Super-enhancers maintain renin-expressing cell identity and memory to preserve multi-system homeostasis
Maria Florencia Martinez, … , Maria Luisa S. Sequeira-Lopez, R. Ariel Gomez
Maria Florencia Martinez, … , Maria Luisa S. Sequeira-Lopez, R. Ariel Gomez
Published August 21, 2018
Citation Information: J Clin Invest. 2018;128(11):4787-4803. https://doi.org/10.1172/JCI121361.
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Research Article Endocrinology Nephrology

Super-enhancers maintain renin-expressing cell identity and memory to preserve multi-system homeostasis

Abstract

Renin cells are crucial for survival — they control fluid-electrolyte and blood pressure homeostasis, vascular development, regeneration, and oxygen delivery to tissues. During embryonic development, renin cells are progenitors for multiple cell types that retain the memory of the renin phenotype. When there is a threat to survival, those descendants are transformed and reenact the renin phenotype to restore homeostasis. We tested the hypothesis that the molecular memory of the renin phenotype resides in unique regions and states of these cells’ chromatin. Using renin cells at various stages of stimulation, we identified regions in the genome where the chromatin is open for transcription, mapped histone modifications characteristic of active enhancers such as H3K27ac, and tracked deposition of transcriptional activators such as Med1, whose deletion results in ablation of renin expression and low blood pressure. Using the rank ordering of super-enhancers, epigenetic rewriting, and enhancer deletion analysis, we found that renin cells harbor a unique set of super-enhancers that determine their identity. The most prominent renin super-enhancer may act as a chromatin sensor of signals that convey the physiologic status of the organism, and is responsible for the transformation of renin cell descendants to the renin phenotype, a fundamental process to ensure homeostasis.

Authors

Maria Florencia Martinez, Silvia Medrano, Robin Isadora Brown, Turan Tufan, Stephen Shang, Nadia Bertoncello, Omar Guessoum, Mazhar Adli, Brian C. Belyea, Maria Luisa S. Sequeira-Lopez, R. Ariel Gomez

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Figure 6

The coactivator MED1 is essential for renin expression in vivo.

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The coactivator MED1 is essential for renin expression in vivo. (A) Cont...
(A) Control mouse where one allele of Med1 gene is floxed and the other is WT. The cell below indicates that in the presence of Med1 the renin gene is transcribed and there is granule formation and renin storage. Mutated mouse where one allele of Med1 is floxed and the other one is deleted; the Cre gene driven by the renin promoter deletes the floxed allele, generating a Med1 homozygous deletion in renin lineage cells. In the cell corresponding to the mutant mouse, absence of MED1 (green dashed line) indicates that there is no renin transcription and no granule formation in the renin cells. (B) Immunostaining for RENIN and AKR1B7 shows a decrease in signal for both proteins in JG cells of mutant mice (n = 6) compared with control mice (signal is indicated by the brown color; n = 8). (C) The JG index, measured as the percentage of RENIN-positive areas over the total number of glomeruli, indicates that mutant mice (n = 6) have fewer renin-positive JG areas when compared with control mice (n = 8). (D) Relative expression of renin mRNA levels measured by qPCR. Mutant mice (n = 6) have significantly lower expression than the controls (n = 8). (E) Plasma RENIN levels are lower in mutant mice (n = 6) than in controls (n = 8). (F) Med1 mutant mice have lower blood pressures than control mice (n = 6 per group). (G) Akr1b7 mRNA levels are decreased in mutant mice (n = 6). Data are mean ± SD. **P < 0.01; ***P < 0. 001, by unpaired, 2-sided Student’s t test.