Your search keyword '"Porrello, Enzo R."' showing total 26 results

1. 3D-cardiomics: A spatial transcriptional atlas of the mammalian heart.

Author

Mohenska M, Tan NM, Tokolyi A, Furtado MB, Costa MW, Perry AJ, Hatwell-Humble J, van Duijvenboden K, Nim HT, Ji YMM, Charitakis N, Bienroth D, Bolk F, Vivien C, Knaupp AS, Powell DR, Elliott DA, Porrello ER, Nilsson SK, Del Monte-Nieto G, Rosenthal NA, Rossello FJ, Polo JM, and Ramialison M

Subjects

Animals, Gene Expression Profiling methods, Mammals, Mice, Heart, Transcriptome

Abstract

Understanding the spatial gene expression and regulation in the heart is key to uncovering its developmental and physiological processes, during homeostasis and disease. Numerous techniques exist to gain gene expression and regulation information in organs such as the heart, but few utilize intuitive true-to-life three-dimensional representations to analyze and visualise results. Here we combined transcriptomics with 3D-modelling to interrogate spatial gene expression in the mammalian heart. For this, we microdissected and sequenced transcriptome-wide 18 anatomical sections of the adult mouse heart. Our study has unveiled known and novel genes that display complex spatial expression in the heart sub-compartments. We have also created 3D-cardiomics, an interface for spatial transcriptome analysis and visualization that allows the easy exploration of these data in a 3D model of the heart. 3D-cardiomics is accessible from http://3d-cardiomics.erc.monash.edu/., (Copyright © 2021. Published by Elsevier Ltd.)

Published

2022

2. From Fragrances to Heart Regeneration: Malonate Repairs Broken Hearts.

Author

McNamara JW and Porrello ER

Subjects

Humans, Malonates, Regeneration, Heart, Odorants

Published

2021

3. Sex-Specific Control of Human Heart Maturation by the Progesterone Receptor.

Author

Sim CB, Phipson B, Ziemann M, Rafehi H, Mills RJ, Watt KI, Abu-Bonsrah KD, Kalathur RKR, Voges HK, Dinh DT, Ter Huurne M, Vivien CJ, Kaspi A, Kaipananickal H, Hidalgo A, Delbridge LMD, Robker RL, Gregorevic P, Dos Remedios CG, Lal S, Piers AT, Konstantinov IE, Elliott DA, El-Osta A, Oshlack A, Hudson JE, and Porrello ER

Subjects

Female, Humans, Male, Sex Factors, Heart physiopathology, Receptors, Progesterone metabolism

Abstract

Background: Despite in-depth knowledge of the molecular mechanisms controlling embryonic heart development, little is known about the signals governing postnatal maturation of the human heart., Methods: Single-nucleus RNA sequencing of 54 140 nuclei from 9 human donors was used to profile transcriptional changes in diverse cardiac cell types during maturation from fetal stages to adulthood. Bulk RNA sequencing and the Assay for Transposase-Accessible Chromatin using sequencing were used to further validate transcriptional changes and to profile alterations in the chromatin accessibility landscape in purified cardiomyocyte nuclei from 21 human donors. Functional validation studies of sex steroids implicated in cardiac maturation were performed in human pluripotent stem cell-derived cardiac organoids and mice., Results: Our data identify the progesterone receptor as a key mediator of sex-dependent transcriptional programs during cardiomyocyte maturation. Functional validation studies in human cardiac organoids and mice demonstrate that the progesterone receptor drives sex-specific metabolic programs and maturation of cardiac contractile properties., Conclusions: These data provide a blueprint for understanding human heart maturation in both sexes and reveal an important role for the progesterone receptor in human heart development.

Published

2021

4. Upsizing Neonatal Heart Regeneration.

Author

Mahmoud AI and Porrello ER

Subjects

Animals, Myocardial Infarction, Swine, Heart, Regeneration

Published

2018

5. Multicellular Transcriptional Analysis of Mammalian Heart Regeneration.

Author

Quaife-Ryan GA, Sim CB, Ziemann M, Kaspi A, Rafehi H, Ramialison M, El-Osta A, Hudson JE, and Porrello ER

Subjects

Animals, Animals, Newborn, Fibroblasts cytology, Fibroblasts metabolism, Gene Expression Regulation, Developmental genetics, Gene Regulatory Networks, Leukocytes cytology, Leukocytes metabolism, Mice, Myocardial Infarction metabolism, Myocardial Infarction pathology, Myocytes, Cardiac cytology, Myocytes, Cardiac metabolism, RNA isolation & purification, RNA metabolism, Regeneration physiology, Sequence Analysis, RNA, Signal Transduction genetics, Transcription Factors genetics, Transcription Factors metabolism, Gene Expression Profiling, Heart physiology, Transcriptome

