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NF-κB–driven lymphangiogenesis affects kidney function via a VEGFR-3–mediated pathway
Arin L. Melkonian, Amie M. Traylor, Anna A. Zmijewska, Kyle H. Moore, Gelare Ghajar-Rahimi, Stephanie Esman, Yanlin Jiang, Hani Jang, Babak J. Mehrara, Timmy C. Lee, James F. George, Anupam Agarwal
Arin L. Melkonian, Amie M. Traylor, Anna A. Zmijewska, Kyle H. Moore, Gelare Ghajar-Rahimi, Stephanie Esman, Yanlin Jiang, Hani Jang, Babak J. Mehrara, Timmy C. Lee, James F. George, Anupam Agarwal
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Research Article Cell biology Nephrology

NF-κB–driven lymphangiogenesis affects kidney function via a VEGFR-3–mediated pathway

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Abstract

The lymphatic system maintains fluid homeostasis and orchestrates immune cell trafficking throughout tissues. While extensively studied in cancer and lymphedema, its role in nonlymphoid organs, particularly the kidney, remains an emerging area of investigation. Previous research established molecular connections among NF-κB, VEGFR-3, and PROX-1 in regulating lymphatic growth during inflammation, and studies using global knockout mice revealed that the NF-κB1 subunit (p50) influences lymphatic vessel density. However, the role of RelA — a key component of the canonical NF-κB heterodimer — in regulating lymphatic growth and kidney function following acute kidney injury (AKI) remains unexplored. Using an inducible, predominantly lymphatic endothelial cell-specific RelA-knockout mouse model, we demonstrated that RelA expression in VEGFR-3+ cells is essential for VEGFR-3–driven lymphangiogenesis following AKI. Knockout mice exhibited substantially worse kidney function, altered histological features, impaired VEGFR-3–dependent lymphangiogenesis, and dysregulated immune cell trafficking compared with WT mice. Compensatory upregulation of PROX-1 and podoplanin occurred despite decreased VEGFR-3 and LYVE-1 total protein expression, suggesting complex regulatory mechanisms. Our findings suggest that RelA is a critical sensor for inflammation and regulator of protective lymphangiogenesis following kidney injury and provide insights into potential therapeutic targets for improved kidney injury outcomes.

Authors

Arin L. Melkonian, Amie M. Traylor, Anna A. Zmijewska, Kyle H. Moore, Gelare Ghajar-Rahimi, Stephanie Esman, Yanlin Jiang, Hani Jang, Babak J. Mehrara, Timmy C. Lee, James F. George, Anupam Agarwal

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Figure 6

Visualization and quantification of lymphatic vessel features in VEGFR-3–specific RelA-deficient mice compared with floxed controls.

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Visualization and quantification of lymphatic vessel features in VEGFR-3...
(A) Representative confocal microscopy images (maximum intensity projections) of quarter kidney sections immunolabeled for VEGFR-3 (green, Alexa 647) and LYVE-1 (red, Alexa 594). Images compare VEGFR-3–specific RelA-deficient mice to floxed controls under baseline conditions and after cisplatin-induced AKI. 10× objective. (B and C) Quantitative analysis of lymphatic vessel morphology for (B) VEGFR-3+ and (C) LYVE-1+ vessels. Measured parameters include branch point density, total filament volume (μm3), and total filament length (μm). Analysis was performed using Imaris Filaments module following image processing (denoising, deconvolution, thresholding). All measurements were normalized to imaging volume based on image field dimensions: x axis (2,038 pixels), y axis (2,038 pixels), and z axis (section thickness in μm), with a pixel size of 1.24 μm/pixel (WT control, N = 3; KO control, N = 3; WT cisplatin, N = 4; KO cisplatin, N = 5). WT, RelAfl/fl; KO, VEGFR-3RelA–/–.

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