Significance How blood stem cells within the bone marrow respond to infection is still unclear. Here we study if mitochondrial transfer from the stromal cells to blood stem cells is required for the rapid generation of leukocytes which are required for the immune system to respond to bacterial infection. We find that mitochondria are transferred to blood stem cells within 2 h of sensing infection and show that direct contact between stromal cells and blood stem cells is required for mitochondrial transfer to occur. The metabolic changes that follow mitochondrial transfer into hematopoietic stem cells underpin the rapid mammalian response to infection. Finally, we find that, if mitochondrial transfer is blocked, an increase in bacterial colonization in the mammalian system occurs.
Hematopoietic stem cells (HSCs) undergo rapid expansion in response to stress stimuli. Here we investigate the bioenergetic processes which facilitate the HSC expansion in response to infection. We find that infection by Gram-negative bacteria drives an increase in mitochondrial mass in mammalian HSCs, which results in a metabolic transition from glycolysis toward oxidative phosphorylation. The initial increase in mitochondrial mass occurs as a result of mitochondrial transfer from the bone marrow stromal cells (BMSCs) to HSCs through a reactive oxygen species (ROS)-dependent mechanism. Mechanistically, ROS-induced oxidative stress regulates the opening of connexin channels in a system mediated by phosphoinositide 3-kinase (PI3K) activation, which allows the mitochondria to transfer from BMSCs into HSCs. Moreover, mitochondria transfer from BMSCs into HSCs, in the response to bacterial infection, occurs before the HSCs activate their own transcriptional program for mitochondrial biogenesis. Our discovery demonstrates that mitochondrial transfer from the bone marrow microenvironment to HSCs is an early physiologic event in the mammalian response to acute bacterial infection and results in bioenergetic changes which underpin emergency granulopoiesis.