Abstract

Background: The inability of the adult mammalian heart to regenerate following injury represents a major barrier in cardiovascular medicine. In contrast, the neonatal mammalian heart retains a transient capacity for regeneration, which is lost shortly after birth. Defining the molecular mechanisms that govern regenerative capacity in the neonatal period remains a central goal in cardiac biology. Here, we assemble a transcriptomic framework of multiple cardiac cell populations during postnatal development and following injury, which enables comparative analyses of the regenerative (neonatal) versus nonregenerative (adult) state for the first time., Methods: Cardiomyocytes, fibroblasts, leukocytes, and endothelial cells from infarcted and noninfarcted neonatal (P1) and adult (P56) mouse hearts were isolated by enzymatic dissociation and fluorescence-activated cell sorting at day 3 following surgery. RNA sequencing was performed on these cell populations to generate the transcriptome of the major cardiac cell populations during cardiac development, repair, and regeneration. To complement our transcriptomic data, we also surveyed the epigenetic landscape of cardiomyocytes during postnatal maturation by performing deep sequencing of accessible chromatin regions by using the Assay for Transposase-Accessible Chromatin from purified mouse cardiomyocyte nuclei (P1, P14, and P56)., Results: Profiling of cardiomyocyte and nonmyocyte transcriptional programs uncovered several injury-responsive genes across regenerative and nonregenerative time points. However, the majority of transcriptional changes in all cardiac cell types resulted from developmental maturation from neonatal stages to adulthood rather than activation of a distinct regeneration-specific gene program. Furthermore, adult leukocytes and fibroblasts were characterized by the expression of a proliferative gene expression network following infarction, which mirrored the neonatal state. In contrast, cardiomyocytes failed to reactivate the neonatal proliferative network following infarction, which was associated with loss of chromatin accessibility around cell cycle genes during postnatal maturation., Conclusions: This work provides a comprehensive framework and transcriptional resource of multiple cardiac cell populations during cardiac development, repair, and regeneration. Our findings define a regulatory program underpinning the neonatal regenerative state and identify alterations in the chromatin landscape that could limit reinduction of the regenerative program in adult cardiomyocytes., (© 2017 The Authors.)

Published

2017

6. Cavin-1 deficiency modifies myocardial and coronary function, stretch responses and ischaemic tolerance: roles of NOS over-activity.

Author

Kaakinen M, Reichelt ME, Ma Z, Ferguson C, Martel N, Porrello ER, Hudson JE, Thomas WG, Parton RG, and Headrick JP

Subjects

Animals, Blotting, Western, Cardiovascular Physiological Phenomena, Disease Models, Animal, Isolated Heart Preparation, Mice, Mice, Inbred C57BL, Mice, Knockout, Myocardial Contraction physiology, Myocardial Reperfusion Injury physiopathology, Nitric Oxide Synthase metabolism, Polymerase Chain Reaction, Stress, Mechanical, Heart physiology, Membrane Proteins metabolism, Myocardial Reperfusion Injury metabolism, Myocardium metabolism, RNA-Binding Proteins metabolism

Abstract

Caveolae and associated cavin and caveolins may govern myocardial function, together with responses to mechanical and ischaemic stresses. Abnormalities in these proteins are also implicated in different cardiovascular disorders. However, specific roles of the cavin-1 protein in cardiac and coronary responses to mechanical/metabolic perturbation remain unclear. We characterised cardiovascular impacts of cavin-1 deficiency, comparing myocardial and coronary phenotypes and responses to stretch and ischaemia-reperfusion in hearts from cavin-1 +/+ and cavin-1 -/- mice. Caveolae and caveolins 1 and 3 were depleted in cavin-1 -/- hearts. Cardiac ejection properties in situ were modestly reduced in cavin-1 -/- mice. While peak contractile performance in ex vivo myocardium from cavin-1 -/- and cavin-1 +/+ mice was comparable, intrinsic beating rate, diastolic stiffness and Frank-Starling behaviour (stretch-dependent diastolic and systolic forces) were exaggerated in cavin-1 -/- hearts. Increases in stretch-dependent forces were countered by NOS inhibition (100 µM L-NAME), which exposed negative inotropy in cavin-1 -/- hearts, and were mimicked by 100 µM nitroprusside. In contrast, chronotropic differences appeared largely NOS-independent. Cavin-1 deletion also induced NOS-dependent coronary dilatation, ≥3-fold prolongation of reactive hyperaemic responses, and exaggerated pressure-dependence of coronary flow. Stretch-dependent efflux of lactate dehydrogenase and cardiac troponin I was increased and induction of brain natriuretic peptide and c-Fos inhibited in cavin-1 -/- hearts, while ERK1/2 phospho-activation was preserved. Post-ischaemic dysfunction and damage was also exaggerated in cavin-1 -/- hearts. Diverse effects of cavin-1 deletion reveal important roles in both NOS-dependent and -independent control of cardiac and coronary functions, together with governing sarcolemmal fragility and myocardial responses to stretch and ischaemia.

Published

2017

7. Periostin paves the way for neonatal heart regeneration.

Author

Hudson JE and Porrello ER

Subjects

Animals, Mice, Animals, Newborn, Glycogen Synthase Kinase 3 beta, Infarction, Phosphatidylinositol 3-Kinases, Disease Models, Animal, Cyclin D1, Heart physiology, Regeneration

Published

2017

8. Development of a human cardiac organoid injury model reveals innate regenerative potential.

Author

Voges HK, Mills RJ, Elliott DA, Parton RG, Porrello ER, and Hudson JE

Subjects

Adult, Cell Death, Cell Differentiation, Cell Line, Cell Proliferation, Freezing, Heart Function Tests, Heart Injuries pathology, Humans, Hypertrophy, Myocardial Contraction, Myocardium pathology, Myocytes, Cardiac cytology, Organoids ultrastructure, Recovery of Function, Heart embryology, Heart physiopathology, Heart Injuries physiopathology, Models, Biological, Organoids embryology, Regeneration

