Mechanisms of the Multitasking Endothelial Protein NRG-1 as a Compensatory Factor During Chronic Heart Failure

Keulenaer, Gilles W. De; Feyen, Eline; Dugaucquier, Lindsey; Shakeri, Hadis; Shchendrygina, Anastasia; Belenkov, Yury; Brink, Marijke; Vermeulen, Zarha; Segers, Vincent F.M.

doi:10.1161/circheartfailure.119.006288

Cited by 50 publications

(39 citation statements)

References 86 publications

(154 reference statements)

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“…Experiments show that expression of FAP (fibroblast activation protein alpha) [66], THBS4 [67], CD27 [68], LEF1 [69], CTHRC1 [70], ESR1 [71], CXCL9 [72], SERPINA3 [73], TRPC4 [74], F13A1 [75], PIK3C2A [76], KCNIP2 [77] and GPR4 [78] contributed to myocardial infarction. MFAP4 [79], ALOX15 [80], COL1A1 [81], APOA1 [82], PDE5A [83], CX3CR1 [84], THY1 [85], GREM1 [86], FMOD (fibromodulin) [87], NPPA (natriuretic peptide A) [88], LTBP2 [89], LUM (lumican) [90], IL34 [91], NRG1 [92], CXCL14 [93], CXCL10 [94], ACE (angiotensin I converting enzyme) [95], CFTR (ystic fibrosis transmembrane conductance regulator) [96], S100A8 [97], S100A9 [97], HP (haptoglobin) [98] [162], Zhang et al [163] and Chen et al [164] study indicated that the expression of CCL22, CCR1, FPR1, KNG1, CRISPLD2, CD38 and GPRC5A were linked with progression of ischemic heart disease. Li et al [165] showed that STEAP3 expression can be associated with cardiac hypertrophy progression.…”

Section: Discussionmentioning

confidence: 99%

Identification of candidate biomarkers and therapeutic agents for heart failure by bioinformatics analysis

Vastrad¹,

Tengli

Vastrad³

2021

Preprint

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Heart failure (HF) is a heterogeneous clinical syndrome and affects millions of people all over the world. HF occurs when the cardiac overload and injury, which is a worldwide complaint. The aim of this study was to screen and verify hub genes involved in developmental HF as well as to explore active drug molecules. The expression profiling by high throughput sequencing of GSE141910 dataset was downloaded from the Gene Expression Omnibus (GEO) database, which contained 366 samples, including 200 heart failure samples and 166 non heart failure samples. The raw data was integrated to find differentially expressed genes (DEGs) and were further analyzed with bioinformatics analysis. Gene ontology (GO) and REACTOME enrichment analyses were performed via ToppGene; protein-protein interaction (PPI) networks of the DEGs was constructed based on data from the HiPPIE interactome database; modules analysis was performed; target gene - miRNA regulatory network and target gene - TF regulatory network were constructed and analyzed; hub genes were validated; molecular docking studies was performed. A total of 881 DEGs, including 442 up regulated genes and 439 down regulated genes were observed. Most of the DEGs were significantly enriched in biological adhesion, extracellular matrix, signaling receptor binding, secretion, intrinsic component of plasma membrane, signaling receptor activity, extracellular matrix organization and neutrophil degranulation. The top hub genes ESR1, PYHIN1, PPP2R2B, LCK, TP63, PCLAF, CFTR, TK1, ECT2 and FKBP5 were identified from the PPI network. Module analysis revealed that HF was associated with adaptive immune system and neutrophil degranulation. The target genes, miRNAs and TFs were identified from the target gene - miRNA regulatory network and target gene - TF regulatory network. Furthermore, receiver operating characteristic (ROC) curve analysis and RT-PCR analysis revealed that ESR1, PYHIN1, PPP2R2B, LCK, TP63, PCLAF, CFTR, TK1, ECT2 and FKBP5 might serve as prognostic, diagnostic biomarkers and therapeutic target for HF. The predicted targets of these active molecules were then confirmed. The current investigation identified a series of key genes and pathways that might be involved in the progression of HF, providing a new understanding of the underlying molecular mechanisms of HF.

