Developing Mouse Heart Research Articles

Cyclin‐dependent kinase 13 is indispensable for normal mouse heart development

AbstractCongenital heart disease (CHD) has an incidence of approximately 1%. Over the last decade, sequencing studies including large cohorts of individuals with CHD have begun to unravel the genetic mechanisms underpinning CHD. This includes the identification of variants in cyclin‐dependent kinase 13 (CDK13), in individuals with syndromic CHD. CDK13 encodes a serine/threonine protein kinase. The cyclin partner of CDK13 is cyclin K; this complex is thought to be important in transcription and RNA processing. Pathogenic variants in CDK13 cause CDK13‐related disorder in humans, characterised by intellectual disability and developmental delay, recognisable facial features, feeding difficulties and structural brain defects, with 35% of individuals having CHD. To obtain a greater understanding for the role that this essential protein kinase plays in embryonic heart development, we have analysed a presumed loss of function Cdk13 transgenic mouse model (Cdk13tm1b). The homozygous mutants were embryonically lethal in most cases by E15.5. X‐gal staining showed Cdk13 expression localised to developing facial regions, heart and surrounding areas at E10.5, whereas at E12.5, it was more widely present. In the E15.5 heart, staining was seen throughout. RT‐qPCR showed significant reduction in Cdk13 transcript expression in homozygous compared with WT and heterozygous hearts at E10.5 and E12.5. Detailed morphological 3D analysis of embryonic and postnatal hearts was performed using high‐resolution episcopic microscopy, which affords a more detailed analysis of structures such as cardiac valve leaflets and endocardial cushions, compared with more traditional histological techniques. We show that both the homozygous and heterozygous Cdk13tm1b mutants exhibit a range of CHD, including ventricular septal defects, bicuspid aortic valve, double outlet right ventricle and atrioventricular septal defects. 100% (n = 4) of homozygous hearts displayed CHD. Differential expression was seen in Cdk13tm1b homozygous mutants for two genes known to be necessary for normal heart development. The types of defects, and the presence of CHD in heterozygous mice (17.02%, n = 8/47), are consistent with the CDK13‐related disorder phenotype in humans. This study provides important insights into the effects of reduced function of CDK13 in the mouse heart and contributes to our understanding of the mechanism behind this disorder as a cause of CHD.

NOTCH1 mitochondria localization during heart development promotes mitochondrial metabolism and the endothelial-to-mesenchymal transition in mice.

Notch signaling activation drives an endothelial-to-mesenchymal transition (EndMT) critical for heart development, although evidence suggests that the reprogramming of endothelial cell metabolism can regulate endothelial function independent of canonical cell signaling. Herein, we investigated the crosstalk between Notch signaling and metabolic reprogramming in the EndMT process. Biochemically, we find that the NOTCH1 intracellular domain (NICD1) localizes to endothelial cell mitochondria, where it interacts with and activates the complex to enhance mitochondrial metabolism. Targeting NICD1 to mitochondria induces more EndMT compared with wild-type NICD1, and small molecule activation of PDH during pregnancy improves the phenotype in a mouse model of congenital heart defect. A NOTCH1 mutation observed in non-syndromic tetralogy of Fallot patients decreases NICD1 mitochondrial localization and subsequent PDH activity in heart tissues. Altogether, our findings demonstrate NICD1 enrichment in mitochondria of the developing mouse heart, which induces EndMT by activating PDH and subsequently improving mitochondrial metabolism.

Di-(2-ethylhexyl) Phthalate Exposure Induces Developmental Toxicity in the Mouse Fetal Heart via Mitochondrial Dysfunction.

Congenital heart disease (CHD) is a major cause of infant mortality and morbidity, with growing interest in the role of environmental factors in its etiology. Di-(2-ethylhexyl) phthalate (DEHP), an environmental endocrine disruptor, has been implicated in the development of CHD. This study aimed to investigate the effects of DEHP exposure on fetal heart development in mice. Pregnant mice exposed to DEHP exhibited increased fetal malformations, decreased fetal weight, and reduced crown-rump length.f Transcriptomic analysis revealed the downregulation of genes involved in aerobic respiration and mitochondrial ATP synthesis. Functional assays demonstrated reduced mitochondrial respiration, decreased ATP production, elevated reactive oxygen species levels, and lowered mitochondrial membrane potential in DEHP-exposed fetal cardiomyocytes. These findings underscore the detrimental effects of DEHP on fetal cardiac health and provide insights into the molecular mechanisms underlying DEHP-induced CHD. Understanding these mechanisms is crucial for developing preventive strategies against environmental toxicants that affect fetal cardiac development.

