Project description:The use of anthracycline antibiotics such as doxorubicin (DOX) has greatly improved the mortality and morbidity of cancer patients. However, the associated risk of cardiomyopathy has limited their clinical application. DOX-associated cardiotoxicity is irreversible and progresses to heart failure (HF). For this reason, a better understanding of the molecular mechanisms underlying these adverse cardiac effects is essential to develop improved regimes that include cardioprotective strategies. MicroRNAs (miRNAs) are short non-coding RNAs that are able to post-trascriptionally regulate gene expression. MiRNAs have been demonstrated to be involved in both cancer and cardiovascular disease. Therefore, we were interested in unveiling the potential role of miRNAs in chemotherapy-induced HF. We used a combination of three different models to recreate this cardiac toxicity (acute in vitro DOX treatment, DOX-induced HF in vivo and a myocardial infarction -MI- leading to failure model) to study the pattern of dysregulated miRNAs. Using RNA from all three conditions, miRNA microarray profiling was performed and a common miRNA signature was identified. Interestingly, these dysregulated miRNAs have been previously identified as involved in the failing heart. Our results suggest that DOX is able to alter the expression of miRNAs implicated in HF, in vitro as well as in vivo. The present study is a microRNA profiling of the damaged cardiac muscle (cardiomyocyte cell population), following either myocardial infarction (MI) induction or doxorubicin (DOX) treatment. Two DOX-treated models were included: ARC exposed to DOX in vitro and a validated DOX-induced heart failure model generated by repeated administration of DOX injections.

Project description:Rationale: Cardiac extracellular matrix (ECM) comprises a dynamic molecular network providing structural support to heart tissue function. Understanding the impact of ECM remodeling on cardiac cells during heart failure (HF) is essential to prevent adverse ventricular remodeling and restore organ functionality in affected patients. Objectives: We aimed to (i) identify consistent modifications to cardiac ECM structure and mechanics that contribute to HF and (ii) determine the underlying molecular mechanisms. Methods and Results: We first performed decellularization of human and murine ECM (dECM) and then analyzed the pathological changes occurring in dECM during HF by atomic force (AFM), two-photon microscopy, high-resolution 3D image analysis and computational fluid dynamics (CFD) simulation. We then performed molecular and functional assays in patient-derived cardiac fibroblasts (CFs) based on YAP-TEAD mechanosensing activity and collagen contraction assays. The analysis of HF dECM resulting from ischemic (IHD) or dilated cardiomyopathy (DCM), as well as from mouse infarcted tissue, identified a common pattern of modifications in their 3D topography. As compared to healthy heart, HF ECM exhibited aligned, flat and compact fiber bundles, with reduced elasticity and organizational complexity. At the molecular level, RNA sequencing of HF CFs highlighted the overrepresentation of dysregulated genes involved in ECM organization, or being connected to TGFß1, Interleukin-1, TNF-alpha and BDNF signaling pathways. Functional tests performed on HF CFs pointed at mechanosensor YAP as a key player in ECM remodeling in the diseased heart via transcriptional activation of focal adhesion assembly. Finally, in vitro experiments clarified pathological cardiac ECM prevents cell homing, thus providing further hints to identify a possible window of action for cell therapy in cardiac diseases. Conclusions: Our multi-parametric approach has highlighted repercussions of ECM remodeling on cell homing, CF activation and focal adhesion protein expression via hyper-activated YAP signaling during HF. Key words: Decellularization, extracellular matrix, dilated cardiomyopathy, ischemic heart disease, YAP, dilated cardiomyopathy, mechanobiology.

