Eukaryotes must balance the metabolic and cell death actions of mitochondria via control of gene expression and cell fate by chromatin, thereby functionally binding the metabolome and epigenome. This ...interaction has far-reaching implications for chronic diseases in humans, the most common of which are those of the cardiovascular system. The most devastating consequence of cardiovascular disease, heart failure, is not a single disease, diagnosis, or endpoint. Human and animal studies have revealed that, regardless of etiology and symptoms, heart failure is universally associated with abnormal metabolism and gene expression – to frame this as cause or consequence, however, may be to wrongfoot the question. This essay aims to challenge current thinking on metabolic–epigenetic crosstalk in heart failure, presenting hypotheses for how chronic diseases arise, take hold, and persist. We unpack assumptions about the order of operations for gene expression and metabolism, exploring recent findings in noncardiac systems that link metabolic intermediates directly to chromatin remodeling. Lastly, we discuss potential mechanisms by which chromatin may serve as a substrate for metabolic memory, and how changes in cellular transcriptomes (and hence in cellular behavior) in response to stress correspond to global changes in chromatin accessibility and structure.
Heart failure is a ruinous destination for many afflicted with cardiovascular disease and is not a single condition or single set of diagnostic criteria; instead, it manifests through an intricate series of molecular and systemic malfunctions ranging from the suborganelle level to the multiple organ systems of the body.Regardless of the etiology, humans with, and animal models of, heart failure are characterized by abnormal metabolism and gene expression, some aspects of which are compensatory responses to the disease whereas others promulgate injury.Close communication between the metabolome and the epigenome sets basal susceptibility to various heart failure symptoms. This communication entrains detrimental conditions in metabolic–epigenetic memory and thus may be a target for novel treatments.
Abstract
Heart failure with preserved ejection fraction (HFpEF) exhibits a sex bias, being more common in women than men, and we hypothesize that mitochondrial sex differences might underlie this ...bias. As part of genetic studies of heart failure in mice, we observe that heart mitochondrial DNA levels and function tend to be reduced in females as compared to males. We also observe that expression of genes encoding mitochondrial proteins are higher in males than females in human cohorts. We test our hypothesis in a panel of genetically diverse inbred strains of mice, termed the Hybrid Mouse Diversity Panel (HMDP). Indeed, we find that mitochondrial gene expression is highly correlated with diastolic function, a key trait in HFpEF. Consistent with this, studies of a “two-hit” mouse model of HFpEF confirm that mitochondrial function differs between sexes and is strongly associated with a number of HFpEF traits. By integrating data from human heart failure and the mouse HMDP cohort, we identify the mitochondrial gene
Acsl6
as a genetic determinant of diastolic function. We validate its role in HFpEF using adenoviral over-expression in the heart. We conclude that sex differences in mitochondrial function underlie, in part, the sex bias in diastolic function.
During postnatal cardiac hypertrophy, cardiomyocytes undergo mitotic exit, relying on DNA replication-independent mechanisms of histone turnover to maintain chromatin organization and gene ...transcription. In other tissues, circadian oscillations in nucleosome occupancy influence clock-controlled gene expression, suggesting a role for the circadian clock in temporal control of histone turnover and coordinated cardiomyocyte gene expression. We sought to elucidate roles for the master circadian transcription factor, Bmal1, in histone turnover, chromatin organization, and myocyte-specific gene expression and cell growth in the neonatal period. Bmal1 knockdown in neonatal rat ventricular myocytes decreased myocyte size, total cellular protein synthesis, and transcription of the fetal hypertrophic gene Nppb after treatment with serum or the α-adrenergic agonist phenylephrine. Depletion of Bmal1 decreased the expression of clock-controlled genes Per2 and Tcap, as well as Sik1, a Bmal1 target upregulated in adult versus embryonic hearts. Bmal1 knockdown impaired Per2 and Sik1 promoter accessibility as measured by micrococcal nuclease-quantitative PCR and impaired histone turnover as measured by metabolic labeling of acid-soluble chromatin fractions. Sik1 knockdown in turn decreased myocyte size, while simultaneously inhibiting natriuretic peptide B transcription and activating Per2 transcription. Linking these changes to chromatin remodeling, depletion of the replication-independent histone variant H3.3a inhibited myocyte hypertrophy and prevented phenylephrine-induced changes in clock-controlled gene transcription. Bmal1 is required for neonatal myocyte growth, replication-independent histone turnover, and chromatin organization at the Sik1 promoter. Sik1 represents a novel clock-controlled gene that coordinates myocyte growth with hypertrophic and clock-controlled gene transcription. Replication-independent histone turnover is required for transcriptional remodeling of clock-controlled genes in cardiac myocytes in response to growth stimuli.
