#2069 Elucidating the function of novel Arg1+/Clec4d+ scar-associated monocyte-derived macrophage population in driving fibrosis in kidney disease models

Abstract

Abstract Background and Aims Fibrosis is the final common pathway in all progressive kidney disease. Macrophages are a major myeloid cell component of the renal mononuclear phagocyte system, with roles in defence against infection, renal injury, and repair. Using single-cell RNA sequencing, we identified a novel myeloid cell subset exclusively present in acute injury of the unilateral ureteric obstruction (UUO) model of kidney fibrosis. This population transcriptomically aligns to monocytes but is enriched for both Arginase-1 (Arg1) and the C-type lectin 4d (Clec4d) and a large number of pro-inflammatory and pro-fibrotic genes. We hypothesise that this novel Arg1+/Clec4d+ population contributes to fibrosis deposition in progressive kidney disease. Methods Monocyte-macrophage populations were characterised in different pre-clinical models; UUO, unilateral ischaemic reperfusion injury (uIRI) and subtotal nephrectomy with flow cytometry. Arg1+/Clec4d+ cells were identified by RT-qPCR, flow cytometry, and immunofluorescence. The origin and consequence of Arg1 deletion in monocytes on renal fibrosis was determined by utilising Ccr2-ERT2-TdTomato and Ccr2-ERT2-TdTomato; Arg1 fl/fl mice, respectively. Results The presence of the Arg1+/Clec4d+ cells was validated in the UUO, uIRI and subtotal nephrectomy models of kidney injury. Analysis of intra-renal inflammation revealed CD45+CD11b+Arg1+ cells persisted and increased in number across 7 days. Post-injury, Arg1+ cells were confirmed to be Clec4dhi. To confirm that Arg1+/Clec4d+ cells were derived from monocytes (Ccr2+), we administered tamoxifen to Ccr2CreERT2-TdTomato mice under a single or multiple-dose regimen following UUO surgery. At day 7 post-injury, ∼50% and ∼90% of the Arg1+ cells were TdTomato+ following a single or multiple doses of tamoxifen, respectively, suggesting that these cells are primarily monocyte derived. Moreover, the Arg1+/Clec4d+ cells were found to localise to areas of scarring (Fig. 1). To investigate the therapeutic potential of targeting Clec4d+ expressed on the Arg1+/Clec4d+ macrophages, mice underwent UUO surgery and given multiple doses of a Clec4d-neutralising antibody. A decrease in Arg1 and fibrosis-related gene expression was evident by day 7 post-injury. To understand the role of increased Arg1 expression in the cells we generated Ccr2-ERT2-TdTomato; Arg1 fl/fl mice. These mice had as expected a reduced Arg1 expression in the Ccr2+ population and metabolic profiling by SCENITH of the tissue monocytes revealed that the loss of Arg1 in the cells reduced their glucose dependence. The loss of Arg1 in these cells reduced Havcr1 gene expression in the kidney. Conclusion As fibrosis is a pathological process that can affect any organ, the work included here, in addition to the proposed future studies, has the potential to develop novel therapeutics that limit fibrosis and enhance repair to halt the progression of disease in CKD.