Project description:The knowledge of an expression network signature in end-stage heart failure (HF) diseased hearts may offer important insights into the complex pathogenesis of advanced cardiac failure, as well as it may provide potential targets for therapeutic intervention. In this study, the NGS sequencing of RNA (RNA-Seq) method was employed to obtain the whole transcriptome of cardiac tissues from transplant recipients with advanced stage of HF. The analysis of RNA-Seq data presents novel challenges and many methods have been developed for the purpose of mapping reads to genomic features and quantifying gene expression. The main goal of this work was to identify, characterize and catalogue all the transcripts expressed within cardiac tissue and to quantify the differential expression of transcripts in both physio- and pathological conditions through whole transcriptome analyses. Expression levels, differential splicing, allele-specific expression, RNA editing and fusion transcripts constitute important information when comparing samples for disease related studies. Analysis methods for RNA-Seq data are continuing to evolve. Thus, in order to find the best solution for filter generated list of differentially expressed genes, an informatic approach of NOISeq BIO method has been applied in this RNA-Seq analysis. Most of the genes obtained by filtering differentially expressed gene list, have been experimentally validated by Real time RT-PCR. Noteworthy, these findings provide valuable resources for further studies of the molecular mechanisms involved in heart ischemic response thus leading to potential novel biomarkers and targets for therapeutic intervention in the onset and progression of cardiomyopathies. Heart biopsies from candidates for solid organ transplantation were collected and their RNA samples were used for high-throughput sequencing purposes. Libraries were sequenced on the Illumina HiSeq2000 NGS platform.

Project description:In response to heart failure (HF), the heart reacts by repressing adult genes and expressing fetal genes, thereby returning to a more fetal-like gene profile. To identify genes involved in this process, we carried out transcriptional analysis on murine hearts at different stages of development and adult mice with HF. Our screen identified 5-oxoprolinase (OPLAH), a member of the -Glutamyl cycle, that functions by scavenging 5-oxoproline. OPLAH depletion occurred as a result of cardiac injury, leading to elevated 5-oxoproline and oxidative stress, whereas OPLAH overexpression improved cardiac function after ischemic injury. In HF patients we observed elevated plasma 5-oxoproline levels, which were associated with a worse clinical outcome. Understanding and modulating fetal-like genes in the failing heart may lead to potential novel diagnostic, prognostic and therapeutic options in HF.

Project description:Aim - Pathological cardiac remodeling is characterized by cardiomyocyte hypertrophy and fibroblast activation, which can ultimately lead to heart failure (HF). Genome-wide expression analysis on heart tissue has been instrumental for the identification of molecular mechanisms at play. However, these data were based on signals derived from all cardiac cell types. Here we aimed for a more detailed view on molecular changes driving cardiomyocyte hypertrophy and failure to aid in the development of therapies to reverse maladaptive remodeling. Methods and results - Utilizing cardiomyocyte-specific reporter mice exposed to pressure overload by transverse aortic banding (TAB), we obtained gene expression profiles of hypertrophic (one-week TAB) and failing (eight-weeks TAB) cardiomyocytes. We identified subsets of genes differentially regulated and specific for either stage. Among these, we found upregulation of known marker genes for HF, such as Nppb and Myh7. Additionally, we identified a set of genes specifically upregulated in failing cardiomyocytes and that so far have not been studied in HF, including the platelet isoform of phosphofructokinase (PFKP). Human cardiomyocytes subjected to 7-day NE/AngII treatment recapitulated the upregulation of the failure-induced genes indicating conservation. RNA-seq on failing and healthy human hearts confirmed increased expression for several failure-induced genes and allowed for expressional correlation to NPPB/MYH7. Finally, suppression of Pfkp in PE-treated primary cardiomyocytes reduced stress-induced gene expression and hypertrophy, suggesting a role in cardiomyocyte failure. Conclusion - Using cardiomyocyte-specific transcriptomic analysis we identified novel failure-induced genes relevant for human HF, and show that PFKP is a conserved failure-induced gene that can modulate cardiomyocyte stress response.

