Your search keyword '"Rolf Bodmer"' showing total 270 results

1. The nutrient sensor CRTC and Sarcalumenin/thinman represent an alternate pathway in cardiac hypertrophy

Author

Cristiana Dondi, Georg Vogler, Anjali Gupta, Stanley M. Walls, Anaïs Kervadec, James Marchant, Michaela R. Romero, Soda Diop, Jason Goode, John B. Thomas, Alex R. Colas, Rolf Bodmer, Marc Montminy, and Karen Ocorr

Subjects

CP: Cell biology, CP: Metabolism, Biology (General), QH301-705.5

Abstract

Summary: CREB-regulated transcription co-activator (CRTC) is activated by Calcineurin (CaN) to regulate gluconeogenic genes. CaN also has roles in cardiac hypertrophy. Here, we explore a cardiac-autonomous role for CRTC in cardiac hypertrophy. In Drosophila, CRTC mutants exhibit severe cardiac restriction, myofibrillar disorganization, fibrosis, and tachycardia. Cardiac-specific CRTC knockdown (KD) phenocopies mutants, and cardiac overexpression causes hypertrophy. CaN-induced hypertrophy in Drosophila is reduced in CRTC mutants, suggesting that CRTC mediates the effects. RNA sequencing (RNA-seq) of CRTC-KD and -overexpressing hearts reveals contraregulation of metabolic genes. Genes with conserved CREB sites include the fly ortholog of Sarcalumenin, a Ca2+-binding protein. Cardiac manipulation of this gene recapitulates the CRTC-KD and -overexpression phenotypes. CRTC KD in zebrafish also causes cardiac restriction, and CRTC KD in human induced cardiomyocytes causes a reduction in Srl expression and increased action potential duration. Our data from three model systems suggest that CaN-CRTC-Sarcalumenin signaling represents an alternate, conserved pathway underlying cardiac function and hypertrophy.

Published

2024

2. Multiplatform modeling of atrial fibrillation identifies phospholamban as a central regulator of cardiac rhythm

Author

Anaïs Kervadec, James Kezos, Haibo Ni, Michael Yu, James Marchant, Sean Spiering, Suraj Kannan, Chulan Kwon, Peter Andersen, Rolf Bodmer, Eleonora Grandi, Karen Ocorr, and Alexandre R. Colas

Subjects

cardiac disease modeling, atrial fibrillation, human ipsc-derived atrial-like cardiomyocytes, computational modeling, high-throughput electrophysiology, single-cell resolution, drosophila, Medicine, Pathology, RB1-214

Published

2023

3. Mitochondrial MICOS complex genes, implicated in hypoplastic left heart syndrome, maintain cardiac contractility and actomyosin integrity

Author

Katja Birker, Shuchao Ge, Natalie J Kirkland, Jeanne L Theis, James Marchant, Zachary C Fogarty, Maria A Missinato, Sreehari Kalvakuri, Paul Grossfeld, Adam J Engler, Karen Ocorr, Timothy J Nelson, Alexandre R Colas, Timothy M Olson, Georg Vogler, and Rolf Bodmer

Subjects

MICOS, CHCHD3/6, HLHS, Drosophila, genetics, CHD, Medicine, Science, Biology (General), QH301-705.5

Abstract

Hypoplastic left heart syndrome (HLHS) is a severe congenital heart disease (CHD) with a likely oligogenic etiology, but our understanding of the genetic complexities and pathogenic mechanisms leading to HLHS is limited. We performed whole genome sequencing (WGS) on 183 HLHS patient-parent trios to identify candidate genes, which were functionally tested in the Drosophila heart model. Bioinformatic analysis of WGS data from an index family of a HLHS proband born to consanguineous parents prioritized 9 candidate genes with rare, predicted damaging homozygous variants. Of them, cardiac-specific knockdown (KD) of mitochondrial MICOS complex subunit dCHCHD3/6 resulted in drastically compromised heart contractility, diminished levels of sarcomeric actin and myosin, reduced cardiac ATP levels, and mitochondrial fission-fusion defects. These defects were similar to those inflicted by cardiac KD of ATP synthase subunits of the electron transport chain (ETC), consistent with the MICOS complex’s role in maintaining cristae morphology and ETC assembly. Five additional HLHS probands harbored rare, predicted damaging variants in CHCHD3 or CHCHD6. Hypothesizing an oligogenic basis for HLHS, we tested 60 additional prioritized candidate genes from these patients for genetic interactions with CHCHD3/6 in sensitized fly hearts. Moderate KD of CHCHD3/6 in combination with Cdk12 (activator of RNA polymerase II), RNF149 (goliath, E3 ubiquitin ligase), or SPTBN1 (β-Spectrin, scaffolding protein) caused synergistic heart defects, suggesting the likely involvement of diverse pathways in HLHS. Further elucidation of novel candidate genes and genetic interactions of potentially disease-contributing pathways is expected to lead to a better understanding of HLHS and other CHDs.

