mTOR-mediated podocyte hypertrophy regulates glomerular integrity in mice and humans
Victor G. Puelles, … , David J. Nikolic-Paterson, John F. Bertram
Victor G. Puelles, … , David J. Nikolic-Paterson, John F. Bertram
Published September 19, 2019
Citation Information: JCI Insight. 2019;4(18):e99271. https://doi.org/10.1172/jci.insight.99271.
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Research Article Cell biology Nephrology

mTOR-mediated podocyte hypertrophy regulates glomerular integrity in mice and humans

Abstract

The cellular origins of glomerulosclerosis involve activation of parietal epithelial cells (PECs) and progressive podocyte depletion. While mammalian target of rapamycin–mediated (mTOR-mediated) podocyte hypertrophy is recognized as an important signaling pathway in the context of glomerular disease, the role of podocyte hypertrophy as a compensatory mechanism preventing PEC activation and glomerulosclerosis remains poorly understood. In this study, we show that glomerular mTOR and PEC activation–related genes were both upregulated and intercorrelated in biopsies from patients with focal segmental glomerulosclerosis (FSGS) and diabetic nephropathy, suggesting both compensatory and pathological roles. Advanced morphometric analyses in murine and human tissues identified podocyte hypertrophy as a compensatory mechanism aiming to regulate glomerular functional integrity in response to somatic growth, podocyte depletion, and even glomerulosclerosis — all of this in the absence of detectable podocyte regeneration. In mice, pharmacological inhibition of mTOR signaling during acute podocyte loss impaired hypertrophy of remaining podocytes, resulting in unexpected albuminuria, PEC activation, and glomerulosclerosis. Exacerbated and persistent podocyte hypertrophy enabled a vicious cycle of podocyte loss and PEC activation, suggesting a limit to its beneficial effects. In summary, our data highlight a critical protective role of mTOR-mediated podocyte hypertrophy following podocyte loss in order to preserve glomerular integrity, preventing PEC activation and glomerulosclerosis.

Authors

Victor G. Puelles, James W. van der Wolde, Nicola Wanner, Markus W. Scheppach, Luise A. Cullen-McEwen, Tillmann Bork, Maja T. Lindenmeyer, Lukas Gernhold, Milagros N. Wong, Fabian Braun, Clemens D. Cohen, Michelle M. Kett, Christoph Kuppe, Rafael Kramann, Turgay Saritas, Claudia R. van Roeyen, Marcus J. Moeller, Leon Tribolet, Richard Rebello, Yu B.Y. Sun, Jinhua Li, Gerhard Müller-Newen, Michael D. Hughson, Wendy E. Hoy, Fermin Person, Thorsten Wiech, Sharon D. Ricardo, Peter G. Kerr, Kate M. Denton, Luc Furic, Tobias B. Huber, David J. Nikolic-Paterson, John F. Bertram

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Figure 5

mTOR-mediated podocyte hypertrophy in diabetic mice and humans.

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mTOR-mediated podocyte hypertrophy in diabetic mice and humans. (A) Tran...
(A) Transcriptional regulation of mTOR signaling in glomerular extracts from human biopsies. Comparison between diabetic nephropathy (DN; n = 14) vs. living donors (n = 42), showing fold-change of each respective gene (q < 0.05 in all genes except those with NS), and representative confocal image from indirect immunofluorescence showing a podocyte specific marker (Wilms’ Tumor 1; WT-1) and a downstream target of mTORC1 (phosphorylated ribosomal protein S6; p-rp-S6) in a glomerulus from a patient with DN. Scale bar: 10 μm. (B) Transcriptional regulation of PEC activation–related genes in glomerular extracts from human biopsies. Comparison between DN (n = 14) vs. living donors (n = 42), showing fold-change of each respective gene (q < 0.05 in all genes except those with NS) and representative confocal image of PEC activation marker CD44 (green) and PEC specific marker Annexin 3 (ANXA3; red). Scale bars: 10 μm. (C) Correlation analysis of regulated mTOR signaling and PEC activation genes. Each box represents an independent association (spearman correlation; R). Every association was statistically significant unless labeled with NS. (D) Schematic representation of experimental design for a hyperglycemic model via streptozotocin (STZ) injection with subsequent injection of diphtheria toxin (DT) to induce selective podocyte loss. (E) Fasting plasma glucose. (F) Kidney weight. (G) Periodic acid–Schiff (PAS) stainings showing development of glomerular lesions only after DT injection. (H) De novo PEC activation (CD44 upregulation; green). (I) Podocyte number. (J) Representative confocal image showing upregulation of mTORC1 signaling in podocytes after podocyte loss. (K) Podocyte density. (L) Total podocyte volume by unit of podocyte density (TPV:PD ratio). ****P < 0.0001; ***P < 0.001; *P < 0.05. In E and F, bars represent means and error bars ± SEMs. Each dot represents 1 mouse. In violin plots, red lines represent medians and blue lines represent IQRs; every gray dot represents 1 glomerulus. Kruskal-Wallis with Dunn’s multiple comparisons tests were used. Scale bars: (G) 50 μm, and (H and J) 100 μm.