We turnover billions of apoptotic cells daily, and these are removed by professional and non-professional phagocytes via efferocytosis 1 . Characterizing the transcriptional program of phagocytes, we discovered a novel solute carrier family (SLC) gene signature (involving 33 SLC members) that is specifically modified during efferocytosis, but not antibody-mediated phagocytosis. Assessing the functional relevance of these SLCs, we noted a robust induction of an aerobic glycolysis program in efferocytic phagocytes, initiated by SLC2A1-mediated glucose uptake, with concurrent suppression of oxidative phosphorylation program. Interestingly, the different steps of phagocytosis 2 , i.e. smell (‘find-me’ signals/ sensing factors released by apoptotic cells), taste (phagocyte-apoptotic cell contact), and ingestion (corpse internalization), activated different SLCs and other molecules to promote glycolysis. Further, lactate, a natural by-product of aerobic glycolysis 3 , was released via another SLC (SLC16A1) that was upregulated after corpse uptake. While glycolysis within phagocytes contributed to actin polymerization and the continued uptake of corpses, the lactate released via SLC16A1 influenced the establishment of an anti-inflammatory tissue environment. Collectively, these data reveal a novel SLC program activated during efferocytosis, identify a previously unknown reliance on aerobic glycolysis during apoptotic cell uptake, and that glycolytic byproducts of efferocytosis can also influence other cells in the microenvironment.
Programmed cell death, a physiologic process for removing cells, is critically important in normal development and for elimination of damaged cells. Conversely, unattended cell death contributes to a variety of human disease pathogenesis. Thus, precise understanding of molecular mechanisms underlying control of cell death is important and relevant to public health. Recent studies emphasize that transforming growth factor-b-activated kinase 1 (TAK1) is a central regulator of cell death and is activated through a diverse set of intra-and extracellular stimuli. The physiologic importance of TAK1 and TAK1-binding proteins in cell survival and death has been demonstrated using a number of genetically engineered mice. These studies uncover an indispensable role of TAK1 and its binding proteins for maintenance of cell viability and tissue homeostasis in a variety of organs. TAK1 is known to control cell viability and inflammation through activating downstream effectors such as NF-jB and mitogen-activated protein kinases (MAPKs). It is also emerging that TAK1 regulates cell survival not solely through NF-jB but also through NF-jB-independent pathways such as oxidative stress and receptor-interacting protein kinase 1 (RIPK1) kinase activity-dependent pathway. Moreover, recent studies have identified TAK1's seemingly paradoxical role to induce programmed necrosis, also referred to as necroptosis. This review summarizes the consequences of TAK1 deficiency in different cell and tissue types from the perspective of cell death and also focuses on the mechanism by which TAK1 complex inhibits or promotes programmed cell death. This review serves to synthesize our current understanding of TAK1 in cell survival and death to identify promising directions for future research and TAK1's potential relevance to human disease pathogenesis.
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