Methyltransferase METTL3 governs the modulation of SH3BGR expression through m6A methylation modification, imparting influence on apoptosis in the context of Down syndrome-associated cardiac development

Down syndrome (DS), caused by an additional chromosome 21, has a high risk of congenital heart defects (CHD), one of the primary causes of mortality in DS newborns. To elucidate the pathogenetic mechanisms underlying this condition, we explored the role of RNA m6A methylation, regulated by METTL3, in DS cardiac development and its impact on the expression of SH3BGR, a gene located at Down syndrome congenital heart disease (DS-CHD) minimal region. We analyzed DS fetal cardiac tissues to assess RNA m6A methylation levels and identify potential contributors. RNA sequencing was performed to detect differentially expressed genes in the same tissues. To further understand METTL3’s function in heart development, we inactivated Mettl3 in the developing mouse heart to mimic the significantly reduced METTL3 observed in DS cardiac development. Additionally, human cardiomyocyte AC16 cells were used to investigate the molecular mechanism by which METTL3 regulates SH3BGR expression. Apoptosis was analyzed to evaluate METTL3’s effect on heart development through SH3BGR regulation. Reduced m6A modification and decreased METTL3 expression were observed in human DS fetal hearts, along with a significant increase of SH3BGR expression. METTL3, through m6A modification, was found to regulate SH3BGR expression, by influencing mRNA stability. METTL3-deficient mouse embryos exhibited heart malformation with increased apoptosis, emphasizing its role in heart development. In DS hearts, METTL3 downregulation and SH3BGR upregulation, potentially orchestrated by abnormal m6A modification, contribute to gene dysregulation and apoptosis. This study reveals novel insights into DS cardiac pathology, highlighting the intricate role of METTL3 in DS congenital heart defects and presenting the m6A modification of SH3BGR as a potential therapeutic target.

Abstract Mo062: Cpne5 is Necessary for Normal Sinoatrial Node Function

Background: Cpne5 (Copine 5) is a Ca2+-dependent phospholipid binding protein implicated in membrane trafficking but has no known role within the heart to date. In single-cell RNA-sequencing (scRNA-seq) of the developing mouse heart, we found Cpne5 gene expression to be highly enriched throughout the cardiac conduction system (CCS). Further, variants in CPNE5 were identified in 6 independent GWAS related to heart rate variability in humans. We therefore hypothesize that Cpne5 is necessary for normal CCS function. Objective: Determine whether Cpne5 is necessary for the normal development and/or function of the CCS. Methods: To assess the necessity of Cpne5, homozygous systemic knockout (KO) mice were generated using CRISPR/Cas9. Cpne5KO and littermate wild-type (WT) control mice were characterized using surface electrocardiogram (ECG), continuous telemetry and echocardiogram. Protein expression of Cpne5 and CCS-related ion channels were assessed by immunofluorescence of tissue sections, isolated adult murine SAN cells and whole mount immunostaining with 3D volumetric imaging (iDISCO+). Further, CRISPR-mediated deletion of CPNE5 was performed in human induced pluripotent stem cells (hiPSC). Differentiated SAN-like cells were phenotyped via calcium transient (CaT) dynamics and microelectrode array. Results: Successful deletion of Cpne5 in CRISPR-generated KO mice was confirmed by PCR immunofluorescence. Homozygous Cpne5KO mice were viable, showed normal growth and allele frequencies segregated in a normal Mendelian fashion. No gross anatomic defects of the CCS were observed in Cpne5KO mice and transthoracic echocardiogram studies showed slight reduction in left ventricular fractional shortening but otherwise a structurally normal heart. Notably, while surface electrocardiogram (ECG) demonstrated normal intervals (PR, QRS, QTc), Cpne5KO mice exhibited pronounced sinus arrhythmia, sinus pauses, and increased heart rate variability compared to WT controls on long term telemetry. Additionally, CPNE5KO hiPSC-derived SAN-like cells exhibited irregular CaT as well as significant beat period variability compared to isogenic WT controls. Conclusion: Systemic loss-of-function of Cpne5 in mice resulted in sinus node dysfunction, consistent with an hiPSC-derived SAN model and human GWAS data, implicating a novel, cell-intrinsic role for Cpne5 in CCS function and/or development. Additional phenotyping and molecular studies are ongoing to further elucidate the underlying mechanism.

