Abstract
BACKGROUND. In human lupus nephritis (LuN), tubulointerstitial inflammation (TII) is prognostically more important than glomerular inflammation. However, a comprehensive understanding of both TII complexity and heterogeneity is lacking. METHODS. Herein, we used high-dimensional confocal microscopy, spatial transcriptomics and specialized computer vision techniques to quantify immune cell populations and localize these within normal and diseased renal cortex structures. With these tools, we compared LuN to renal allograft rejection (RAR) and normal kidney on 54 de-identified biopsies. RESULTS. In both LuN and RAR, the 33 characterized immune cell populations formed discrete subgroups whose constituents co-varied in prevalence across biopsies. In both diseases, these co-variant immune cell subgroups organized into the same unique niches. Therefore, inflammation could be resolved into trajectories representing the relative prevalence and density of cardinal immune cell members of each co-variant subgroup. Indeed, in any one biopsy, the inflammatory state could be characterized by quantifying constituent immune cell trajectories. Remarkably, LuN heterogeneity could be captured by quantifying a few myeloid immune cell trajectories while RAR was more complex with additional T cell trajectories. CONCLUSIONS. Our studies identify rules governing renal inflammation and thus provide an approach for resolving LuN into discrete mechanistic categories. FUNDING. NIH (U19 AI 082724 [MRC], R01 AI148705 [MRC and ASC]), Chan Zuckerberg Biohub (MRC) and Lupus Research Alliance (MRC)
Authors
Gabriel Casella, Madeleine S. Torcasso, Junting Ai, Thao P. Cao, Satoshi Hara, Michael S. Andrade, Deepjyoti Ghosh, Daming Shao, Anthony Chang, Kichul Ko, Anita S. Chong, Maryellen L. Giger, Marcus R. Clark
Graphical abstract
Copyright © 2025 American Society for Clinical Investigation
ISSN: 0021-9738 (print), 1558-8238 (online)