Published

2023

4. Genetic architecture of natural variation of cardiac performance from flies to humans

Author

Saswati Saha, Lionel Spinelli, Jaime A Castro Mondragon, Anaïs Kervadec, Michaela Lynott, Laurent Kremmer, Laurence Roder, Sallouha Krifa, Magali Torres, Christine Brun, Georg Vogler, Rolf Bodmer, Alexandre R Colas, Karen Ocorr, and Laurent Perrin

Subjects

heart function, GWAS, gene regulatory networks, Drosophila, human, conserved genetic architecture, Medicine, Science, Biology (General), QH301-705.5

Abstract

Deciphering the genetic architecture of human cardiac disorders is of fundamental importance but their underlying complexity is a major hurdle. We investigated the natural variation of cardiac performance in the sequenced inbred lines of the Drosophila Genetic Reference Panel (DGRP). Genome-wide associations studies (GWAS) identified genetic networks associated with natural variation of cardiac traits which were used to gain insights as to the molecular and cellular processes affected. Non-coding variants that we identified were used to map potential regulatory non-coding regions, which in turn were employed to predict transcription factors (TFs) binding sites. Cognate TFs, many of which themselves bear polymorphisms associated with variations of cardiac performance, were also validated by heart-specific knockdown. Additionally, we showed that the natural variations associated with variability in cardiac performance affect a set of genes overlapping those associated with average traits but through different variants in the same genes. Furthermore, we showed that phenotypic variability was also associated with natural variation of gene regulatory networks. More importantly, we documented correlations between genes associated with cardiac phenotypes in both flies and humans, which supports a conserved genetic architecture regulating adult cardiac function from arthropods to mammals. Specifically, roles for PAX9 and EGR2 in the regulation of the cardiac rhythm were established in both models, illustrating that the characteristics of natural variations in cardiac function identified in Drosophila can accelerate discovery in humans.

Published

2022

5. Nascent polypeptide-Associated Complex and Signal Recognition Particle have cardiac-specific roles in heart development and remodeling.

Author

Analyne M Schroeder, Tanja Nielsen, Michaela Lynott, Georg Vogler, Alexandre R Colas, and Rolf Bodmer

Subjects

Genetics, QH426-470

Abstract

Establishing a catalog of Congenital Heart Disease (CHD) genes and identifying functional networks would improve our understanding of its oligogenic underpinnings. Our studies identified protein biogenesis cofactors Nascent polypeptide-Associated Complex (NAC) and Signal-Recognition-Particle (SRP) as disease candidates and novel regulators of cardiac differentiation and morphogenesis. Knockdown (KD) of the alpha- (Nacα) or beta-subunit (bicaudal, bic) of NAC in the developing Drosophila heart disrupted cardiac developmental remodeling resulting in a fly with no heart. Heart loss was rescued by combined KD of Nacα with the posterior patterning Hox gene Abd-B. Consistent with a central role for this interaction in cardiogenesis, KD of Nacα in cardiac progenitors derived from human iPSCs impaired cardiac differentiation while co-KD with human HOXC12 and HOXD12 rescued this phenotype. Our data suggest that Nacα KD preprograms cardioblasts in the embryo for abortive remodeling later during metamorphosis, as Nacα KD during translation-intensive larval growth or pupal remodeling only causes moderate heart defects. KD of SRP subunits in the developing fly heart produced phenotypes that targeted specific segments and cell types, again suggesting cardiac-specific and spatially regulated activities. Together, we demonstrated directed function for NAC and SRP in heart development, and that regulation of NAC function depends on Hox genes.