Atractylenolide-I Alleviates Hyperglycemia-Induced Heart Developmental Malformations through Direct and Indirect Modulation of the STAT3 Pathway

BackgroundGestational diabetes could elevate the risk of congenital heart defects (CHD) in infants, and effective preventive and therapeutic medications are currently lacking. Atractylenolide-I (AT-I) is the active ingredient of Atractylodes Macrocephala Koidz (known as Baizhu in China), which is a traditional pregnancy-supporting Chinese herb. PurposeIn this study, we investigated the protective effect of AT-I on the development of CHD in embryos exposed to high glucose (HG). Study design and MethodsFirst, systematic review search results revealed associations between gestational diabetes mellitus (GDM) and cardiovascular malformations. Subsequently, a second systematic review indicated that heart malformations were consistently associated with oxidative stress and cell apoptosis. We assessed the cytotoxic impacts of Atractylenolide compounds (AT-I, AT-II, and AT-III) on H9c2 cells and chick embryos, determining an optimal concentration of AT-I for further investigation. Second, immunofluorescence, western blot, Polymerase Chain Reaction (PCR), and flow cytometry were utilized to delve into the mechanisms through which AT-I mitigates oxidative stress and apoptosis in cardiac cells. Molecular docking was employed to investigate whether AT-I exerts cardioprotective effects via the STAT3 pathway. Then, we developed a streptozotocin-induced diabetes mellitus (PGDM) mouse model to evaluate AT-I's protective efficacy in mammals. Finally, we explored how AT-I protects hyperglycemia-induced abnormal fetal heart development through microbiota analysis and untargeted metabolomics analysis. ResultsThe study showed the protective effect of AT-I on embryonic development using a chick embryo model which rescued the increase in the reactive oxygen species (ROS) and decrease in cell survival induced by HG. We also provided evidence suggesting that AT-I might directly interact with STAT3, inhibiting its phosphorylation. Further, in the PGDM mouse model, we observed that AT-I not only partially alleviated PGDM-related blood glucose issues and complications but also mitigated hyperglycemia-induced abnormal fetal heart development in pregnant mice. This effect is hypothesized to be mediated through alterations in gut microbiota composition. We proposed that dysregulation in microbiota metabolism could influence the downstream STAT3 signaling pathway via EGFR, consequently impacting cardiac development and formation. ConclusionsThis study marks the first documented instance of AT-I's effectiveness in reducing the risk of early cardiac developmental anomalies in fetuses affected by gestational diabetes. AT-I achieves this by inhibiting the STAT3 pathway activated by ROS during gestational diabetes, significantly reducing the risk of fetal cardiac abnormalities. Notably, AT-I also indirectly safeguards normal fetal cardiac development by influencing the maternal gut microbiota and suppressing the EGFR/STAT3 pathway.

Cardiac-specific deletion of heat shock protein 60 induces mitochondrial stress and disrupts heart development in mice