Abstract

The adult human heart possesses a limited regenerative potential following an ischemic event, and undergoes a number of pathological changes in response to injury. Although cardiac regeneration has been documented in zebrafish and neonatal mouse hearts, it is currently unknown whether the immature human heart is capable of undergoing complete regeneration. Combined progress in pluripotent stem cell differentiation and tissue engineering has facilitated the development of human cardiac organoids (hCOs), which resemble fetal heart tissue and can be used to address this important knowledge gap. This study aimed to characterize the regenerative capacity of immature human heart tissue in response to injury. Following cryoinjury with a dry ice probe, hCOs exhibited an endogenous regenerative response with full functional recovery 2 weeks after acute injury. Cardiac functional recovery occurred in the absence of pathological fibrosis or cardiomyocyte hypertrophy. Consistent with regenerative organisms and neonatal human hearts, there was a high basal level of cardiomyocyte proliferation, which may be responsible for the regenerative capacity of the hCOs. This study suggests that immature human heart tissue has an intrinsic capacity to regenerate., (© 2017. Published by The Company of Biologists Ltd.)

Published

2017

9. Resetting the epigenome for heart regeneration.

Author

Quaife-Ryan GA, Sim CB, Porrello ER, and Hudson JE

Subjects

Animals, Cellular Reprogramming genetics, DNA Methylation genetics, Heart embryology, Models, Genetic, Regeneration genetics, Epigenesis, Genetic, Heart physiology, Regeneration physiology

Abstract

In contrast to adults, recent evidence suggests that neonatal mice are able to regenerate following cardiac injury. This regenerative capacity is reliant on robust induction of cardiomyocyte proliferation, which is required for faithful regeneration of the heart following injury. However, cardiac regenerative potential is lost as cardiomyocytes mature and permanently withdraw from the cell cycle shortly after birth. Recently, a handful of factors responsible for the regenerative disparity between the adult and neonatal heart have been identified, but the proliferative response of adult cardiomyocytes following modulation of these factors rarely reaches neonatal levels. The inefficient re-induction of proliferation in adult cardiomyocytes may be due to the epigenetic landscape, which drastically changes during cardiac development and maturation. In this review, we provide an overview of the role of epigenetic modifiers in developmental processes related to cardiac regeneration. We propose an epigenetic framework for heart regeneration whereby adult cardiomyocyte identity requires resetting to a neonatal-like state to facilitate cell cycle re-entry and regeneration following cardiac injury., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2016

10. Cardiac gene expression data and in silico analysis provide novel insights into human and mouse taste receptor gene regulation.

Author

Foster SR, Porrello ER, Stefani M, Smith NJ, Molenaar P, dos Remedios CG, Thomas WG, and Ramialison M

Subjects

Adolescent, Adult, Aged, Animals, Binding Sites, Child, Child, Preschool, Computational Biology, Computer Simulation, Female, Humans, Male, Mice, Mice, Transgenic, Middle Aged, Promoter Regions, Genetic, Young Adult, Gene Expression Regulation, Heart physiology, Receptors, G-Protein-Coupled genetics, Taste genetics

Abstract

G protein-coupled receptors are the principal mediators of the sweet, umami, bitter, and fat taste qualities in mammals. Intriguingly, the taste receptors are also expressed outside of the oral cavity, including in the gut, airways, brain, and heart, where they have additional functions and contribute to disease. However, there is little known about the mechanisms governing the transcriptional regulation of taste receptor genes. Following our recent delineation of taste receptors in the heart, we investigated the genomic loci encoding for taste receptors to gain insight into the regulatory mechanisms that drive their expression in the heart. Gene expression analyses of healthy and diseased human and mouse hearts showed coordinated expression for a subset of chromosomally clustered taste receptors. This chromosomal clustering mirrored the cardiac expression profile, suggesting that a common gene regulatory block may control the taste receptor locus. We identified unique domains with strong regulatory potential in the vicinity of taste receptor genes. We also performed de novo motif enrichment in the proximal promoter regions and found several overrepresented DNA motifs in cardiac taste receptor gene promoters corresponding to ubiquitous and cardiac-specific transcription factor binding sites. Thus, combining cardiac gene expression data with bioinformatic analyses, this study has provided insights into the noncoding regulatory landscape for taste GPCRs. These findings also have broader relevance for the study of taste GPCRs outside of the classical gustatory system, where understanding the mechanisms controlling the expression of these receptors may have implications for future therapeutic development.

Published

2015

11. Regulation of microRNA during cardiomyocyte maturation in sheep.

Author

Morrison JL, Zhang S, Tellam RL, Brooks DA, McMillen IC, Porrello ER, and Botting KJ

Subjects

Animals, Cell Proliferation genetics, Gene Expression Profiling, Gene Expression Regulation, Developmental, Humans, MicroRNAs biosynthesis, Microarray Analysis, RNA, Messenger genetics, Sheep growth & development, Heart growth & development, MicroRNAs genetics, Myocytes, Cardiac physiology, Sheep genetics

