate that histone lactylation directly stimulates gene transcription from chromatin. In total, we identify 28 lactylation sites on core histones in human and mouse cells. Hypoxia and bacterial challenges induce production of lactate through glycolysis that in turn serves as precursor for stimulating histone lactylation. Using bacterially exposed M1 macrophages as a model system, we demonstrate that histone lactylation has different temporal dynamics from acetylation. In the late phase of M1 macrophage polarization, elevated histone lactylation induces homeostatic genes involved in wound healing including arginase 1. Collectively, our results suggest the presence of an endogenous “lactate clock” in bacterially challenged M1 macrophages that turns on gene expression to promote homeostasis. Histone lactylation thus represents a new avenue for understanding the functions of lactate and its role in diverse pathophysiological conditions, including infection and cancer. Show more

Regulatory T (T reg ) cells, vital for maintaining immune homeostasis, also represent a major barrier to cancer immunity, as the tumor microenvironment (TME) promotes T reg cell recruitment, differentiation, and activity 1 , 2 . Tumor cells have deregulated metabolism leading to a metabolite-depleted, hypoxic, and acidic TME 3 , placing infiltrating effector T cells in competition with tumors for metabolites, impairing their function 4 – 6 . Conversely, T reg cells maintain high suppressive function within the TME 7 , 8 . As previous studies suggested T reg cells possess a distinct metabolic profile from effector T cells 9 – 11 , we hypothesized the altered metabolic landscape of the TME and increased activity of intratumoral T reg cells are linked. Here we show T reg cells display broad heterogeneity in utilization of glucose metabolism within normal and transformed tissues and can engage an alternative metabolic pathway to maintain suppressive function and proliferation. Glucose uptake correlated with poorer suppressive function and long-term instability, and high glucose culture impaired T reg cell function and stability. T reg cells rather upregulate pathways in metabolism of the glycolytic byproduct lactic acid. T reg cells withstood high lactate conditions, and lactate treatment prevented the destabilizing effects of high glucose, generating intermediates necessary for proliferation. T reg cell-restricted deletion of MCT1, a lactate transporter, revealed lactate uptake is dispensable for peripheral T reg cell function but required intratumorally, resulting in slowed tumor growth and increased response to immunotherapy. Thus T reg cells are metabolically flexible: they can utilize ‘alternative’ metabolites in the TME to maintain suppressive identity. Further, our studies suggest tumors avoid destruction by not only depriving effector T cells of nutrients, but also metabolically supporting regulatory populations. Show more