Congenital heart diseases are the most common birth defects around the world. Emerging evidence suggests that mitochondrial homeostasis is required for normal heart development. In mitochondria, a series of molecular chaperones including heat shock protein 60 (HSP60) are engaged in assisting the import and folding of mitochondrial proteins. However, it remains largely obscure whether and how these mitochondrial chaperones regulate cardiac development. Here, we generated a cardiac-specific Hspd1 deletion mouse model by αMHC-Cre and investigated the role of HSP60 in cardiac development. We observed that deletion of HSP60 in embryonic cardiomyocytes resulted in abnormal heart development and embryonic lethality, characterized by reduced cardiac cell proliferation and thinner ventricular walls, highlighting an essential role of cardiac HSP60 in embryonic heart development and survival. Our results also demonstrated that HSP60 deficiency caused significant downregulation of mitochondrial ETC subunits and induced mitochondrial stress. Analysis of gene expression revealed that P21 that negatively regulates cell proliferation is significantly upregulated in HSP60 knockout hearts. Moreover, HSP60 deficiency induced activation of eIF2α-ATF4 pathway, further indicating the underlying mitochondrial stress in cardiomyocytes after HSP60 deletion. Taken together, our study demonstrated that regular function of mitochondrial chaperones is pivotal for maintaining normal mitochondrial homeostasis and embryonic heart development.

Single-cell transcriptional landscape of long non-coding RNAs orchestrating mouse heart development

Long non-coding RNAs (lncRNAs) comprise the most representative transcriptional units of the mammalian genome. They are associated with organ development linked with the emergence of cardiovascular diseases. We used bioinformatic approaches, machine learning algorithms, systems biology analyses, and statistical techniques to define co-expression modules linked to heart development and cardiovascular diseases. We also uncovered differentially expressed transcripts in subpopulations of cardiomyocytes. Finally, from this work, we were able to identify eight cardiac cell-types; several new coding, lncRNA, and pcRNA markers; two cardiomyocyte subpopulations at four different time points (ventricle E9.5, left ventricle E11.5, right ventricle E14.5 and left atrium P0) that harbored co-expressed gene modules enriched in mitochondrial, heart development and cardiovascular diseases. Our results evidence the role of particular lncRNAs in heart development and highlight the usage of co-expression modular approaches in the cell-type functional definition.

Transcription factor NFYa controls cardiomyocyte metabolism and proliferation during mouse fetal heart development

Cardiomyocytes are highly metabolic cells responsible for generating the contractile force in the heart. During fetal development and regeneration, these cells actively divide but lose their proliferative activity in adulthood. The mechanisms that coordinate their metabolism and proliferation are not fully understood. Here, we study the role of the transcription factor NFYa in developing mouse hearts. Loss of NFYa alters cardiomyocyte composition, causing a decrease in immature regenerative cells and an increase in trabecular and mature cardiomyocytes, as identified by spatial and single-cell transcriptome analyses. NFYa-deleted cardiomyocytes exhibited reduced proliferation and impaired mitochondrial metabolism, leading to cardiac growth defects and embryonic death. NFYa, interacting with cofactor SP2, activates genes linking metabolism and proliferation at the transcription level. Our study identifies a nodal role of NFYa in regulating prenatal cardiac growth and a previously unrecognized transcriptional control mechanism of heart metabolism, highlighting the importance of mitochondrial metabolism during heart development and regeneration.

Abstract 12259: Gas6 Binding With Sav1 to Restore Yap Transcriptional Activity in a Specialized Cardiomyocytes Population Contributes to Heart Regeneration

Introduction: The neonatal mammalian heart possesses transient regeneration capacity following injury, during which certain cardiomyocytes (CMs) undergo self-proliferation and establish specific communication networks within the microenvironment. However, the characteristic of these CMs has not been elucidated. Hypothesis: Analyzing communication networks of CMs involved in the microenvironment of neonatal heart regeneration will help identify heterogeneous populations of CMs and functional genes for regenerative treatment of adult myocardial infarction. Methods: CellChat was used to analyze communication networks in sc(n)RNA-seq datasets of postnatal mouse heart development and post-injury regeneration processes. Transcriptomic analysis was performed on Gas6-enriched CMs. Single-type cell isolation was used to assess Gas6 expression. CM-specific Gas6 loss- or gain-mice were generated using Cre-loxP system and Adeno-associated virus system. Adenoviral gene transfection, mass spectrometry, co-immunoprecipitation, domain truncation constructs, and dual-luciferase reporter gene assay were used to investigate the effect and mechanism of Gas6 in vitro. Results: The Gas pathway was identified among 2021 cell-cell pathways as contributing to the development and regeneration of CMs, with Gas6 being the functional gene involved. Gas6-enriched CMs exhibit heterogeneity in relation to proliferation and are abundant in neonatal hearts but disappear in adult hearts. CM-specific Gas6 gene knockout hindered myocardial proliferation in neonatal mice after apex resection. CM-specific Gas6 gene overexpression increased CM proliferation and protected cardiac function during postnatal heart growth and in injured adult hearts. In vitro studies revealed that the α-helical domain of Gas6 interacted with Sav1, inhibiting its recruitment to MST and subsequent phosphorylation cascade. Overexpression of Gas6 promoted Yap translocation into the nucleus and restored the transcription of genes involved proliferation and regeneration. Conclusions: Gas6-enriched CMs constitute a specialized population necessary for heart regeneration, in which Gas6 acts as a promoter of Yap transcriptional activity to enhance CM proliferation.