Abstract

Background: There is a limited capacity to repair damage in the mammalian heart after birth, which is primarily due to the inability of cardiomyocytes to proliferate after birth. This is in contrast to zebrafish and salamander, in which cardiomyocytes retain the ability to proliferate throughout life and can regenerate their heart after significant damage. Recent studies in zebrafish and rodents implicate microRNA (miRNA) in the regulation of genes responsible for cardiac cell cycle progression and regeneration, in particular, miR-133a, the miR-15 family, miR-199a and miR-590. However, the significance of these miRNA and miRNA in general in the regulation of cardiomyocyte proliferation in large mammals, including humans, where the timing of heart development relative to birth is very different than in rodents, is unclear. To determine the involvement of miRNA in the down-regulation of cardiomyocyte proliferation occurring before birth in large mammals, we investigated miRNA and target gene expression in sheep hearts before and after birth. The experimental approach included targeted transcriptional profiling of miRNA and target mRNA previously identified in rodent studies as well as genome-wide miRNA profiling using microarrays., Results: The cardiac expression of miR-133a increased and its target gene IGF1R decreased with increasing age, reaching their respective maximum and minimum abundance when the majority of ovine cardiomyocytes were quiescent. The expression of the miR-15 family members was variable with age, however, four of their target genes decreased with age. These latter profiles are inconsistent with the direct involvement of this family of miRNA in cardiomyocyte quiescence in late gestation sheep. The expression patterns of 'pro-proliferative' miR-199a and miR-590 were also inconsistent with their involvement in cardiomyocyte quiescence. Consequently, miRNA microarray analysis was undertaken, which identified six discrete clusters of miRNA with characteristic developmental profiles. The functions of predicted target genes for the miRNA in four of the six clusters were enriched for aspects of cell division and regulation of cell proliferation suggesting a potential role of these miRNA in regulating cardiomyocyte proliferation., Conclusion: The results of this study show that the expression of miR-133a and one of its target genes is consistent with it being involved in the suppression of cardiomyocyte proliferation, which occurs across the last third of gestation in sheep. The expression patterns of the miR-15 family, miR-199a and miR-590 were inconsistent with direct involvement in the regulation cardiomyocyte proliferation in sheep, despite studies in rodents demonstrating that their manipulation can influence the degree of cardiomyocyte proliferation. miRNA microarray analysis suggests a coordinated and potentially more complex role of multiple miRNA in the regulation of cardiomyocyte quiescence and highlights significant differences between species that may reflect their substantial differences in the timing of this developmental process.

Published

2015

12. Dynamic changes in the cardiac methylome during postnatal development.

Author

Sim CB, Ziemann M, Kaspi A, Harikrishnan KN, Ooi J, Khurana I, Chang L, Hudson JE, El-Osta A, and Porrello ER

Subjects

Animals, Animals, Newborn, Azacitidine analogs & derivatives, Azacitidine pharmacology, Cell Cycle Checkpoints, Cell-Penetrating Peptides, Decitabine, Epigenesis, Genetic, Gene Expression Regulation, Developmental, Male, Mice, Mice, Inbred C57BL, Mice, Inbred ICR, Myocytes, Cardiac cytology, Myocytes, Cardiac drug effects, Myocytes, Cardiac metabolism, Signal Transduction, DNA Methylation drug effects, Heart growth & development, Myocardium metabolism

Abstract

Relatively little is known about the epigenetic control mechanisms that guide postnatal organ maturation. The goal of this study was to determine whether DNA methylation plays an important role in guiding transcriptional changes during the first 2 wk of mouse heart development, which is an important period for cardiomyocyte maturation, loss of proliferative capacity and loss of regenerative potential. Gene expression profiling (RNA-seq) and genome-wide sequencing of methylated DNA (MBD-seq) identified dynamic changes in the cardiac methylome during postnatal development [2545 differentially methylated regions (DMRs) from P1 to P14 in the mouse]. The vast majority (~80%) of DMRs were hypermethylated between P1 and P14, and these hypermethylated regions were associated with transcriptional shut down of important developmental signaling pathways, including Hedgehog, bone morphogenetic protein, TGF-β, fibroblast growth factor, and Wnt/β-catenin signaling. Postnatal inhibition of DNA methylation with 5-aza-2'-deoxycytidine induced a marked increase (~3-fold) in cardiomyocyte proliferation and ~50% reduction in the percentage of binucleated cardiomyocytes compared with saline-treated controls. This study provides novel evidence for widespread alterations in DNA methylation during postnatal heart maturation and suggests that cardiomyocyte cell cycle arrest during the neonatal period is subject to regulation by DNA methylation., (© FASEB.)

Published

2015

13. Therapeutic silencing of miR-652 restores heart function and attenuates adverse remodeling in a setting of established pathological hypertrophy.

Author

Bernardo BC, Nguyen SS, Winbanks CE, Gao XM, Boey EJ, Tham YK, Kiriazis H, Ooi JY, Porrello ER, Igoor S, Thomas CJ, Gregorevic P, Lin RC, Du XJ, and McMullen JR

Subjects

Animals, Cells, Cultured, Mice, Rats, Rats, Sprague-Dawley, Real-Time Polymerase Chain Reaction, Cardiomegaly genetics, Gene Silencing, Heart physiopathology, MicroRNAs genetics

Abstract

Expression of microRNA-652 (miR-652) increases in the diseased heart, decreases in a setting of cardioprotection, and is inversely correlated with heart function. The aim of this study was to assess the therapeutic potential of inhibiting miR-652 in a mouse model with established pathological hypertrophy and cardiac dysfunction due to pressure overload. Mice were subjected to a sham operation or transverse aortic constriction (TAC) for 4 wk to induce hypertrophy and cardiac dysfunction, followed by administration of a locked nucleic acid (LNA)-antimiR-652 (miR-652 inhibitor) or LNA control. Cardiac function was assessed before and 8 wk post-treatment. Expression of miR-652 increased in hearts subjected to TAC compared to sham surgery (2.9-fold), and this was suppressed by ∼95% in LNA-antimiR-652-treated TAC mice. Inhibition of miR-652 improved cardiac function in TAC mice (fractional shortening:29±1% at 4 wk post-TAC compared to 35±1% post-treatment) and attenuated cardiac hypertrophy. Improvement in heart function was associated with reduced cardiac fibrosis, less apoptosis and B-type natriuretic peptide gene expression, and preserved angiogenesis. Mechanistically, we identified Jagged1 (a Notch1 ligand) as a novel direct target of miR-652. In summary, these studies provide the first evidence that silencing of miR-652 protects the heart against pathological remodeling and improves heart function., (© FASEB.)