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Section: Discussionmentioning

confidence: 99%

Identification of candidate biomarkers and therapeutic agents for heart failure by bioinformatics analysis

Vastrad¹,

Tengli

Vastrad³

2021

Preprint

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“…In heart failure, enhanced activity of NRG-1 emerges as one of the adaptive mechanisms counteracting cardiac remodeling and disease progression (73). The endogenous source of NRG-1 in the heart has been shown largely to be the microvascular and endocardial endothelium (74,75), and ECs have been demonstrated to be a crucial source of NRG-1 for cardioprotection against ischemic insult (76).…”

Section: Neuregulin-1mentioning

confidence: 99%

“…of ERBB signaling in the heart are remarkably pleiotropic with effects on endothelial cells, fibroblasts, macrophages and neuronal cells (73). Thus, the benefits reported with NRG-1 therapy may involve multiple cell types and mechanisms of action in addition to myocyte growth and/or proliferation.…”

Section: Figurementioning

confidence: 99%

“…These molecular events promote hypertrophic and, at least during development, also mitotic cardiomyocyte growth, as well as cardiomyocyte resistance to apoptosis ( 77 , 78 ). However, in pathological hypertrophy induced by for example, angiotensin II–hypertension model or myocardial infarction, NRG-1 reduces the increase of cardiomyocyte cross-sectional area ( 73 ). NRG-1/ERBB signaling is also activated in physiological hemodynamic overload during pregnancy ( 79 ) and HB-EGF/NRG-1 expression and shedding are induced by VEGFR2 signaling in angiogenesis-induced physiological cardiac hypertrophy ( 13 ).…”

Section: Neuregulin-1mentioning

confidence: 99%

“…Previously, phase 2 human trials had reported recombinant NRG-1 administration to be safe and to improve cardiovascular function in patients with heart failure ( 81 , 82 ). The effects of ERBB signaling in the heart are remarkably pleiotropic with effects on endothelial cells, fibroblasts, macrophages and neuronal cells ( 73 ). Thus, the benefits reported with NRG-1 therapy may involve multiple cell types and mechanisms of action in addition to myocyte growth and/or proliferation.…”

Section: Neuregulin-1mentioning

confidence: 99%

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Angiogenesis and angiocrines regulating heart growth

Hemanthakumar

Kivelä

2020

Vascular Biology

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Endothelial cells (ECs) line the inner surface of all blood and lymphatic vessels throughout the body, making endothelium one of the largest tissues. In addition to its transport function, endothelium is now appreciated as a dynamic organ actively participating in angiogenesis and permeability and vascular tone regulation, as well as in the development and regeneration of tissues. The identification of endothelial-derived secreted factors, angiocrines, has revealed non-angiogenic mechanisms of endothelial cells in both physiological and pathological tissue remodeling. In the heart, ECs play a variety of important roles during cardiac development as well as in growth, homeostasis and regeneration of the adult heart. To date, several angiocrines affecting cardiomyocyte growth in response to physiological or pathological stimuli have been identified. In this review, we discuss the effects of angiogenesis and EC-mediated signaling in the regulation of cardiac hypertrophy. Identification of the molecular and metabolic signals from ECs during physiological and pathological cardiac growth could provide novel therapeutic targets to treat heart failure, as endothelium is emerging as one of the potential target organs in cardiovascular and metabolic diseases.

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Pathophysiology of Cardiac Toxicity

Farmakis

2022

Current Clinical Pathology

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Mechanisms of the Multitasking Endothelial Protein NRG-1 as a Compensatory Factor During Chronic Heart Failure

Cited by 50 publications

References 86 publications

Identification of candidate biomarkers and therapeutic agents for heart failure by bioinformatics analysis

Identification of candidate biomarkers and therapeutic agents for heart failure by bioinformatics analysis

Angiogenesis and angiocrines regulating heart growth

Pathophysiology of Cardiac Toxicity

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