Expression analysis of plvap in mouse heart development, homeostasis and injury

Plasmalemma vesicle associated protein (PLVAP) is commonly considered to be specifically expressed in endothelial cells in which it localized to diaphragms of caveolae, fenestrae, and transendothelial channels. PLVAP is reported to be an important regulator of heart development and a novel target to promote cardiac repair in the ischemic heart. However, the dynamics of plvap expression in heart development, homeostasis and pathology have not been comprehensively described. In this study, we analyzed the temporal and spatial expression of plvap in mouse heart under different conditions. We found that, during embryonic and neonatal stages, PLVAP was detected in endocardial endothelial cells, epicardial mesothelial cells, and a small amount of coronary vascular endothelial cells. In adult heart, PLVAP was also identified in endocardial cells and a few coronary vascular endothelial cells. However, epicardial expression of PLVAP was lost during postnatal heart development and cannot be detected in mouse heart by immunostaining since 3-week-old. We also analyzed the expression of plvap in a model of cardiac hypertrophy and failure induced by transverse aortic constriction surgery, and identified expression of PLVAP in endocardial cells and coronary vascular endothelial cells in the injured heart. This study provides new evidence to better understand the role of plvap in mouse heart development and injury.

Abstract P1007: Graph Neural Network Analysis Of Dynamic Temporal Relationships Between Chromatin Accessibility And RNA Expression In The Developing Mouse Heart

Mammalian development is a dynamic process that transforms the epigenetic and transcriptomic landscapes of cells as they differentiate into various cell types and tissues. In vertebrates, the heart is the first functioning organ of the embryo, but its development has yet to be fully understood. Using simultaneous scRNA-seq and scATAQ-seq data from three major timepoints (E8.5, E10.5, E16.5) of murine development, we develop a novel approach to analyze the temporal relationship between chromatin accessibility and gene expression across development using RNA velocity and interpretable graph neural network (GNN) models. RNA velocity is a powerful splicing kinetics tool for uncovering directed transcriptional dynamics in complex biological systems, and it infers the direction and rate of change of gene expression in single cells over time by comparing the ratio of unspliced to spliced mRNA reads between adjacent cells. We represent the vectors identified through RNA velocity as a directed graph, thereby transforming the single-cell data with the additional simultaneous ATAC-seq information into an input for a GNN. The GNN then learns the temporal epigenetic and transcriptomic dynamics from the node feature information, ie. scATAC-seq, with the graph structure, ie. RNA velocity vectors, to predict the developmental trajectories of cells. After training of the GNN model, we implement an additional GNN explainer model to analyze it and identify subgraphs, ie. networks of DNA regions, that maximize the mutual information associated with its trajectory predictions. By interpreting the contributions of ATAC peaks in the GNN model, we identify novel regulatory dynamics and trends involved in the separation of distinct cardiac lineages in the developing mouse heart. Ultimately, we provide new insight for future investigation into the temporal relationship between chromatin accessibility and gene expression levels..