Project description:The knowledge of an expression network signature in end-stage heart failure (HF) diseased hearts may offer important insights into the complex pathogenesis of advanced cardiac failure, as well as it may provide potential targets for therapeutic intervention. In this study, the NGS sequencing of RNA (RNA-Seq) method was employed to obtain the whole transcriptome of cardiac tissues from transplant recipients with advanced stage of HF. The analysis of RNA-Seq data presents novel challenges and many methods have been developed for the purpose of mapping reads to genomic features and quantifying gene expression. The main goal of this work was to identify, characterize and catalogue all the transcripts expressed within cardiac tissue and to quantify the differential expression of transcripts in both physio- and pathological conditions through whole transcriptome analyses. Expression levels, differential splicing, allele-specific expression, RNA editing and fusion transcripts constitute important information when comparing samples for disease related studies. Analysis methods for RNA-Seq data are continuing to evolve. Thus, in order to find the best solution for filter generated list of differentially expressed genes, an informatic approach of NOISeq BIO method has been applied in this RNA-Seq analysis. Most of the genes obtained by filtering differentially expressed gene list, have been experimentally validated by Real time RT-PCR. Noteworthy, these findings provide valuable resources for further studies of the molecular mechanisms involved in heart ischemic response thus leading to potential novel biomarkers and targets for therapeutic intervention in the onset and progression of cardiomyopathies.

Project description:Oxidative stress plays a key role in development and progression of cardiovascular diseases and it is correlated with left ventricular dysfunction and heart failure (HF). Oxidative environments lead to the formation of intra- and intermolecular disulfide bonds, as well as to plethora of other reversible and irreversible oxidative amino acid modifications, affecting the functionality of the proteins. Here we report that heart failure due to ischemic cardiomyopathy (ICM) or dilated cardiomyopathy (DCM) is correlated with increase in oxidative stress compared to non-failing control hearts, manifested through decreased GSH/GSSG ratio in failing heart tissue samples and adaptations of cardiac redox proteome which occur in correlation with two different heart pathologies.

Project description:Heart Failure (HF) remains the leading cause of mortality and morbidity globally. Novel therapeutic targets to tackle this pandemic are in dire need. Zebrafish, a vertebrate whose heart shares many physiological similarities to the human heart, are able to naturally undergo cardiac regeneration following HF. We used microarrays to analyse gene expression during cardiac regeneration following heart failure

Project description:Epigenetic status has been linked to cardiac hypertrophy and heart failure. Histone deacetylase inhibitors are promising drugs for preventing cardiac remodeling. We previously demonstrated very different patterns of histone H3 lysine 9 trimethylation (H3K9me3) and histone H3 lysine 4 trimethylation (H3K4me3) in failing hearts compared to control hearts in both animal models and clinical heart specimens. Here, we focused on a heart failure-specific histone modification, H3K9me3, and investigated the prognostic efficacy of administering a histone H3K9 methyltransferase inhibitor, chaetocin, to Dahl salt-sensitive rats, an animal model of heart failure. Chaetocin delayed the timing of transition from cardiac hypertrophy to heart failure, and prolonged survival in this animal model. Mitochondrial dysfunction was improved with inhibitor use in the failing heart. ChIP-seq analysis demonstrated that heart failure caused an increase in H3K9me3 alignments in thousands of repetitive elements, including regions neighboring mitochondrial genes, and a corresponding reduction of this effect with inhibitor use. However, at 35 loci, heart failure was conversely associated with a reduction in H3K9me3 alignments, and inhibitor use reversed this effect. These data suggest that excessive heterochromatinization of repetitive elements in the failing heart might impair pumping function with mitochondrial gene silencing. H3K9 methyltransferase inhibitors may be a promising novel therapy for chronic heart failure.

Project description:Cardiac fibroblasts (CFs) play a crucial role in cardiac remodeling, which is a common cause of heart failure (HF). However, the molecular mechanisms underlying the transformation of fibroblasts into myofibroblasts remain largely unknown. Foxm1 is well-known in various cardiovascular diseases. However, the role of Foxm1-driven CF activation in the progression of cardiac remodeling towards HF is still being investigated. In this study, we observed an upregulation of Foxm1 expression in samples obtained from patients with heart failure (HF) and in mice with transverse aortic constriction (TAC)-induced cardiac remodeling. Additionally, we discovered that inhibition of Foxm1 using the drug FDI-6 improved TAC-induced cardiac remodeling and attenuated the activation of cardiac fibroblasts (CFs). Furthermore, through our investigations, we found that Foxm1 was activated in Tcf21-Cre and PostnMCM transgenic mice subjected to TAC surgery, resulting in the activation of CFs and exerting an influence on the cardiac remodeling process.