Published

2022

6. Depletion of cardiac cardiolipin synthase alters systolic and diastolic function

Author

Elia Smeir, Sarah Leberer, Annelie Blumrich, Georg Vogler, Anastasia Vasiliades, Sandra Dresen, Carsten Jaeger, Yoann Gloaguen, Christian Klose, Dieter Beule, P. Christian Schulze, Rolf Bodmer, Anna Foryst-Ludwig, and Ulrich Kintscher

Subjects

Animal physiology, Molecular physiology, Molecular biology, Lipidomics, Science

Abstract

Summary: Cardiolipin (CL) is a major cardiac mitochondrial phospholipid maintaining regular mitochondrial morphology and function in cardiomyocytes. Cardiac CL production includes its biosynthesis and a CL remodeling process. Here we studied the impact of CL biosynthesis and the enzyme cardiolipin synthase (CLS) on cardiac function. CLS and cardiac CL species were significantly downregulated in cardiomyocytes following catecholamine-induced cardiac damage in mice, accompanied by increased oxygen consumption rates, signs of oxidative stress, and mitochondrial uncoupling. RNAi-mediated cardiomyocyte-specific knockdown of CLS in Drosophila melanogaster resulted in marked cardiac dilatation, severe impairment of systolic performance, and slower diastolic filling velocity assessed by fluorescence-based heart imaging. Finally, we showed that CL72:8 is significantly decreased in cardiac samples from patients with heart failure with reduced ejection fraction (HFrEF). In summary, we identified CLS as a regulator of cardiac function. Considering the cardiac depletion of CL species in HFrEF, pharmacological targeting of CLS may be a promising therapeutic approach.

Published

2021

7. Intergenerational inheritance of high fat diet-induced cardiac lipotoxicity in Drosophila

Author

Maria Clara Guida, Ryan Tyge Birse, Alessandra Dall’Agnese, Paula Coutinho Toto, Soda Balla Diop, Antonello Mai, Peter D. Adams, Pier Lorenzo Puri, and Rolf Bodmer

Subjects

Science

Abstract

Animal studies have shown that the nutritional status of parents can predispose the offspring to obesity and obesity-related diseases. Here the authors show that cardiac dysfunction induced by a high-fat diet persists for two generations in Drosophila, and that targeted expression of ATGL/bmm in the offspring, as well as inhibition of H3K27 trimethylation, is cardioprotective.

Published

2019

8. Fat-body brummer lipase determines survival and cardiac function during starvation in Drosophila melanogaster

Author

Annelie Blumrich, Georg Vogler, Sandra Dresen, Soda Balla Diop, Carsten Jaeger, Sarah Leberer, Jana Grune, Eva K. Wirth, Beata Hoeft, Kostja Renko, Anna Foryst-Ludwig, Joachim Spranger, Stephan Sigrist, Rolf Bodmer, and Ulrich Kintscher

Subjects

Molecular Physiology, Lipidomics, Metabolomics, Science

Abstract

Summary: The cross talk between adipose tissue and the heart has an increasing importance for cardiac function under physiological and pathological conditions. This study characterizes the role of fat body lipolysis for cardiac function in Drosophila melanogaster. Perturbation of the function of the key lipolytic enzyme, brummer (bmm), an ortholog of the mammalian ATGL (adipose triglyceride lipase) exclusively in the fly's fat body, protected the heart against starvation-induced dysfunction. We further provide evidence that this protection is caused by the preservation of glycerolipid stores, resulting in a starvation-resistant maintenance of energy supply and adequate cardiac ATP synthesis. Finally, we suggest that alterations of lipolysis are tightly coupled to lipogenic processes, participating in the preservation of lipid energy substrates during starvation. Thus, we identified the inhibition of adipose tissue lipolysis and subsequent energy preservation as a protective mechanism against cardiac dysfunction during catabolic stress.