Abstract P3050: Cpne5 Is Necessary For Normal Murine Sinoatrial Node Function In Vivo

Cpne5 ( Copine 5 ) is a Ca 2+ -dependent phospholipid binding protein implicated in membrane trafficking but has no known role within the heart to date. In single-cell RNA-sequencing of the developing mouse heart, we previously found Cpne5 gene expression to be highly enriched in the cardiac conduction system (CCS). Further, variants in CPNE5 were identified in 6 independent GWAS related to heart rate variability in humans. We therefore hypothesized that Cpne5 is necessary for normal CCS function through Ca 2+ -dependent membrane trafficking of ion channels. Whole mount immunostaining with 3D volumetric imaging (iDISCO+) of intact WT hearts demonstrated robust and specific protein expression of Cpne5 throughout all CCS components, including the sinoatrial node (SAN) and SAN-transitional cells. Next, to assess the necessity of Cpne5 within the CCS, systemic knockout mice (Cpne5KO) were generated using CRISPR/Cas9. Successful deletion of Cpne5 in CRISPR-generated KO mice was confirmed by PCR and, at the protein level, immunofluorescence. Homozygous Cpne5KO mice were viable, showed normal growth and allele frequencies segregated in a normal Mendelian fashion. No gross anatomic defects of the CCS were observed in Cpne5KO mice and transthoracic echocardiogram studies showed a slight reduction in left ventricular fractional shortening but otherwise a structurally normal heart. Notably, while surface electrocardiogram (ECG) demonstrated normal intervals (PR, QRS, QTc), Cpne5KO mice exhibited pronounced sinus arrhythmia, with notable sinus pauses, sinus bradycardia, and increased heart rate variability as compared to WT littermate controls on long term telemetry. Systemic loss-of-function of Cpne5 in mice resulted in marked sinus node dysfunction, consistent with human GWAS data, implicating a novel role for Cpne5 in CCS function and/or development. Additional phenotyping and molecular studies, including CPNE5 deletion in human induced-pluripotent cell-derived SAN-like cells, are ongoing to further elucidate its underlying mechanism.

Lem2 is essential for cardiac development by maintaining nuclear integrity.

Nuclear envelope integrity is essential for the compartmentalization of the nucleus and cytoplasm. Importantly, mutations in genes encoding nuclear envelope (NE) and associated proteins are the second highest cause of familial dilated cardiomyopathy. One such NE protein that causes cardiomyopathy in humans and affects mouse heart development is Lem2. However, its role in the heart remains poorly understood. We generated mice in which Lem2 was specifically ablated either in embryonic cardiomyocytes (Lem2 cKO) or in adult cardiomyocytes (Lem2 iCKO) and carried out detailed physiological, tissue, and cellular analyses. High-resolution episcopic microscopy was used for three-dimensional reconstructions and detailed morphological analyses. RNA-sequencing and immunofluorescence identified altered pathways and cellular phenotypes, and cardiomyocytes were isolated to interrogate nuclear integrity in more detail. In addition, echocardiography provided a physiological assessment of Lem2 iCKO adult mice. We found that Lem2 was essential for cardiac development, and hearts from Lem2 cKO mice were morphologically and transcriptionally underdeveloped. Lem2 cKO hearts displayed high levels of DNA damage, nuclear rupture, and apoptosis. Crucially, we found that these defects were driven by muscle contraction as they were ameliorated by inhibiting myosin contraction and L-type calcium channels. Conversely, reducing Lem2 levels to ∼45% in adult cardiomyocytes did not lead to overt cardiac dysfunction up to 18 months of age. Our data suggest that Lem2 is critical for integrity at the nascent NE in foetal hearts, and protects the nucleus from the mechanical forces of muscle contraction. In contrast, the adult heart is not detectably affected by partial Lem2 depletion, perhaps owing to a more established NE and increased adaptation to mechanical stress. Taken together, these data provide insights into mechanisms underlying cardiomyopathy in patients with mutations in Lem2 and cardio-laminopathies in general.

EZH2 controls epicardial cell migration during heart development.

