Endothelial Lactate Controls Muscle Regeneration from Ischemia by Inducing M2-like Macrophage Polarization

Overview

Journal Cell Metab

Publisher Cell Press

Specialties Cell Biology
Endocrinology

Date 2020 Jun 4

PMID 32492393

Citations 163

Authors

Jing Zhang

Jonathan Muri

Gillian Fitzgerald

Tatiane Gorski

Roberto Gianni-Barrera

Evi Masschelein

Gommaar DHulst

Paola Gilardoni

Guillermo Turiel

Zheng Fan

Tongtong Wang

Melanie Planque

Peter Carmeliet

Luc Pellerin

Christian Wolfrum

Sarah-Maria Fendt

Andrea Banfi

Christian Stockmann

Ines Soro-Arnaiz

Manfred Kopf

Katrien De Bock

Affiliations

Soon will be listed here.

Abstract

Endothelial cell (EC)-derived signals contribute to organ regeneration, but angiocrine metabolic communication is not described. We found that EC-specific loss of the glycolytic regulator pfkfb3 reduced ischemic hindlimb revascularization and impaired muscle regeneration. This was caused by the reduced ability of macrophages to adopt a proangiogenic and proregenerative M2-like phenotype. Mechanistically, loss of pfkfb3 reduced lactate secretion by ECs and lowered lactate levels in the ischemic muscle. Addition of lactate to pfkfb3-deficient ECs restored M2-like polarization in an MCT1-dependent fashion. Lactate shuttling by ECs enabled macrophages to promote proliferation and fusion of muscle progenitors. Moreover, VEGF production by lactate-polarized macrophages was increased, resulting in a positive feedback loop that further stimulated angiogenesis. Finally, increasing lactate levels during ischemia rescued macrophage polarization and improved muscle reperfusion and regeneration, whereas macrophage-specific mct1 deletion prevented M2-like polarization. In summary, ECs exploit glycolysis for angiocrine lactate shuttling to steer muscle regeneration from ischemia.

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