Published

2014

14. A neonatal blueprint for cardiac regeneration.

Author

Porrello ER and Olson EN

Subjects

Animals, Animals, Newborn, Cell Proliferation, Humans, Mice, Myocardium cytology, Myocardium metabolism, Heart physiology, Regeneration

Abstract

Adult mammals undergo minimal regeneration following cardiac injury, which severely compromises cardiac function and contributes to the ongoing burden of heart failure. In contrast, the mammalian heart retains a transient capacity for cardiac regeneration during fetal and early neonatal life. Recent studies have established the importance of several evolutionarily conserved mechanisms for heart regeneration in lower vertebrates and neonatal mammals including induction of cardiomyocyte proliferation, epicardial cell activation, angiogenesis, extracellular matrix deposition and immune cell infiltration. In this review, we provide an up-to-date account of the molecular and cellular basis for cardiac regeneration in lower vertebrates and neonatal mammals. The historical context for these recent findings and their ramifications for the future development of cardiac regenerative therapies are also discussed., (Copyright © 2014. Published by Elsevier B.V.)

Published

2014

15. Macrophages are required for neonatal heart regeneration.

Author

Aurora AB, Porrello ER, Tan W, Mahmoud AI, Hill JA, Bassel-Duby R, Sadek HA, and Olson EN

Subjects

Animals, Animals, Newborn, Cell Proliferation, Coronary Vessels physiopathology, Mice, Mice, Inbred ICR, Myocardial Infarction immunology, Myocardial Infarction pathology, Myocardial Infarction physiopathology, Myocytes, Cardiac physiology, Neovascularization, Physiologic, Transcriptome, Heart physiology, Macrophages physiology, Regeneration immunology

Abstract

Myocardial infarction (MI) leads to cardiomyocyte death, which triggers an immune response that clears debris and restores tissue integrity. In the adult heart, the immune system facilitates scar formation, which repairs the damaged myocardium but compromises cardiac function. In neonatal mice, the heart can regenerate fully without scarring following MI; however, this regenerative capacity is lost by P7. The signals that govern neonatal heart regeneration are unknown. By comparing the immune response to MI in mice at P1 and P14, we identified differences in the magnitude and kinetics of monocyte and macrophage responses to injury. Using a cell-depletion model, we determined that heart regeneration and neoangiogenesis following MI depends on neonatal macrophages. Neonates depleted of macrophages were unable to regenerate myocardia and formed fibrotic scars, resulting in reduced cardiac function and angiogenesis. Immunophenotyping and gene expression profiling of cardiac macrophages from regenerating and nonregenerating hearts indicated that regenerative macrophages have a unique polarization phenotype and secrete numerous soluble factors that may facilitate the formation of new myocardium. Our findings suggest that macrophages provide necessary signals to drive angiogenesis and regeneration of the neonatal mouse heart. Modulating inflammation may provide a key therapeutic strategy to support heart regeneration.

Published

2014

16. Surgical models for cardiac regeneration in neonatal mice.

Author

Mahmoud AI, Porrello ER, Kimura W, Olson EN, and Sadek HA

Subjects

Animals, Heart Injuries surgery, Mice, Animals, Newborn physiology, Cardiac Surgical Procedures methods, Heart physiology, Models, Animal, Regeneration physiology

Abstract

Although amphibian and fish models of heart regeneration have existed for decades, a mammalian equivalent has long remained elusive. Our discovery of a brief postnatal window for heart regeneration in neonatal mice has led to the establishment of surgical models for cardiac regenerative studies in mammals for the first time. This protocol describes a 10-min surgical procedure to induce cardiac injury in 1-d-old neonatal mice. This allows for the analysis of cardiac regeneration after surgical amputation of the left ventricle (LV) (apical resection) and coronary artery occlusion (myocardial infarction (MI)). A comparative analysis of neonatal and adult responses to myocardial injury should enable identification of the key differences between regenerative and nonregenerative responses to cardiac injury. This protocol can also be adapted to the growing repertoire of genetic models available in the mouse, and it provides a valuable tool for unlocking the molecular mechanisms that guide mammalian heart regeneration during early postnatal life.

