Long telomeres protect against age-dependent cardiac disease caused by NOTCH1 haploinsufficiency
Christina V. Theodoris, … , Helen M. Blau, Deepak Srivastava
Christina V. Theodoris, … , Helen M. Blau, Deepak Srivastava
Published March 27, 2017
Citation Information: J Clin Invest. 2017;127(5):1683-1688. https://doi.org/10.1172/JCI90338.
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Long telomeres protect against age-dependent cardiac disease caused by NOTCH1 haploinsufficiency

Abstract

Diseases caused by gene haploinsufficiency in humans commonly lack a phenotype in mice that are heterozygous for the orthologous factor, impeding the study of complex phenotypes and critically limiting the discovery of therapeutics. Laboratory mice have longer telomeres relative to humans, potentially protecting against age-related disease caused by haploinsufficiency. Here, we demonstrate that telomere shortening in NOTCH1-haploinsufficient mice is sufficient to elicit age-dependent cardiovascular disease involving premature calcification of the aortic valve, a phenotype that closely mimics human disease caused by NOTCH1 haploinsufficiency. Furthermore, progressive telomere shortening correlated with severity of disease, causing cardiac valve and septal disease in the neonate that was similar to the range of valve disease observed within human families. Genes that were dysregulated due to NOTCH1 haploinsufficiency in mice with shortened telomeres were concordant with proosteoblast and proinflammatory gene network alterations in human NOTCH1 heterozygous endothelial cells. These dysregulated genes were enriched for telomere-contacting promoters, suggesting a potential mechanism for telomere-dependent regulation of homeostatic gene expression. These findings reveal a critical role for telomere length in a mouse model of age-dependent human disease and provide an in vivo model in which to test therapeutic candidates targeting the progression of aortic valve disease.

Authors

Christina V. Theodoris, Foteini Mourkioti, Yu Huang, Sanjeev S. Ranade, Lei Liu, Helen M. Blau, Deepak Srivastava

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Figure 3

Genes dysregulated due to telomere shortening are enriched for telomere-contacted promoters.

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Genes dysregulated due to telomere shortening are enriched for telomere-...
(A) mRNA expression by RNA-seq of dysregulated genes in N1WT mTRG2 (n = 4) vs N1WT mTRWT (n = 4) AVs. (B) mRNA expression of dysregulated genes in N1+/− mTRWT (n = 4) vs. N1WT mTRWT (n = 4) or N1+/− mTRG2 (n = 4) vs N1WT mTRG2 AVs (n = 3). Telo, telomere. (C) Percentage of overlap of indicated murine gene groups with genes dysregulated (dysreg) due to N1 heterozygosity in human iPSC-derived ECs (16). *P < 0.05, χ2 test. (D and E) Mean mRNA expression of indicated genes in WT (n = 4), N1+/− (n = 4), mTRG2 (n = 3), and N1+/− mTRG2 (n = 4) AVs. Data are shown as mean ± SEM. *Significant by negative binomial test, false discovery rate (FDR) correction of 10%. FPKM, fragments per kilobase million. (F) Fold enrichment of telomere-contacting promoters in stated gene groups compared with all genes. *P < 0.05, hypergeometric test, Benjamini-Hochberg correction. (G) Model of telomere length and relationship to disease onset. Left, telomere length shortens with each cell division. Right, telomere length varies at baseline by organism and mTR genotype and progressively shortens with aging as cells divide over time. Dotted line, threshold after which heart valve disease may ensue. Increased cell division caused by N1 haploinsufficiency accelerates telomere shortening rate, eliciting the heart valve disease phenotype in N1+/− mTRG2 mice.