Published

2021

9. Identification of MYOM2 as a candidate gene in hypertrophic cardiomyopathy and Tetralogy of Fallot, and its functional evaluation in the Drosophila heart

Author

Emilie Auxerre-Plantié, Tanja Nielsen, Marcel Grunert, Olga Olejniczak, Andreas Perrot, Cemil Özcelik, Dennis Harries, Faramarz Matinmehr, Cristobal Dos Remedios, Christian Mühlfeld, Theresia Kraft, Rolf Bodmer, Georg Vogler, and Silke R. Sperling

Subjects

congenital heart disease, cardiomyopathy, cg14964, myomesin, candidate gene, Medicine, Pathology, RB1-214

Abstract

The causal genetic underpinnings of congenital heart diseases, which are often complex and multigenic, are still far from understood. Moreover, there are also predominantly monogenic heart defects, such as cardiomyopathies, with known disease genes for the majority of cases. In this study, we identified mutations in myomesin 2 (MYOM2) in patients with Tetralogy of Fallot (TOF), the most common cyanotic heart malformation, as well as in patients with hypertrophic cardiomyopathy (HCM), who do not exhibit any mutations in the known disease genes. MYOM2 is a major component of the myofibrillar M-band of the sarcomere, and a hub gene within interactions of sarcomere genes. We show that patient-derived cardiomyocytes exhibit myofibrillar disarray and reduced passive force with increasing sarcomere lengths. Moreover, our comprehensive functional analyses in the Drosophila animal model reveal that the so far uncharacterized fly gene CG14964 [herein referred to as Drosophila myomesin and myosin binding protein (dMnM)] may be an ortholog of MYOM2, as well as other myosin binding proteins. Its partial loss of function or moderate cardiac knockdown results in cardiac dilation, whereas more severely reduced function causes a constricted phenotype and an increase in sarcomere myosin protein. Moreover, compound heterozygous combinations of CG14964 and the sarcomere gene Mhc (MYH6/7) exhibited synergistic genetic interactions. In summary, our results suggest that MYOM2 not only plays a critical role in maintaining robust heart function but may also be a candidate gene for heart diseases such as HCM and TOF, as it is clearly involved in the development of the heart. This article has an associated First Person interview with Emilie Auxerre-Plantié and Tanja Nielsen, joint first authors of the paper.

Published

2020

10. Age-dependent Lamin changes induce cardiac dysfunction via dysregulation of cardiac transcriptional programs

Author

Natalie J. Kirkland, Scott H. Skalak, Alexander J. Whitehead, James D. Hocker, Pranjali Beri, Geo Vogler, Bill Hum, Mingyi Wang, Edward G. Lakatta, Bing Ren, Rolf Bodmer, and Adam J. Engler

Subjects

Aging, Heart Disease, Underpinning research, 1.1 Normal biological development and functioning, Genetics, Neuroscience (miscellaneous), 2.1 Biological and endogenous factors, Aetiology, Geriatrics and Gerontology, Cardiovascular, Article

Abstract

As we age, structural changes contribute to progressive decline in organ function, which in the heart act through poorly characterized mechanisms. Taking advantage of the short lifespan and conserved cardiac proteome of the fruit fly, we found that cardiomyocytes exhibit progressive loss of Lamin C (mammalian Lamin A/C homologue) with age, coincident with decreasing nuclear size and increasing nuclear stiffness. Premature genetic reduction of Lamin C phenocopies aging’s effects on the nucleus, and subsequently decreases heart contractility and sarcomere organization. Surprisingly, Lamin C reduction downregulates myogenic transcription factors and cytoskeletal regulators, possibly via reduced chromatin accessibility. Subsequently, we find a role for cardiac transcription factors in regulating adult heart contractility and show that maintenance of Lamin C, and cardiac transcription factor expression, prevents age-dependent cardiac decline. Our findings are conserved in aged non-human primates and mice, demonstrating that age-dependent nuclear remodeling is a major mechanism contributing to cardiac dysfunction.