Published

2014

17. Hippo pathway effector Yap promotes cardiac regeneration.

Author

Xin M, Kim Y, Sutherland LB, Murakami M, Qi X, McAnally J, Porrello ER, Mahmoud AI, Tan W, Shelton JM, Richardson JA, Sadek HA, Bassel-Duby R, and Olson EN

Subjects

Acyltransferases, Adaptor Proteins, Signal Transducing genetics, Animals, Blotting, Western, Cell Cycle Proteins, DNA Primers genetics, Echocardiography, Hippo Signaling Pathway, Histological Techniques, Mice, Mice, Transgenic, Mutation, Missense genetics, Myocardial Contraction genetics, Myocardial Contraction physiology, Myocytes, Cardiac metabolism, Phosphoproteins genetics, Protein Serine-Threonine Kinases metabolism, Tetrazolium Salts, Transcription Factors genetics, YAP-Signaling Proteins, Adaptor Proteins, Signal Transducing metabolism, Heart physiology, Myocytes, Cardiac physiology, Phosphoproteins metabolism, Regeneration physiology, Signal Transduction physiology, Transcription Factors metabolism

Abstract

The adult mammalian heart has limited potential for regeneration. Thus, after injury, cardiomyocytes are permanently lost, and contractility is diminished. In contrast, the neonatal heart can regenerate owing to sustained cardiomyocyte proliferation. Identification of critical regulators of cardiomyocyte proliferation and quiescence represents an important step toward potential regenerative therapies. Yes-associated protein (Yap), a transcriptional cofactor in the Hippo signaling pathway, promotes proliferation of embryonic cardiomyocytes by activating the insulin-like growth factor and Wnt signaling pathways. Here we report that mice bearing mutant alleles of Yap and its paralog WW domain containing transcription regulator 1 (Taz) exhibit gene dosage-dependent cardiac phenotypes, suggesting redundant roles of these Hippo pathway effectors in establishing proper myocyte number and maintaining cardiac function. Cardiac-specific deletion of Yap impedes neonatal heart regeneration, resulting in a default fibrotic response. Conversely, forced expression of a constitutively active form of Yap in the adult heart stimulates cardiac regeneration and improves contractility after myocardial infarction. The regenerative activity of Yap is correlated with its activation of embryonic and proliferative gene programs in cardiomyocytes. These findings identify Yap as an important regulator of cardiac regeneration and provide an experimental entry point to enhance this process., Competing Interests: The authors declare no conflict of interest.

Published

2013

18. microRNAs in cardiac development and regeneration.

Author

Porrello ER

Subjects

Animals, Heart physiology, Heart Defects, Congenital genetics, Heart Defects, Congenital pathology, Humans, MicroRNAs genetics, Morphogenesis, Myocytes, Cardiac pathology, Signal Transduction, Stem Cells pathology, Heart embryology, Heart growth & development, MicroRNAs physiology, Regeneration

Abstract

Heart development involves the precise orchestration of gene expression during cardiac differentiation and morphogenesis by evolutionarily conserved regulatory networks. miRNAs (microRNAs) play important roles in the post-transcriptional regulation of gene expression, and recent studies have established critical functions for these tiny RNAs in almost every facet of cardiac development and disease. The realization that miRNAs are amenable to therapeutic manipulation has also generated considerable interest in the potential of miRNA-based drugs for the treatment of a number of human diseases, including cardiovascular disease. In the present review, I discuss well-established and emerging roles of miRNAs in cardiac development, their relevance to congenital heart disease and unresolved questions in the field for future investigation, as well as emerging therapeutic possibilities for cardiac regeneration.

Published

2013

19. Regulation of neonatal and adult mammalian heart regeneration by the miR-15 family.

Author

Porrello ER, Mahmoud AI, Simpson E, Johnson BA, Grinsfelder D, Canseco D, Mammen PP, Rothermel BA, Olson EN, and Sadek HA

Subjects

Animals, Animals, Newborn, Cell Proliferation, Coronary Vessels surgery, Galactosides, Image Processing, Computer-Assisted, Indoles, Ligation, Mice, MicroRNAs physiology, Myocardial Infarction etiology, Myocytes, Cardiac physiology, Gene Expression Regulation, Developmental physiology, Heart physiology, MicroRNAs metabolism, Myocardial Infarction physiopathology, Myocardial Ischemia complications, Regeneration physiology

Abstract

We recently identified a brief time period during postnatal development when the mammalian heart retains significant regenerative potential after amputation of the ventricular apex. However, one major unresolved question is whether the neonatal mouse heart can also regenerate in response to myocardial ischemia, the most common antecedent of heart failure in humans. Here, we induced ischemic myocardial infarction (MI) in 1-d-old mice and found that this results in extensive myocardial necrosis and systolic dysfunction. Remarkably, the neonatal heart mounted a robust regenerative response, through proliferation of preexisting cardiomyocytes, resulting in full functional recovery within 21 d. Moreover, we show that the miR-15 family of microRNAs modulates neonatal heart regeneration through inhibition of postnatal cardiomyocyte proliferation. Finally, we demonstrate that inhibition of the miR-15 family from an early postnatal age until adulthood increases myocyte proliferation in the adult heart and improves left ventricular systolic function after adult MI. We conclude that the neonatal mammalian heart can regenerate after myocardial infarction through proliferation of preexisting cardiomyocytes and that the miR-15 family contributes to postnatal loss of cardiac regenerative capacity.

