Several post-translational modifications figure prominently in ventricular remodeling. The beta-Olinkage of N-acetylglucosamine (O-GlcNAc) to proteins has emerged as an important signal in the cardiovascular system. Although there are limited insights about the regulation of the biosynthetic pathway that gives rise to the O-GlcNAc post-translational modification, much remains to be elucidated regarding the enzymes, such as O-GlcNAc transferase (OGT) and O-GlcNAcase (OGA), which regulate the presence/absence of O-GlcNAcylation. Recently, we showed that the transcription factor, E2F1, could negatively regulate OGT and OGA expression in vitro. The present study sought to determine whether E2f1 deletion would improve post-infarct ventricular function by de-repressing expression of OGT and OGA. Male and female mice were subjected to non-reperfused myocardial infarction (MI) and followed for 1 or 4 week. MI significantly increased E2F1 expression. Deletion of E2f1 alone was not sufficient to alter OGT or OGA expression in a naïve setting. Cardiac dysfunction was significantly attenuated at 1-week post-MI in E2f1-ablated mice. During chronic heart failure, E2f1 deletion also attenuated cardiac dysfunction. Despite the improvement in function, OGT and OGA expression was not normalized and protein O-GlcNAcyltion was not changed at 1-week post-MI. OGA expression was significantly upregulated at 4-week post-MI but overall protein O-GlcNAcylation was not changed. As an alternative explanation, we also performed guided transcriptional profiling of predicted targets of E2F1, which indicated potential differences in cardiac metabolism,
Rationale The beta-O-linkage of N-acetylglucosamine (i.e., O-GlcNAc) to proteins is a pro-adaptive response to cellular insults. To this end, increased protein O-GlcNAcylation improves short-term survival of cardiomyocytes subjected to acute injury. This observation has been repeated by multiple groups and in multiple models; however, whether increased protein O-GlcNAcylation plays a beneficial role in more chronic settings remains an open question. Objective Here, we queried whether increasing levels of cardiac protein O-GlcNAcylation would be beneficial during infarct-induced heart failure. Methods and results To achieve increased protein O-GlcNAcylation, we targeted Oga, the gene responsible for removing O-GlcNAc from proteins. Here, we generated mice with cardiomyocyte-restricted, tamoxifen-inducible haploinsufficient Oga gene. In the absence of infarction, we observed a slight reduction in ejection fraction in Oga deficient mice. Overall, Oga reduction had no major impact on ventricular function. In additional cohorts, mice of both sexes and both genotypes were subjected to infarct-induced heart failure and followed for up to four weeks, during which time cardiac function was assessed via echocardiography. Contrary to our prediction, the Oga deficient mice exhibited exacerbated—not improved—cardiac function at one week following infarction. When the observation was extended to 4 wk post-MI, this acute exacerbation was lost. Conclusions The present findings, coupled with our previous work, suggest that altering the ability of cardiomyocytes to either add or remove O-GlcNAc modifications to proteins exacerbates early infarct-induced heart failure. We speculate that more nuanced approaches to regulating O-GlcNAcylation are needed to understand its role—and, in particular, the possibility of cycling, in the pathophysiology of the failing heart.
Most preclinical studies have used only cells from healthy, nonfailing hearts. Whether donor condition (i.e., heart failure) impacts cells used for cell therapy is not known. We directly tested whether donor condition impacted the reparative effects of cardiac mesenchymal cells in a chronic model of myocardial infarction. Although cells from failing hearts differed in multiple aspects, they retained the potential to limit ventricular remodeling.
Background: The extracellular matrix (ECM) provides structural and functional support for the myocardium, but myocardial infarction (MI) changes the composition of the ECM. One of the chief components of the ECM, hyaluronan (HA), is elevated after MI; however, specific biological actions of HA—particularly at the level of infiltrating immune cells and implications of such interactions on ventricular remodeling—have not been explored. Goals: Because upregulation of HA coincides with macrophage infiltration after MI, we determined whether hyaluronan interacts with macrophages and investigated the implication of such interactions on macrophage function. Methods: WT mice were subjected to non-reperfused MI to determine changes in hyaluronan synthases (HAS), hyaluronidases (HYAL), and HA levels in the heart. Interaction of HA with macrophages was studied by polarizing bone marrow derived macrophages and analyzing cells by flow cytometry. Next, we characterized the ability of macrophages to metabolize HA by profiling polarized macrophages for HA-metabolizing enzymes, HA receptors, HA-binding proteins, hyaluronidase activity, and phagocytosis. Results: Compared to Sham hearts, MI (n=5/group) augmented the expression of HAS-2 (10-fold, p=0.002) and HYAL-2 (2 to 4-fold, p=0.0004) in the infarct and remote regions of the heart at 5 d post-MI. HA levels (n=8/group) were elevated in the infarct (1 to 2-fold, p=0.0200) and remote (2 to 3-fold, p=0.0007) regions of the heart compared to sham hearts. Polarizing macrophages (n=3/group) in the presence fluorescein-conjugated HA (HA-FL) showed that naïve (M0), pro-inflammatory (M1), and pro-resolving (M2) macrophages interact with HA-FL; M1 showed the highest FITC intensity. Interestingly, exposing macrophages (n=5/group) to HA provoked an inflammatory phenotype, as reflected by enhanced expression of TNFα (4-fold, p=0.0001) and IL-1β (7-fold, p=0.0094) mRNA; HA also enhanced macrophage phagocytosis (0.5-fold, p= 0.0476). Conclusion: Hyaluronan is elevated following MI and can influence macrophage function. Because of the accumulation of hyaluronan and macrophages in the post-MI heart, macrophage-hyaluronan interactions may be a nexus regulating ventricular remodeling.
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