Published

2022

11. Patient-specific genomics and cross-species functional analysis implicate LRP2 in hypoplastic left heart syndrome

Author

Jeanne L Theis, Georg Vogler, Maria A Missinato, Xing Li, Tanja Nielsen, Xin-Xin I Zeng, Almudena Martinez-Fernandez, Stanley M Walls, Anaïs Kervadec, James N Kezos, Katja Birker, Jared M Evans, Megan M O'Byrne, Zachary C Fogarty, André Terzic, Paul Grossfeld, Karen Ocorr, Timothy J Nelson, Timothy M Olson, Alexandre R Colas, and Rolf Bodmer

Subjects

lipoproteins, iPSC, cardiogenesis, congenital heart disease, hypoplastic left heart syndrome, Medicine, Science, Biology (General), QH301-705.5

Abstract

Congenital heart diseases (CHDs), including hypoplastic left heart syndrome (HLHS), are genetically complex and poorly understood. Here, a multidisciplinary platform was established to functionally evaluate novel CHD gene candidates, based on whole-genome and iPSC RNA sequencing of a HLHS family-trio. Filtering for rare variants and altered expression in proband iPSCs prioritized 10 candidates. siRNA/RNAi-mediated knockdown in healthy human iPSC-derived cardiomyocytes (hiPSC-CM) and in developing Drosophila and zebrafish hearts revealed that LDL receptor-related protein LRP2 is required for cardiomyocyte proliferation and differentiation. Consistent with hypoplastic heart defects, compared to parents the proband’s iPSC-CMs exhibited reduced proliferation. Interestingly, rare, predicted-damaging LRP2 variants were enriched in a HLHS cohort; however, understanding their contribution to HLHS requires further investigation. Collectively, we have established a multi-species high-throughput platform to rapidly evaluate candidate genes and their interactions during heart development, which are crucial first steps toward deciphering oligogenic underpinnings of CHDs, including hypoplastic left hearts.

Published

2020

12. Systemic and heart autonomous effects of sphingosine Δ4 desaturase deficiency in lipotoxic cardiac pathophysiology

Author

Stanley M. Walls, Dale A. Chatfield, Karen Ocorr, Greg L. Harris, and Rolf Bodmer

Subjects

ifc, sphingosine δ4 desaturase, dihydroceramide, sphingolipid metabolism, ceramide, cardiac, Medicine, Pathology, RB1-214

Abstract

Lipotoxic cardiomyopathy (LCM) is characterized by cardiac steatosis, including the accumulation of fatty acids, triglycerides and ceramides. Model systems have shown the inhibition of ceramide biosynthesis to antagonize obesity and improve insulin sensitivity. Sphingosine Δ4 desaturase (encoded by ifc in Drosophila melanogaster) enzymatically converts dihydroceramide into ceramide. Here, we examine ifc mutants to study the effects of desaturase deficiency on cardiac function in Drosophila. Interestingly, ifc mutants exhibited classic hallmarks of LCM: cardiac chamber dilation, contractile defects and loss of fractional shortening. This outcome was phenocopied in global ifc RNAi-mediated knockdown flies. Surprisingly, cardiac-specific ifc knockdown flies exhibited cardiac chamber restriction with no contractile defects, suggesting heart autonomous and systemic roles for ifc activity in cardiac function. Next, we demonstrated that ifc mutants exhibit suppressed Sphingosine kinase 1 (Sk1) expression. Ectopic overexpression of Sk1 was sufficient to prevent cardiac chamber dilation and loss of fractional shortening in ifc mutants. Partial rescue was also observed with cardiac- and fat-body-specific Sk1 overexpression. Finally, we showed that cardiac-specific expression of Drosophila inhibitor of apoptosis (dIAP) also prevented cardiac dysfunction in ifc mutants, suggesting a role for caspase activity in the observed cardiac pathology. Collectively, we show that spatial regulation of sphingosine Δ4 desaturase activity differentially affects cardiac function in heart autonomous and systemic mechanisms through tissue interplay.

Published

2020

13. Silencing of CCR4-NOT complex subunits affects heart structure and function

Author

Lisa Elmén, Claudia B. Volpato, Anaïs Kervadec, Santiago Pineda, Sreehari Kalvakuri, Nakissa N. Alayari, Luisa Foco, Peter P. Pramstaller, Karen Ocorr, Alessandra Rossini, Anthony Cammarato, Alexandre R. Colas, Andrew A. Hicks, and Rolf Bodmer

Subjects

cnot1, gwas, arrhythmia, long-qt syndrome, drosophila heart, hipsc, cardiomyocytes, Medicine, Pathology, RB1-214

