Sterile inflammation after injury is important for tissue restoration. In injured human and mouse tissues, macrophages were recently found to accumulate perivascularly. This study investigates if macrophages adopt a mural cell phenotype important for restoration after ischemic injury. Single-cell RNA sequencing of fate-mapped macrophages from ischemic mouse muscles demonstrates a macrophage-toward-mural cell switch of a subpopulation of macrophages with downregulated myeloid cell genes and upregulated mural cell genes, including PDGFRβ. This observation was further strengthened when including unspliced transcripts in the analysis. The macrophage switch was proven functionally relevant, as induction of macrophage-specific PDGFRβ deficiency prevented their perivascular macrophage phenotype, impaired vessel maturation and increased vessel leakiness, which ultimately reduced limb function. In conclusion, macrophages in adult ischemic tissue were demonstrated to undergo a cellular program to morphologically, transcriptomically and functionally resemble mural cells while weakening their macrophage identity. The macrophage-to-mural cell-like phenotypic switch is crucial for restoring tissue function and warrants further exploration as a potential target for immunotherapies to enhance healing.
© 2024. The Author(s).

Urinary tract infections (UTIs) in men are uncommon but carry increased risk for severe pyelonephritis and other complications. In models of Escherichia coli UTI, male C3H/HeN mice uniformly develop high-titer pyelonephritis (most with renal abscesses) in a testosterone-dependent manner, but the mechanisms underlying this phenotype are unknown. Here, using female mouse models, we show that androgen exposure impairs neutrophil maturation in the upper and lower urinary tract, compounded by an additional reduction of neutrophil function specifically within the infected kidney, enabling persistent high-titer infection and promoting abscess formation. Following intravesical inoculation with uropathogenic E. coli (UPEC), kidneys of androgen-exposed C3H mice showed delayed local pro-inflammatory cytokine responses while robustly recruiting neutrophils. These were enriched for an end-organ-specific population of aged but immature neutrophils (CD49d+, CD101–). Compared to their mature counterparts, these aged immature kidney neutrophils exhibited reduced functions in vitro , including impaired degranulation and diminished phagocytic activity, while splenic, bone marrow, and bladder neutrophils did not display these alterations. Further, aged immature neutrophils exhibited little phagocytic activity within intratubular UPEC communities in vivo . Experiments with B6 conditional androgen receptor (AR)-deficient mice indicated rescue of the maturation defect when AR was deleted in myeloid cells. We conclude that the recognized enhancement of UTI severity by androgens reflects urinary tract-specific impairment of neutrophil maturation (largely via cell-intrinsic AR signaling) and kidney-specific reduction in neutrophil antimicrobial capacity, resulting in failure to control renal bacterial infection.

Alterations to organ biology caused by transplantation can have major impacts on the outcome. Tissue-resident lymphocytes normally maintain an organ's immunity and function and are transferred during transplantation. Here, we provide a detailed protocol for the isolation of leukocytes, including tissue-resident lymphocytes, from transplanted livers and hearts in mice. Phenotypic and functional analysis of conventional and unconventional T cells by flow cytometry is included. This protocol can also be used for the effective isolation of leukocytes from non-transplanted livers and hearts. For complete details on the use and execution of this protocol, please refer to Prosser et al. (2021).
© 2021 The Authors.