| Literature DB >> 33440149 |
Mainak Chakraborty1, Kevin Chu2, Annie Shrestha3, Xavier S Revelo4, Xiangyue Zhang5, Matthew J Gold6, Saad Khan7, Megan Lee2, Camille Huang2, Masoud Akbari2, Fanta Barrow8, Yi Tao Chan9, Helena Lei1, Nicholas K Kotoulas10, Juan Jovel11, Chiara Pastrello12, Max Kotlyar12, Cynthia Goh10, Evangelos Michelakis13, Xavier Clemente-Casares2, Pamela S Ohashi14, Edgar G Engleman5, Shawn Winer15, Igor Jurisica16, Sue Tsai17, Daniel A Winer18.
Abstract
Stiffness in the tissue microenvironment changes in most diseases and immunological conditions, but its direct influence on the immune system is poorly understood. Here, we show that static tension impacts immune cell function, maturation, and metabolism. Bone-marrow-derived and/or splenic dendritic cells (DCs) grown in vitro at physiological resting stiffness have reduced proliferation, activation, and cytokine production compared with cells grown under higher stiffness, mimicking fibro-inflammatory disease. Consistently, DCs grown under higher stiffness show increased activation and flux of major glucose metabolic pathways. In DC models of autoimmune diabetes and tumor immunotherapy, tension primes DCs to elicit an adaptive immune response. Mechanistic workup identifies the Hippo-signaling molecule, TAZ, as well as Ca2+-related ion channels, including potentially PIEZO1, as important effectors impacting DC metabolism and function under tension. Tension also directs the phenotypes of monocyte-derived DCs in humans. Thus, mechanical stiffness is a critical environmental cue of DCs and innate immunity.Entities:
Keywords: PIEZO1; TAZ; danger signals; dendritic cells; immunometabolism; inflammation; innate immunity; mechanoimmunology; mechanosensing; tension
Mesh:
Year: 2021 PMID: 33440149 DOI: 10.1016/j.celrep.2020.108609
Source DB: PubMed Journal: Cell Rep Impact factor: 9.423