Enhancer of zeste homolog 2 (EZH2) is an important transcriptional regulator in development that catalyzes H3K27me3. The role of EZH2 in epicardial development is still unknown. In this study, we show that EZH2 is expressed in epicardial cells during both human and mouse heart development. Ezh2 epicardial deletion resulted in impaired epicardial cell migration, myocardial hypoplasia, and defective coronary plexus development, leading to embryonic lethality. By using RNA sequencing, we identified that EZH2 controls the transcription of tissue inhibitor of metalloproteinase 3 (TIMP3) in epicardial cells during heart development. Loss-of-function studies revealed that EZH2 promotes epicardial cell migration by suppressing TIMP3 expression. We also found that epicardial Ezh2 deficiency-induced TIMP3 up-regulation leads to extracellular matrix reconstruction in the embryonic myocardium by mass spectrometry. In conclusion, our results demonstrate that EZH2 is required for epicardial cell migration because it blocks Timp3 transcription, which is vital for heart development. Our study provides new insight into the function of EZH2 in cell migration and epicardial development.

Left Ventricular Noncompaction and Coronary Artery Disease: An Unexpected Combination

A 51-year-old man without cardiac risk factors was referred to the hospital after a complete left bundle block was discovered on an electrocardiogram; he had a 6-month history of fatigue and mild exertional dyspnea. Transthoracic echocardiogram showed a spongiform appearance of the left ventricle, with prominent hypertrabeculations in lateral and apical walls (Fig. 1A and B). The left ventricle was dilated and hypokinetic (diastolic diameter, 70 mm; ejection fraction, 25%).Severe stenosis (90%) of both the middle tract of the left anterior descending artery and the first diagonal branch was detected by coronary angiography (Fig. 2). Lesions were treated with angioplasty and drug-eluting stent implantation. Cardiac magnetic resonance imaging confirmed the diagnosis of left ventricular noncompaction (LVNC) (Fig. 3A–D).Left ventricular noncompaction is a primary cardiomyopathy of genetic origin1 that may cause congestive heart failure. Concomitant coronary artery disease (CAD) is uncommon, even more so in a patient without cardiac risk factors.A theoretical explanation of this finding might be that the compaction of intertrabecular recesses in the left ventricular myocardium occurs simultaneously with the development of the coronary vasculature between 12 and 18 weeks' gestation.2The anomalous origin of coronary arteries and coronary fistulae have previously been described together with LVNC in isolated case reports in the literature.The co-occurrence of LVNC and CAD has been described only a few times before,3–7 and prior literature on LVNC with congestive heart failure does not report any association with acquired CAD.The presented case shows a peculiar association relevant for future reference in prospective studies to be done in cases of LVNC with cardiomyopathy.The evidence of significant coronary stenosis in combination with LVNC without documented dyslipidemia has led to the hypothesis of a common genetic involvement for myocardial compaction and coronary endothelium development. This speculation is bolstered by the identification of a family with familial CAD and LVNC.8In vitro and in the developing mouse heart, deletion of the Ino80 chromatin remodeler in vascular endothelial cells prevents ventricular compaction. This correlates with scarce coronary vascularization: Ino80 deletion results in a defect in coronary vessel formation, which means coronary arteries develop to become significantly smaller than normal.9 Arbustini et al10 provided an updated list of other genes that are associated with LVNC.Therefore, LVNC is a morphogenetic defect that occurs at the site and time of embryologic development of the coronary arteries (intramyocardial section) that could potentially affect the biology of coronary arteries and increase the risk of early development of CAD.In conclusion, whether the association of CAD with LVNC is coincidental is a question that needs further research. This report contributes to the case recording and opens the prospects for the possibility of some association in patients with LVNC cardiomyopathy.

Elabela and Apelin regulate coronary angiogenesis in a competitive manner.

APJ, a G-protein coupled receptor, regulates coronary angiogenesis in the developing mouse heart. However, the exact mechanism by which APJ regulates coronary angiogenesis from its dual ligands, ELABELA and APELIN, is unclear. Our study show that ELABELA and APELIN both stimulate angiogenic activities such as proliferation and sprouting outgrowth in explant cultures. We found APELIN to be a more robust angiogenic stimulant compared to ELABELA. When explant cultures were stimulated by both ligands together, we found that ELABELA repress the angiogenic activity of APELIN. Collectively, we show that ELABELA and APELIN regulate coronary angiogenesis in a competitive manner.

The second heart field: the first 20years.

