Abstract
During the development of urinary stone disease, the formation of tiny crystals that adhere to the renal tubular epithelium induces epithelial cell damage. This damage and repair of the epithelium is associated with the establishment of more crystal adhesion sites, which in turn stimulates further crystal adhesion and, eventually, stone formation. Deposited crystals typically cause changes in epithelial cell gene expression, such as transcriptome changes and alternative splicing events. Although considered important for regulating gene expression, alternative splicing has not been reported in studies related to kidney stones. To date, whether alternative splicing events are involved in the regulation of stone formation and whether crystallographic cell interactions are regulated by alternative splicing at the transcriptional level have remained unknown. Therefore, we conducted RNA sequencing and alternative splicing-related bioassays by modeling the in vitro stone environment. Many alternative splicing events were associated with crystallographic cell interactions. Moreover, these events regulated transcription and significantly affected the capacity of crystals to adhere to renal tubular epithelial cells and regulate apoptosis.
Highlights
The incidence of renal stone disease has more than doubled in the past 40 years, with between 7 and 11% of the population at risk of kidney stone-related symptoms each year [1]
Analysis of differentially expressed genes (DEGs) in calcium oxalate stone nanocrystaltreated renal tubular epithelial cells compared with control cells revealed significant alterations in gene expression
The results of Gene Ontology (GO) and KEGG enrichment analyses revealed that most DEGs were associated with cell adhesion, inflammatory responses, inflammatory mediator secretion and other processes (Figs. 1 and 2) as well as with human autoimmune diseases such as systemic lupus erythematosus and rheumatoid arthritis
Summary
The incidence of renal stone disease has more than doubled in the past 40 years, with between 7 and 11% of the population at risk of kidney stone-related symptoms each year [1]. The formation of urinary stones involves several microscopic processes, such as crystal formation, adhesion and growth [2]. During these processes, renal tubular epithelial cells closely interact with adherent crystals, which affect cell adhesion, apoptosis, and inflammatory responses [3,4,5]. Renal tubular epithelial cells closely interact with adherent crystals, which affect cell adhesion, apoptosis, and inflammatory responses [3,4,5] These interactions play important roles in the eventual formation of stones.
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