BACKGROUND:Cardiovascular disease is associated with epigenomic changes in the heart; however, the endogenous structure of cardiac myocyte chromatin has never been determined.
METHODS:To investigate ...the mechanisms of epigenomic function in the heart, genome-wide chromatin conformation capture (Hi-C) and DNA sequencing were performed in adult cardiac myocytes following development of pressure overload–induced hypertrophy. Mice with cardiac-specific deletion of CTCF (a ubiquitous chromatin structural protein) were generated to explore the role of this protein in chromatin structure and cardiac phenotype. Transcriptome analyses by RNA-seq were conducted as a functional readout of the epigenomic structural changes.
RESULTS:Depletion of CTCF was sufficient to induce heart failure in mice, and human patients with heart failure receiving mechanical unloading via left ventricular assist devices show increased CTCF abundance. Chromatin structural analyses revealed interactions within the cardiac myocyte genome at 5-kb resolution, enabling examination of intra- and interchromosomal events, and providing a resource for future cardiac epigenomic investigations. Pressure overload or CTCF depletion selectively altered boundary strength between topologically associating domains and A/B compartmentalization, measurements of genome accessibility. Heart failure involved decreased stability of chromatin interactions around disease-causing genes. In addition, pressure overload or CTCF depletion remodeled long-range interactions of cardiac enhancers, resulting in a significant decrease in local chromatin interactions around these functional elements.
CONCLUSIONS:These findings provide a high-resolution chromatin architecture resource for cardiac epigenomic investigations and demonstrate that global structural remodeling of chromatin underpins heart failure. The newly identified principles of endogenous chromatin structure have key implications for epigenetic therapy.
Human speech is one of the few examples of vocal learning among mammals yet ~half of avian species exhibit this ability. Its neurogenetic basis is largely unknown beyond a shared requirement for ...FoxP2 in both humans and zebra finches. We manipulated FoxP2 isoforms in Area X, a song-specific region of the avian striatopallidum analogous to human anterior striatum, during a critical period for song development. We delineate, for the first time, unique contributions of each isoform to vocal learning. Weighted gene coexpression network analysis of RNA-seq data revealed gene modules correlated to singing, learning, or vocal variability. Coexpression related to singing was found in juvenile and adult Area X whereas coexpression correlated to learning was unique to juveniles. The confluence of learning and singing coexpression in juvenile Area X may underscore molecular processes that drive vocal learning in young zebra finches and, by analogy, humans.
Atrial fibrillation (AF) is the most common sustained cardiac arrhythmia and post-operative atrial fibrillation (POAF) is a major healthcare burden, contributing to an increased risk of stroke, ...kidney failure, heart attack and death. Genetic studies have identified associations with AF, but no molecular diagnostic exists to predict POAF based on pre-operative measurements. Such a tool would be of great value for perioperative planning to improve patient care and reduce healthcare costs. In this pilot study of epigenetic precision medicine in the perioperative period, we carried out bisulfite sequencing to measure DNA methylation status in blood collected from patients prior to cardiac surgery to identify biosignatures of POAF.
We enrolled 221 patients undergoing cardiac surgery in this prospective observational study. DNA methylation measurements were obtained from blood samples drawn from awake patients prior to surgery. After controlling for clinical and methylation covariates, we analyzed DNA methylation loci in the discovery cohort of 110 patients for association with POAF. We also constructed predictive models for POAF using clinical and DNA methylation data. We subsequently performed targeted analyses of a separate cohort of 101 cardiac surgical patients to measure the methylation status solely of significant methylation loci in the discovery cohort.
A total of 47 patients in the discovery cohort (42.7%) and 43 patients in the validation cohort (42.6%) developed POAF. We identified 12 CpGs that were statistically significant in the discovery cohort after correcting for multiple hypothesis testing. Of these sites, 6 were amenable to targeted bisulfite sequencing and chr16:24640902 was statistically significant in the validation cohort. In addition, the methylation POAF prediction model had an AUC of 0.79 in the validation cohort.
We have identified DNA methylation biomarkers that can predict future occurrence of POAF associated with cardiac surgery. This research demonstrates the use of precision medicine to develop models combining epigenomic and clinical data to predict disease.