In 2001, three independent groups reported the identification of a novel cluster of progenitor cells that contribute to heart development in mouse and chicken embryos. This population of progenitor cells was designated as the second heart field (SHF), and a new research direction in heart development was launched. Twenty years have since passed and a comprehensive understanding of the SHF has been achieved. This review provides retrospective insights in to the contribution, the signaling regulatory networks and the epithelial properties of the SHF. It also includes the spatiotemporal characteristics of SHF development and interactions between the SHF and other types of cells during heart development. Although considerable efforts will be required to investigate the cellular heterogeneity of the SHF, together with its intricate regulatory networks and undefined mechanisms, it is expected that the burgeoning new technology of single-cell sequencing and precise lineage tracing will advance the comprehension of SHF function and its molecular signals. The advances in SHF research will translate to clinical applications and to the treatment of congenital heart diseases, especially conotruncal defects, as well as to regenerative medicine.

Combined method of whole mount and block-face imaging: Acquisition of 3D data of gene expression pattern from conventional in situ hybridization.

Visualization of spatiotemporal expression of a gene of interest is a fundamental technique for analyzing the involvements of genes in organ development. In situ hybridization (ISH) is one of the most popular methods for visualizing gene expression. When conventional ISH is performed on sections or whole-mount specimens, the gene expression pattern is represented in 2-dimensional (2D) microscopic images or in the surface view of the specimen. To obtain 3-dimensional (3D) data of gene expression from conventional ISH, the "serial section method" has traditionally been employed. However, this method requires an extensive amount of time and labor because it requires researchers to collect a tremendous number of sections, label all sections by ISH, and image them before 3D reconstruction. Here, we proposed a rapid and low-cost 3D imaging method that can create 3D gene expression patterns from conventional ISH-labeled specimens. Our method consists of a combination of whole-mount ISH and Correlative Microscopy and Blockface imaging (CoMBI). The whole-mount ISH-labeled specimens were sliced using a microtome or cryostat, and all block-faces were imaged and used to reconstruct 3D images by CoMBI. The 3D data acquired using our method showed sufficient quality to analyze the morphology and gene expression patterns in the developing mouse heart. In addition, 2D microscopic images of the sections can be obtained when needed. Correlating 2D microscopic images and 3D data can help annotate gene expression patterns and understand the anatomy of developing organs. These results indicated that our method can be useful in the field of developmental biology.

Maternal Delta-9-Tetrahydrocannabinol Exposure Induces Abnormalities of the Developing Heart in Mice.

Introduction: Cannabis is increasingly being consumed by pregnant women for recreational purposes as well as for its antiemetic and anxiolytic effects despite limited studies on its safety during pregnancy. Importantly, phytocannabinoids found in cannabis can pass through the placenta and enter the fetal circulation. Recent reports suggest gestational cannabis use is associated with negative fetal outcomes, including fetal growth restriction and perinatal intensive care, however, the effects of delta-9-tetrahydrocannabinol (THC) on fetal heart development remains to be elucidated. Materials and Methods: We aimed to determine the outcomes of maternal THC exposure on fetal heart development in mice by administering 0, 5, or 10 mg/kg/day of THC orally to C57BL/6 dams starting at embryonic day (E)3.5. Offspring were collected at E12.5 for molecular analysis, at E17.5 to analyze cardiac morphology or at postnatal day (PND)21 to assess heart function. Results: Maternal THC exposure in E17.5 fetuses resulted in an array of cardiac abnormalities with an incidence of 44% and 55% in the 5 and 10 mg/kg treatment groups, respectively. Maternal THC exposure in offspring resulted in ventricular septal defect, higher semilunar valve volume relative to orifice ratio, and higher myocardial wall thickness. Notably, cell proliferation within the ventricular myocardium was increased, and expression of multiple cardiac transcription factors was downregulated in THC-exposed E12.5 fetuses. Furthermore, heart function was compromised with lower left ventricular ejection fraction, fractional shortening, and cardiac output in PND21 pups exposed to THC compared to controls. Discussion: The results show that maternal THC exposure during gestation induces myocardial hyperplasia and semilunar valve thickening in the fetal heart and postnatal cardiac dysfunction. Our study suggests that maternal cannabis consumption may induce abnormalities in the developing heart and cardiac dysfunction in postnatal life.