Monocyte control of organismal energy homeostasis

Multicellular organisms rely on inter-organ communication networks to maintain vital parameters within a dynamic physiological range. Macrophages are central to this homeostatic control system, sensing deviations of those parameters and responding accordingly to support tissue function and organismal homeostasis. Here we demonstrate that dysregulation of iron metabolism in parenchyma cells, imposed by the deletion of ferritin H chain, is sensed by monocyte-derived macrophages. In response, macrophages derived from circulating monocytes support tissue function, energy metabolism and thermoregulation, as demonstrated in bone marrow chimeric and parabiotic mice. This salutary effect is contingent on a transcriptional program, controlled in macrophages by the transcription factor A mitochondria. This transcriptional response acts in a non-cell autonomous manner to support the mitochondria of parenchyma cells, irrespectively of mitochondrial transfer. In conclusion, monocyte-derived macrophages cross-regulate Fe and energy metabolism to support tissue function and organismal homeostasis.