Published

2013

20. Turning back the cardiac regenerative clock: lessons from the neonate.

Author

Mahmoud AI and Porrello ER

Subjects

Adult, Amphibians, Animals, Animals, Newborn, Biological Evolution, Cell Lineage, Cell Proliferation, Heart Injuries therapy, Humans, Infant, Newborn, Mammals, Mice, Myocytes, Cardiac physiology, Phylogeny, Zebrafish, Heart physiology, Regeneration, Regenerative Medicine methods

Abstract

The adult mammalian heart has an extremely limited capacity for regeneration. As a consequence, ischemic heart disease remains the leading cause of death in the developed world, and the heart continues to be a major focal point for regenerative medicine. Understanding innate mechanisms of heart regeneration is important and may provide a blueprint for clinical translation. For example, urodele amphibians and teleost fish can mount an endogenous regenerative response following multiple forms of cardiac injury, and this regenerative response appears to be mediated through proliferation of pre-existing cardiomyocytes. How and why mammals have lost the capacity for heart regeneration since the divergence from teleost fish more than 450 million years ago has been a major unresolved question in the field. Recent studies in mice indicate that the mammalian heart possesses significant regenerative potential during embryonic and neonatal life, but this regenerative capacity is lost rapidly after birth. This review focuses on mechanisms of heart regeneration in neonatal mice, with a particular emphasis on similarities and differences with the zebrafish model. Recent advances in our understanding of the molecular mechanisms of postnatal heart maturation and regenerative arrest are also highlighted. The possibility of recapitulating ontogenetically and phylogenetically ancient mechanisms of cardiac regeneration in the adult human heart represents an exciting new frontier in cardiology., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

21. Transient regenerative potential of the neonatal mouse heart.

Author

Porrello ER, Mahmoud AI, Simpson E, Hill JA, Richardson JA, Olson EN, and Sadek HA

Subjects

Aging, Animals, Animals, Newborn, Cardiomegaly, Cell Lineage, Cell Proliferation, Echocardiography, Fibrosis, Heart Ventricles surgery, Mice, Myocardial Contraction, Myocardium pathology, Sarcomeres ultrastructure, Stroke Volume, Heart physiology, Myocytes, Cardiac physiology, Regeneration

Abstract

Certain fish and amphibians retain a robust capacity for cardiac regeneration throughout life, but the same is not true of the adult mammalian heart. Whether the capacity for cardiac regeneration is absent in mammals or whether it exists and is switched off early after birth has been unclear. We found that the hearts of 1-day-old neonatal mice can regenerate after partial surgical resection, but this capacity is lost by 7 days of age. This regenerative response in 1-day-old mice was characterized by cardiomyocyte proliferation with minimal hypertrophy or fibrosis, thereby distinguishing it from repair processes. Genetic fate mapping indicated that the majority of cardiomyocytes within the regenerated tissue originated from preexisting cardiomyocytes. Echocardiography performed 2 months after surgery revealed that the regenerated ventricular apex had normal systolic function. Thus, for a brief period after birth, the mammalian heart appears to have the capacity to regenerate.

Published

2011

22. Building a new heart from old parts: stem cell turnover in the aging heart.

Author

Porrello ER and Olson EN

Subjects

Adult, Age Factors, Aged, Aged, 80 and over, Animals, Humans, Middle Aged, Myocytes, Cardiac physiology, Sex Factors, Stem Cells physiology, Young Adult, Aging physiology, Heart anatomy & histology, Heart physiology, Myocytes, Cardiac cytology, Stem Cells cytology

Published

2010

23. Heritable pathologic cardiac hypertrophy in adulthood is preceded by neonatal cardiac growth restriction.

Author

Porrello ER, Bell JR, Schertzer JD, Curl CL, McMullen JR, Mellor KM, Ritchie RH, Lynch GS, Harrap SB, Thomas WG, and Delbridge LM

Subjects

Animals, Apoptosis drug effects, Blotting, Western, Calcineurin physiology, Cell Nucleus ultrastructure, Cell Proliferation, Cell Survival physiology, Disease Progression, Extracellular Signal-Regulated MAP Kinases physiology, In Situ Nick-End Labeling, In Vitro Techniques, Longevity, Mitogen-Activated Protein Kinases physiology, Myocardium pathology, Myocytes, Cardiac pathology, Myocytes, Cardiac physiology, Myocytes, Cardiac ultrastructure, Rats, Rats, Inbred SHR, Reverse Transcriptase Polymerase Chain Reaction, Animals, Newborn physiology, Cardiomegaly genetics, Cardiomegaly pathology, Heart growth & development

Abstract

The identification of genetic factors influencing cardiac growth independently of increased load is crucial to an understanding of the molecular and cellular basis of pathological cardiac hypertrophy. The central aim of this investigation was to determine how pathological hypertrophy in the adult can be linked with disturbances in cardiomyocyte growth and viability in early neonatal development. The hypertrophic heart rat (HHR) model is derived from the spontaneously hypertensive rat and exhibits marked cardiac hypertrophy, in the absence of a pressure load at maturity. Hearts were harvested from male HHR, and control strain normal heart rats (NHR), at different stages of postnatal development [neonatal (P2), 4 wk, 6 wk, 8 wk, 12 wk, 20 wk]. Isolated neonatal cardiomyocytes were prepared to evaluate cell size, number, and binucleation. At postnatal day 2, HHR hearts were considerably smaller than control NHR (4.3 +/- 0.2 vs. 5.0 +/- 0.1 mg/g, P < 0.05). Cardiac growth restriction in the neonatal HHR was associated with reduced myocyte size (length and width) and an increased proportion of binucleated cardiomyocytes. Furthermore, the number of cardiomyocytes isolated from HHR neonatal hearts was significantly less ( approximately 29%) than NHR. We also observe that growth stress in the neonate is associated with accentuated PI3K and suppressed MAPK activation, although these signaling pathways are normalized in the adult heart exhibiting established hypertrophy. Thus, using the HHR model, we identified novel molecular and cellular mechanisms involving premature exit from the cell cycle, reduced cardiomyocyte endowment, and dysregulated trophic signaling during early development, which are implicated in the etiology of heritable cardiac hypertrophy in the adult.

