Beyond the Cell Atlas: Functional Communities as the Essential Pathologic Units Driving Kidney Disease.

Kidney disease represents a growing global health crisis, demanding a deeper understanding of its underlying pathophysiology. Current mechanistic efforts are often focused on discrete cell states identified by single-cell sequencing, which remains the standard for characterizing the human kidney. Crucially, these molecular atlases fail to explain how individual cell states organize and interact in specific spatial contexts to drive collective, systems-level organ failure. This Review introduces the conceptual and clinical utility of "functional communities"-spatially constrained, interacting multicellular neighborhoods-as the definitive pathologic units of kidney disease. We first outline recent advances in spatial and multiomic technologies that are essential for resolving the composition and communication networks of these communities in situ . This is followed by a deconstruction of three archetypal pathologic communities: the maladaptive repair niche linked to chronic injury, the profibrotic niche driven by specific fibroblast subtypes, and the tissue-destructive immune niche. Moreover, by integrating artificial intelligence and multiomics data, it is possible to build virtual models capable of simulating and predicting dynamic intercellular interactions in kidney diseases. Finally, we discuss key challenges and future directions for translating this community-centric view into novel diagnostics and therapeutics. This framework offers a robust, integrated strategy for identifying vulnerable microenvironments, thereby guiding the development of next-generation diagnostics and targeted therapeutic interventions.