Author’s Reply: The Subcellular Localization of RRAGD

• RagD
• RRAGD
• immunohistochemistry
• distal convoluted tubule
• thick ascending limb

We thank Ma et al. for their interest in our recent report, which identified mutations in RRAGD as a cause for kidney tubulopathy and dilated cardiomyopathy.¹ In their letter, Ma et al. report RagD staining in the nucleus of tubular epithelial cells. As the authors correctly note, the RagD staining in our manuscript is predominantly located in the cytoplasm of epithelial cells in the thick ascending limb of the loop of Henle (TAL) and the distal convoluted tubule (DCT) segments of the kidney.¹ Our findings are in line with mRNA expression data from the mouse and the rat nephron, and human single-cell RNA sequencing data which demonstrate high expression in these segments. ²⇓^–4

Our manuscript reports immunohistochemistry of mouse kidney tissue because we have good segmental markers against mouse proteins available and the tissue can be better fixated due to perfusions. However, we have also analyzed human kidney cortex samples, which confirm the mouse stainings. In these human kidney sections, RagD expression is observed predominantly in the cytoplasm (Figure 1).

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Figure 1.

RagD is expressed in the cytoplasm of the distal convoluted tubule. Serial sections (as notified by the asterisk located in the same renal tubule) of human kidney were incubated with primary antibodies against (A) RagD or (B) uromodulin. The RagD protein was detected in uromodulin-positive the thick ascending limb of the loop of Henle (*). No significant signal was observed in the proximal tubule (p) or the glomerulus (g). Scale bar, 50 μm.

Indeed, the Rag GTPase complex is extensively described as a cytoplasmic nutrient sensor, where it resides at the lysosomal membrane and detects leucine and arginine amino acids.⁵ Upon amino acid binding, the Rag complex recruits mammalian target of rapamycin (mTOR) to the lysosomal membrane and activates the mTOR signaling pathway.⁶ Although cytoplasmic localization is, therefore, expected, there are reports of nuclear translocation of Rag proteins via the nuclear pore complex.⁷ In HEK293 cells, it has been demonstrated that RagC requires nuclear passage to fully activate mTOR signaling.⁷ Moreover, the metformin analogue phenformin could prevent this nuclear translocation, suggesting intracellular signaling pathways may determine the nuclear versus cytoplasmic expression of Rag proteins. Consequently, differences in subcellular Rag expression may be explained by the metabolic status of the assessed kidney tissue. Therefore, the interesting observation of Ma et al. spikes an interest in further investigations of metabolic regulation of the Rag complex in the kidney.

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