Macrophage skewing by Phd2 haplodeficiency prevents ischaemia by inducing arteriogenesis

PHD2 serves as an oxygen sensor that rescues blood supply by regulating vessel formation and shape in case of oxygen shortage. However, it is unknown whether PHD2 can influence arteriogenesis. Here we studied the role of PHD2 in collateral artery growth by using hindlimb ischaemia as a model, a process that compensates for the lack of blood flow in case of major arterial occlusion. We show that Phd2 (also known as Egln1) haplodeficient (Phd2(+/-)) mice displayed preformed collateral arteries that preserved limb perfusion and prevented tissue necrosis in ischaemia. Improved arteriogenesis in Phd2(+/-) mice was due to an expansion of tissue-resident, M2-like macrophages and their increased release of arteriogenic factors, leading to enhanced smooth muscle cell (SMC) recruitment and growth. Both chronic and acute deletion of one Phd2 allele in macrophages was sufficient to skew their polarization towards a pro-arteriogenic phenotype. Mechanistically, collateral vessel preconditioning relied on the activation of canonical NF-κB pathway in Phd2(+/-) macrophages. These results unravel how PHD2 regulates arteriogenesis and artery homeostasis by controlling a specific differentiation state in macrophages and suggest new treatment options for ischaemic disorders.     

Surface expression of MHC class II in dendritic cells is controlled by regulated ubiquitination

Dendritic cells have a unique function in the immune response owing to their ability to stimulate immunologically naive T lymphocytes. In response to microbial and inflammatory stimuli, dendritic cells enhance their capacity for antigen presentation by a process of terminal differentiation, termed maturation. The conversion of immature to mature dendritic cells is accompanied by a marked cellular reorganization, including the redistribution of major histocompatibility complex class II molecules (MHC II) from late endosomal and lysosomal compartments to the plasma membrane and the downregulation of some forms of endocytosis, which has been thought to slow the clearance of MHC II from the surface. The relative extent to which these or other mechanisms contribute to the regulation of surface MHC II remains unclear, however. Here we find that the MHC II beta-chain cytoplasmic tail is ubiquitinated in mouse immature dendritic cells. Although only partly required for the sequestration of MHC II in multivesicular bodies, this modification is essential for endocytosis. Notably, ubiquitination of MHC II ceased upon maturation, resulting in the accumulation of MHC II at the cell surface. Dendritic cells thus exhibit a unique ability to regulate MHC II surface expression by selectively controlling MHC II ubiquitination.