Molecular Studies on Calcium Oxalate Kidney Stones: A Window into the Pathogenesis of Nephrolithiasis

Abstract

Nephrolithiasis will affect one-in-eleven people, and more than half of those individuals will have stone recurrence within a decade of their first episode. Despite decades of biomedical research on nephrolithiasis and extraordinary advances in molecular and cell biology, the precise mechanisms of kidney stone formation are not fully understood. Currently, there are limited treatments or preventative measures for nephrolithiasis. Therefore, it is crucial to scrutinize kidney stones from a molecular and cell biology perspective to better understand its pathogenesis and pathophysiology; and to, hereafter, contribute to effective therapeutic targets and preventative strategies. Kidney stones are composed of an admixture of crystal aggregated material and an organic matrix. 80% of all kidney stones are composed of calcium oxalate (CaOx) and half of all CaOx patients grow their stones on to Randall’s plaques (RP). RP are interstitial calcium phosphate mineral deposits in the renal papilla. Thus, we developed and optimized methodologies to directly interrogate CaOx stones. CaOx stones were demineralized, sectioned, and imaged by microscopy, utilizing micro CT for precise orientation. Laser microdissection (LMD) of specific regions of stone matrix analyzed by proteomics revealed various proteins involved in inflammation and the immune response. Analyses on jackstone calculi, having arm protrusions that extend out from the body of the stone, revealed that they are a rare subtype of CaOx stone formation. Micro CT analyses on 98 jackstones showed a radiolucent, organic-rich core in the arm protrusions. Fluorescence imaging on RP stones showed consistent differences in autofluorescence patterns between RP and CaOx overgrowth regions. Moreover, cell nuclei were discovered with preserved morphology in RP regions, along with variable expressions of vimentin and CD45. In comparing spatial transcriptomic expression of reference and CaOx kidney papillae, CaOx patients differentially expressed genes associated with pathways of immune cell activation, reactive oxygen damage and injury, extracellular remodeling, and ossification. Our findings provide novel methodologies to better understand the role of molecules and cells in CaOx stone matrix. Several of the proteins and cells identified in these studies may serve as potential biomarkers, and future therapeutic targets in preventing kidney stone disease.