NAD+ prevents chronic kidney disease by activating renal tubular metabolism
Bryce A. Jones, Debora L. Gisch, Komuraiah Myakala, Amber Sadiq, Ying-Hua Cheng, Elizaveta Taranenko, Julia Panov, Kyle Korolowicz, Ricardo Melo Ferreira, Xiaoping Yang, Briana A. Santo, Katherine C. Allen, Teruhiko Yoshida, Xiaoxin X. Wang, Avi Z. Rosenberg, Sanjay Jain, Michael T. Eadon, Moshe Levi
Bryce A. Jones, Debora L. Gisch, Komuraiah Myakala, Amber Sadiq, Ying-Hua Cheng, Elizaveta Taranenko, Julia Panov, Kyle Korolowicz, Ricardo Melo Ferreira, Xiaoping Yang, Briana A. Santo, Katherine C. Allen, Teruhiko Yoshida, Xiaoxin X. Wang, Avi Z. Rosenberg, Sanjay Jain, Michael T. Eadon, Moshe Levi
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Research Article Nephrology

NAD+ prevents chronic kidney disease by activating renal tubular metabolism

Abstract

Chronic kidney disease (CKD) is associated with renal metabolic disturbances, including impaired fatty acid oxidation (FAO). Nicotinamide adenine dinucleotide (NAD+) is a small molecule that participates in hundreds of metabolism-related reactions. NAD+ levels are decreased in CKD, and NAD+ supplementation is protective. However, both the mechanism of how NAD+ supplementation protects from CKD, as well as the cell types involved, are poorly understood. Using a mouse model of Alport syndrome, we show that nicotinamide riboside (NR), an NAD+ precursor, stimulated renal PPARĪ± signaling and restored FAO in the proximal tubules, thereby protecting from CKD in both sexes. Bulk RNA-sequencing showed that renal metabolic pathways were impaired in Alport mice and activated by NR in both sexes. These transcriptional changes were confirmed by orthogonal imaging techniques and biochemical assays. Single-nuclei RNA sequencing and spatial transcriptomics, both the first of their kind to our knowledge from Alport mice, showed that NAD+ supplementation restored FAO in proximal tubule cells. Finally, we also report, for the first time to our knowledge, sex differences at the transcriptional level in this Alport model. In summary, the data herein identify a nephroprotective mechanism of NAD+ supplementation in CKD, and they demonstrate that this benefit localizes to the proximal tubule cells.

Authors

Bryce A. Jones, Debora L. Gisch, Komuraiah Myakala, Amber Sadiq, Ying-Hua Cheng, Elizaveta Taranenko, Julia Panov, Kyle Korolowicz, Ricardo Melo Ferreira, Xiaoping Yang, Briana A. Santo, Katherine C. Allen, Teruhiko Yoshida, Xiaoxin X. Wang, Avi Z. Rosenberg, Sanjay Jain, Michael T. Eadon, Moshe Levi

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Figure 7

snRNA-Seq of control and Alport mice, with and without NAD+ supplementation.

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snRNA-Seq of control and Alport mice, with and without NAD+ supplementat...
(A) The snRNA-Seq reduction by UMAP of 49,488 nuclei in 30 clusters. (B) Proportion of nuclei per cluster by condition. Myofibroblasts and immune cells were upregulated in Alport mice. The effect was mitigated by NR treatment. (C) Differentially expressed genes in proximal tubule cells (PT_S1/S2) of NR-treated Alport mice (vs. vehicle-treated Alport mice). Mice treated with NR had reduced expression of immune signaling transcripts and increased expression of metabolism-related genes (e.g., Acot1, Ehhadh, and Insig1). (D) Enriched pathways between NR-treated Alport mice and vehicle-treated Alport mice in the proximal tubule cell. NR treatment significantly impacted translation (ribosome), metabolism, endocrine function, and PPAR signaling in the proximal tubule cell. Ctrl, control; NAD+, nicotinamide adenine dinucleotide; NR, nicotinamide riboside; UMAP, uniform manifold approximation and projection; Veh, vehicle. aPT, adaptive proximal tubules; B, B cell; CIC, cortical intercalated cells; CNT, connecting tubule; DCT, distal convoluted tubule; DendriC, dendritic cell; EC_1, endothelial cells 1; EC_2, endothelial cells 2; EC_Cycl, endothelial cells cycling; iDN, injury distal nephron; IMCL, intramedullary collecting cells; iPT, injury proximal tubules; MIC, medullary intercalated cells; MP_LP_1, macrophage or lymphocyte cells 1; MP_LP_2, macrophage or lymphocyte cells 2; NK_T, natural killer or T cell; PapEpi, papillary epithelial cells; PC, principal cell; POD, podocyte; PT_S1, proximal tubules segment 1; PT_S2, proximal tubules segment 2 cells; PT_S3, proximal tubules segment 3 cells 1; rDCT, regenerative distal convoluted tubule; sTAL, stressed thick ascending limb; STR_1, stromal cell 1; STR_2, stromal cell 2; STR_3, stromal cell 3; STR_4, stromal cell 4; TAL, thick ascending limb.