Abstract

The identification of genetic variants that predispose individuals to cardiovascular disease and a better understanding of their targets would be highly advantageous. Genome-wide association studies have identified variants that associate with QT-interval length (a measure of myocardial repolarization). Three of the strongest associating variants (single-nucleotide polymorphisms) are located in the putative promotor region of CNOT1, a gene encoding the central CNOT1 subunit of CCR4-NOT: a multifunctional, conserved complex regulating gene expression and mRNA stability and turnover. We isolated the minimum fragment of the CNOT1 promoter containing all three variants from individuals homozygous for the QT risk alleles and demonstrated that the haplotype associating with longer QT interval caused reduced reporter expression in a cardiac cell line, suggesting that reduced CNOT1 expression might contribute to abnormal QT intervals. Systematic siRNA-mediated knockdown of CCR4-NOT components in human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) revealed that silencing CNOT1 and other CCR4-NOT genes reduced their proliferative capacity. Silencing CNOT7 also shortened action potential duration. Furthermore, the cardiac-specific knockdown of Drosophila orthologs of CCR4-NOT genes in vivo (CNOT1/Not1 and CNOT7/8/Pop2) was either lethal or resulted in dilated cardiomyopathy, reduced contractility or a propensity for arrhythmia. Silencing CNOT2/Not2, CNOT4/Not4 and CNOT6/6L/twin also affected cardiac chamber size and contractility. Developmental studies suggested that CNOT1/Not1 and CNOT7/8/Pop2 are required during cardiac remodeling from larval to adult stages. To summarize, we have demonstrated how disease-associated genes identified by GWAS can be investigated by combining human cardiomyocyte cell-based and whole-organism in vivo heart models. Our results also suggest a potential link of CNOT1 and CNOT7/8 to QT alterations and further establish a crucial role of the CCR4-NOT complex in heart development and function. This article has an associated First Person interview with the first author of the paper.

Published

2020

14. Ceramide-Protein Interactions Modulate Ceramide-Associated Lipotoxic Cardiomyopathy

Author

Stanley M. Walls, Anthony Cammarato, Dale A. Chatfield, Karen Ocorr, Greg L. Harris, and Rolf Bodmer

Subjects

Biology (General), QH301-705.5

Abstract

Summary: Lipotoxic cardiomyopathy (LCM) is characterized by abnormal myocardial accumulation of lipids, including ceramide; however, the contribution of ceramide to the etiology of LCM is unclear. Here, we investigated the association of ceramide metabolism and ceramide-interacting proteins (CIPs) in LCM in the Drosophila heart model. We find that ceramide feeding or ceramide-elevating genetic manipulations are strongly associated with cardiac dilation and defects in contractility. High ceramide-associated LCM is prevented by inhibiting ceramide synthesis, establishing a robust model of direct ceramide-associated LCM, corroborating previous indirect evidence in mammals. We identified several CIPs from mouse heart and Drosophila extracts, including caspase activator Annexin-X, myosin chaperone Unc-45, and lipogenic enzyme FASN1, and remarkably, their cardiac-specific manipulation can prevent LCM. Collectively, these data suggest that high ceramide-associated lipotoxicity is mediated, in part, through altering caspase activation, sarcomeric maintenance, and lipogenesis, thus providing evidence for conserved mechanisms in LCM pathogenesis in mammals. : Lipotoxic cardiomyopathy (LCM) is characterized by abnormal myocardial accumulation of lipids, including ceramide. Here, Walls et al. find that ceramide feeding or ceramide-elevating genetic manipulations induce LCM. They identified several ceramide-interacting proteins, whose subsequent cardiac-specific manipulation can prevent LCM by altering caspase activation, sarcomeric maintenance, and lipogenesis. Keywords: heart, sphingolipids, Drosophila, diabetic cardiac disease, myriocin, apoptosis, lipogenesis, Unc-45, Annexin, FASN

Published

2018

15. Deacetylase-dependent and -independent role of HDAC3 in cardiomyopathy

Author

Jieyu Ren, Qun Zeng, Hongmei Wu, Xuewen Liu, Maria C. Guida, Wen Huang, Yiyuan Zhai, Junjie Li, Karen Ocorr, Rolf Bodmer, and Min Tang