Abstract only Mechanosensitive pathways are fine tuned to the physiological environment of the cell. Adrenergic stimulation induces cell type specific responses in the heart, including cardiomyocyte ...hypertrophy and fibroblast proliferation. We hypothesized acute induction of hypertrophy by phenylephrine (PHE) would activate mechanosensitive pathways in fibroblasts and myocytes, revealing novel molecular features of early hypertrophic adaptation. Male mice were subcutaneously injected with 20 mg/kg of PHE or PBS every other day for one week. Echocardiography revealed significant cardiac hypertrophy with increased ejection fraction (72.45% + 6.15 PHE v 56.32 + 5.32 PBS, p<0.0001) and LV wall thickness (2.25 mm + 0.29 PHE v 1.62 + 0.13 PBS, p<0.0001), along with diastolic impairment, as measured by elevated E/e’ ratio (37.25 + 7.29 PHE v 23.67 + 3.62 PBS, p<0.0001). Interestingly, histological analysis showed increased fibrotic deposition and cardiomyocyte cross-sectional area was preferential increased in fibrotic areas (265.5 um 2 + 67.5 PHE fibrotic v 195.1 + 47.46 PHE non-fibrotic v 165.6 + 46.96 PBS). While cardiac fibroblasts from PHE-treated animals did not show alpha smooth muscle actin staining, a traditional marker for activated myofibroblasts, fibroblasts from PHE-treated mice showed increased f-actin stress fibers and nuclear localization of Mrtfa, a mechanosensitive transcriptional coactivator. We performed RNA-seq on isolated cardiomyocytes, demonstrating activation of myocyte-specific responses to increased pressure ( Des, Nppa ), as well as activation of fibrotic genes ( Tgfbr1, Tgfbr2, Tgfb2 ) in myocytes . We sought to investigate mechanosensitive pathways initiated by PHE treatment in cardiomyocytes and identified transcriptional changes in Ankrd1, a Titin binding protein which translocates to the nucleus upon stress. We demonstrate a PHE induced increase in Ankrd1 protein expression and nuclear localization (nuclear area occupancy, as measured by microscopy, 17.04% + 8.76 PHE v 11.91% + 9.134 PBS, p=0.002) in cardiomyocytes. Together these findings demonstrate distinct acute phenotyptic adaptation to adrenergic stress in myocytes and fibroblasts, revealing cell type-specific mechanosensitive signaling mechanisms.
Abstract only Given rising obesity rates, understanding how metabolic changes exacerbate other cardiovascular disease (CVD) risk factors will yield novel therapeutic targets for associated ...comorbidities, such as heart failure. We hypothesize that obesity-related metabolic syndrome induces transcriptional programs that engender cardiac pathology via mechanisms involving chromatin regulators, thereby perpetuating the pathology by epigenetic memory. C57BL/6J adult male mice were put on a high fat diet (HFD) for 24 weeks. After HFD, hearts were in hypertrophy, as defined by an increase in heart weight to tibia length ratio (24.67 ± 5.14 mg/mm in HFD versus 17.06 ± 0.98 mg/mm in regular chow controls, p=0.026). Examination of blood plasma revealed significant increase in LDL-C (74.37 ± 22.45 mg/dL in HFD versus 21.91 ± 5.98 mg/dL in controls, p=0.0005) and insulin (452.81 ± 224.77 uIU/mL in HFD versus 89.66 ± 45.60 uIU/mL in controls, p=0.0003), indicative of metabolic disorder. RNA-seq of isolated cardiomyocytes revealed distinct transcriptomic changes at 1 week, 6 weeks, and 24 weeks of HFD. At 1 week, HFD stimulus induced promotion of lipid metabolism ( Pdk4, Per2 ) and suppression of genes related to development and proliferation ( Sox4, Epha4 ). By 6 weeks, the cardiomyocytes underwent metabolic reprogramming (downregulation of Lpl and Irs2 ) and structural changes ( Acta2, Col8a1). At 24 weeks, we observed suppression of ketolytic machinery (downregulation of Abat, Bdh1, and Oxct1 ) in response to obesity-driven hyperglycemia, suggesting that cardiomyocytes transitioned to a pre-diabetic state. To test whether this metabolic disease state compounds with other CVD risk factors, we devised a two-hit model, where mice were fed HFD for 6 weeks and then underwent transverse aortic constriction as a model of pressure overload. Cardiomyocytes from this two-hit model exhibited an enhanced hypertrophic response ( Myh7, Nppa, Col1a1 mRNA levels) compared to pressure overload with regular chow, sham surgery with HFD, or sham surgery with chow. Thus, phenotypic and transcriptional data suggest that HFD reprograms cardiomyocytes to a pre-diabetic state characterized by insulin resistance which exacerbates the effects of other CVD risk factors like hypertrophy.