Cardiac fibroblast proliferation rates and collagen expression mature early in life and do not change with advancing age [Bisulfite-Seq]
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ABSTRACT: Cardiac fibrosis is a pathophysiologic hallmark of the aging heart. In the uninjured heart, cardiac fibroblasts exist in the quiescent state, but little is known about how proliferation rates and fibroblast transcriptional programs change throughout the lifespan of the organism from the immediate postnatal period to adult life and old age. Using EdU pulse labeling, we demonstrate that more than 50% of cardiac fibroblasts are actively proliferating in the first day of post-natal life. However, within 4 weeks of birth in the juvenile animal, only 10% of cardiac fibroblasts are proliferating. By early adulthood, the fraction of proliferating cardiac fibroblasts further decreases to approximately 2%, where it so remains throughout the rest of the organism’s life span. Examination of absolute cardiac fibroblast numbers demonstrated concordance with age related changes in fibroblast proliferation with no significant differences in absolute cardiac fibroblast numbers between animals 14 weeks and 1.5 years of age. We demonstrate that the maximal changes in cardiac fibroblast transcriptional programs and in particular collagen expression occur within the first weeks of life from the immediate postnatal to the juvenile period. We show that even though the aging heart exhibits an increase in the total amount of accumulated collagen, transcription of various collagens and ECM genes both in the heart and cardiac fibroblast is maximal in the newly born and juvenile animal and decreases with organismal aging. Examination of DNA methylation changes both in the heart and in cardiac fibroblasts did not demonstrate significant changes in differentially methylated regions between young and old mice. Our observations demonstrate that cardiac fibroblasts attain a stable proliferation rate and transcriptional program early in the life span of the organism and suggest a model of cardiac aging where phenotypic changes in the aging heart are not directly attributable to changes in proliferation rate or altered collagen expression in cardiac fibroblasts.
ORGANISM(S): Mus musculus
PROVIDER: GSE160074 | GEO | 2020/10/26
REPOSITORIES: GEO
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