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Longitudinal multiorgan transcriptomic atlas of salt-induced hypertension
Ratnakar Tiwari, Olha Kravtsova, Lashodya V. Dissanayake, Melissa Lowe, Biyang Xu, Vladislav Levchenko, Steven Didik, Ruslan Bohovyk, Daria V. Ilatovskaya, Oleg Palygin, Alexander Staruschenko
Ratnakar Tiwari, Olha Kravtsova, Lashodya V. Dissanayake, Melissa Lowe, Biyang Xu, Vladislav Levchenko, Steven Didik, Ruslan Bohovyk, Daria V. Ilatovskaya, Oleg Palygin, Alexander Staruschenko
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Research Article Inflammation Metabolism Nephrology

Longitudinal multiorgan transcriptomic atlas of salt-induced hypertension

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Abstract

High dietary salt intake elevates blood pressure and drives multiorgan damage. However, the molecular programs underlying progressive organ injury remain poorly defined. Here, we present a longitudinal multiorgan transcriptomic atlas of salt-induced hypertensive injury. We profiled kidney cortex, kidney medulla, heart, and liver across 4 stages, spanning early hypertension to advanced pathology in Dahl salt-sensitive rats. We identified dynamic and tissue-specific molecular trajectories, including a shared early proliferative response that converges on proinflammatory and fibrotic remodeling. Notably, we uncovered compartment-specific renal responses, showing that the cortex and medulla, despite their proximity, follow distinct molecular trajectories during disease progression. We further identified 79 stage- and tissue-specific transcription factors that drive gene expression dynamics in salt-induced hypertensive injury. Integration with human genome-wide association studies revealed conserved pathways in endocrine signaling, ion transport, lipid metabolism, and detoxification, establishing cross-species relevance and highlighting mechanistic targets of clinical importance. Compound-transcriptome analysis revealed stage- and organ-specific therapeutic opportunities, prioritizing kinase and epigenetic modulators as candidates to rebalance maladaptive gene programs. Overall, this study provides a resource for understanding molecular mechanisms from early salt-induced hypertension to tissue-specific injury and underscores the need for precision interventions.

Authors

Ratnakar Tiwari, Olha Kravtsova, Lashodya V. Dissanayake, Melissa Lowe, Biyang Xu, Vladislav Levchenko, Steven Didik, Ruslan Bohovyk, Daria V. Ilatovskaya, Oleg Palygin, Alexander Staruschenko

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Figure 2

High-salt diet–induced hypertension dynamically regulates biological pathway activity across organs.

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High-salt diet–induced hypertension dynamically regulates biological pat...
(A) Mean pathway activity heatmap of 50 Hallmark pathways across cortex, medulla, heart, and liver at days 7, 14, 21, and 35 after initiation of a high-salt (HS) diet compared with normal-salt (NS) controls. Pathways are highlighted as functional groups, including metabolism, inflammation and death, cell cycle, and other clustered along the y axis. (B) Euclidean distances from baseline pathway profiles plotted over time, representing the magnitude of transcriptomic remodeling in each organ. The medulla shows the greatest divergence, followed by the heart, cortex, and liver. (C) Stacked bar charts enumerating upregulated (red) and downregulated (blue) Hallmark pathways at each time point for each organ. Numeric labels indicate pathway counts, highlighting distinct kinetics of pathway engagement across tissues. (D) Heatmaps showing Pearson correlation between pathway profiles across tissues (cortex, medulla, heart, and liver) at each time point (days 7, 14, 21, and 35). Each panel compares all organ pairs for a single time point, revealing similarities and differences in pathway responses among organs after the HS diet. CX, cortex; MD, medulla; LV, liver; HR, heart; D7, day 7; D14, day 14; D21, day 21; and D35, day 35 time points. n = 6 male rats per group.

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ISSN 2379-3708

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