Published

2009

24. Early origins of cardiac hypertrophy: does cardiomyocyte attrition programme for pathological 'catch-up' growth of the heart?

Author

Porrello ER, Widdop RE, and Delbridge LM

Subjects

Animals, Cell Death physiology, Humans, Myocardium cytology, Myocytes, Cardiac cytology, Myocytes, Cardiac physiology, Cardiomegaly pathology, Heart growth & development, Myocardium pathology, Myocytes, Cardiac pathology

Abstract

1. Epidemiological and experimental evidence suggests that adult development of cardiovascular disease is influenced by events of prenatal and early postnatal life. Cardiac hypertrophy is recognized as an important predictor of cardiovascular morbidity and mortality, but the developmental origins of this condition are not well understood. 2. In the heart, a switch from hyperplastic to hypertrophic cellular growth occurs during late prenatal or early postnatal life. Postnatal growth of the heart is almost entirely reliant on hypertrophy of individual cardiomyocytes, and damage to heart muscle in adulthood is typically not reparable by cell replacement. Therefore, a reduced number of cardiomyocytes may render the heart more vulnerable in situations where an increased workload is required. 3. A number of different animal models have been used to study fetal programming of adult diseases, including nutritional, hypoxic, maternal/neonatal endocrine stress and genetic models. Although studies investigating the cellular basis of myocardial disease in growth-restricted models are limited, a reduction in cardiomyocyte number through either reduced cellular proliferation or increased apoptosis appears to be a central feature. 4. The mechanisms responsible for the programming of adult cardiovascular disease are poorly understood. We hypothesize that cardiac hypertrophy can have a developmental origin in excess cardiomyocyte attrition during a critical perinatal growth window. Findings that have directly assessed the impact of fetal growth restriction on the myocardium are considered and cellular and molecular mechanisms involved in the potential pathological 'catch-up' growth of the heart during later maturation are identified.

Published

2008

25. Reactivation of Myc transcription in the mouse heart unlocks its proliferative capacity.

Author

Bywater, Megan J., Burkhart, Deborah L., Straube, Jasmin, Sabò, Arianna, Pendino, Vera, Hudson, James E., Quaife-Ryan, Gregory A., Porrello, Enzo R., Rae, James, Parton, Robert G., Kress, Theresia R., Amati, Bruno, Littlewood, Trevor D., Evan, Gerard I., and Wilson, Catherine H.

Subjects

HEART, TRANSCRIPTION factors, MICE, TRANSGENIC organisms, LIVER

Abstract

It is unclear why some tissues are refractory to the mitogenic effects of the oncogene Myc. Here we show that Myc activation induces rapid transcriptional responses followed by proliferation in some, but not all, organs. Despite such disparities in proliferative response, Myc is bound to DNA at open elements in responsive (liver) and non-responsive (heart) tissues, but fails to induce a robust transcriptional and proliferative response in the heart. Using heart as an exemplar of a non-responsive tissue, we show that Myc-driven transcription is re-engaged in mature cardiomyocytes by elevating levels of the positive transcription elongation factor (P-TEFb), instating a large proliferative response. Hence, P-TEFb activity is a key limiting determinant of whether the heart is permissive for Myc transcriptional activation. These data provide a greater understanding of how Myc transcriptional activity is determined and indicate modification of P-TEFb levels could be utilised to drive regeneration of adult cardiomyocytes for the treatment of heart myopathies. Levels of the transcription factor Myc are deregulated in a range of different cancers. Here the authors show that Myc induces rapid transcriptional responses in some mouse tissues (liver), but not others (heart), and that transcriptional and proliferative responses in cardiomyocytes depend on the positive transcription elongation factor (P-TEFb). [ABSTRACT FROM AUTHOR]

Published

2020

26. Maternal Vitamin D Deficiency Leads to Cardiac Hypertrophy in Rat Offspring.

Author

Gezmish, Oksan, Tare, Marianne, Parkington, Helena C., Morley, Ruth, Porrello, Enzo R., Bubb, Kristen J., and Black, Mary Jane

Subjects

VITAMIN D deficiency, NUTRITION in pregnancy, CARDIAC hypertrophy, RAT reproduction, LACTATION, HEART cells, LEFT heart ventricle, HEART dilatation

Abstract

The aim of this study was to determine the effect of vitamin D deficiency from conception until 4 weeks of age on the development of the heart in rat offspring. Sprague-Dawley (SD) rats were fed either a vitamin D deplete or vitamin D-replete diet for 6 weeks prior to pregnancy, during pregnancy and throughout lactation. Cardiomyocyte number was determined in fixed hearts of offspring at postnatal day 3 and 4 weeks of age using an optical disector/fractionator stereological technique. In other litters, cardiomyocytes were isolated from freshly excised hearts to determine the proportion of mononucleated and binucleated cardiomyocytes. Maternal vitamin D deficiency had no effect on cardiomyocyte number, cardiomyocyte area, or the proportion of mononucleated/binucleated cardiomyocytes in 3-day-old male and female offspring. Importantly, however, vitamin D deficiency led to an increase in left ventricle (LV) volume that was accompanied by an increase in cardiomyocyte number and size, and in the proportion of mononucleated cardiomyocytes at 4 weeks of age. Our findings suggest that exposure to vitamin D deficiency in utero and early life leads to delayed maturation and subsequent enhanced growth (proliferation and hypertrophy) of cardiomyocytes in the LV. This may lead to altered cardiac function later in life. [ABSTRACT FROM AUTHOR]

Published

2010