Characterization of ROMK cellular heterogeneity along the mouse kidney thick ascending limb

Abstract

The renal thick ascending limb (TAL) plays a key role in water and ion homeostasis. Apical potassium secretion via the renal outer medullary potassium channel (ROMK) is essential for transepithelial sodium reabsorption via the furosemide-sensitive Na-K-2Cl-cotransporter and creates the electrochemical gradient for paracellular ion transport through Claudin tight junction proteins. Interestingly, the TAL exhibits transcriptomic heterogeneity and variable apical ROMK abundance. Single-cell RNA sequencing suggests that the cortical TAL consists of at least three distinct cell types, but whether ROMK distribution aligns with these types remains unclear. We analyzed perfusion-fixed mouse kidneys using RNAscope in situ hybridization (ISH), iterative indirect immunofluorescence imaging (4i multiplexing), and machine learning. ROMK mRNA expression was seen in all TAL cells. In contrast, apical ROMK protein abundance was found on almost all macula densa (MD) cells but was heterogeneous along the rest of the TAL. In the remaining TAL, only about 60% of the TAL cells had strong apical ROMK staining, while 40% lacked apical ROMK but showed weak perinuclear signals. ISH revealed that apical ROMK-positive cells express Ptger3 mRNA, whereas apical ROMK-negative cells express Foxq1 mRNA. Multiplexing analysis showed that ROMK-positive cells form Claudin-10b-positive tight junctions, while ROMK-negative cells form Claudin-16/19-positive junctions and express basolateral Kir4.1. Despite universal ROMK mRNA expression, apical ROMK distribution aligns with molecularly distinct TAL cell types. This unique ROMK expression pattern suggests functional heterogeneity for ROMK along the TAL.