Subjects

Physiology, Clinical Biochemistry, Cell Biology, Article

Abstract

Cardiomyopathy is a common disease of cardiac muscle that negatively affects cardiac function. HDAC3 commonly functions as corepressor by removing acetyl moieties from histone tails. However, a deacetylase-independent role of HDAC3 has also been described. Cardiac deletion of HDAC3 causes reduced cardiac contractility accompanied by lipid accumulation, but the molecular function of HDAC3 in cardiomyopathy remains unknown. We have used powerful genetic tools in Drosophila to investigate the enzymatic and nonenzymatic roles of HDAC3 in cardiomyopathy. Using the Drosophila heart model, we showed that cardiac-specific HDAC3 knockdown (KD) leads to prolonged systoles and reduced cardiac contractility. Immunohistochemistry revealed structural abnormalities characterized by myofiber disruption in HDAC3 KD hearts. Cardiac-specific HDAC3 KD showed increased levels of whole-body triglycerides and increased fibrosis. The introduction of deacetylase-dead HDAC3 mutant in HDAC3 KD background showed comparable results with wild-type HDAC3 in aspects of contractility and Pericardin deposition. However, deacetylase-dead HDAC3 mutants failed to improve triglyceride accumulation. Our data indicate that HDAC3 plays a deacetylase-independent role in maintaining cardiac contractility and preventing Pericardin deposition as well as a deacetylase-dependent role to maintain triglyceride homeostasis.

Published

2023

16. The deacetylase dependent and independent role of HDAC3 in cardiomyopathy

Author

Jieyu Ren, Qun Zeng, Hongmei Wu, Xuewen Liu, Maria Clara Guida, Wen Huang, Yiyuan Zhai, Junjie Li, Karen Ocorr, Rolf Bodmer, and Min Tang

Abstract

BackgroundCardiomyopathy is a common disease of cardiac muscle that negatively affects cardiac function. HDAC3 commonly functions as co-repressor by removing acetyl moieties from histone tails. However, a deacetylase-independent role of HDAC3 has also been described. Cardiac deletion of HDAC3 causes reduced cardiac contractility accompanied by lipid accumulation. The molecular function of HDAC3 in cardiomyopathy remains unknown. We have used the powerful genetic tools inDrosophilato investigate the enzymatic and non-enzymatic roles of HDAC3 in cardiomyopathy.Methods and ResultsUsing theDrosophilaheart model, we showed that cardiac-specific HDAC3 knockdown leads to prolonged systoles and reduced cardiac contractility. Immunohistochemistry revealed structural abnormalities characterized by myofiber disruption in HDAC3 knock down hearts. Cardiac-specific HDAC3 knockdown showed increased levels of whole body triglycerides and increased fibrosis. The introduction of deacetylase-dead HDAC3 mutant in HDAC3 KD background showed comparable results with wild type HDAC3 in aspects of contractility and Pericardin deposition. However, deacetylase-dead HDAC3 mutants failed to improve triglyceride accumulation.ConclusionsOur data indicate that HDAC3 plays a deacetylase-independent role in maintaining cardiac contractility and preventing Pericardin deposition as well as a deacetylase-dependent role to maintain triglyceride homestasis.

Published

2022

17. Overexpression of Kif1A in the Developing Drosophila Heart Causes Valvar and Contractility Defects: Implications for Human Congenital Heart Disease

Author

Takeshi Akasaka, Karen Ocorr, Lizhu Lin, Georg Vogler, Rolf Bodmer, and Paul Grossfeld

Subjects

Kif1A, cardiac development, congenital heart disease, aortic valve, Drosophila, myoblasts, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Left-sided congenital heart defects (CHDs) are among the most common forms of congenital heart disease, but a disease-causing gene has only been identified in a minority of cases. Here, we identified a candidate gene for CHDs, KIF1A, that was associated with a chromosomal balanced translocation t(2;8)(q37;p11) in a patient with left-sided heart and aortic valve defects. The breakpoint was in the 5′ untranslated region of the KIF1A gene at 2q37, which suggested that the break affected the levels of Kif1A gene expression. Transgenic fly lines overexpressing Kif1A specifically in the heart muscle (or all muscles) caused diminished cardiac contractility, myofibrillar disorganization, and heart valve defects, whereas cardiac knockdown had no effect on heart structure or function. Overexpression of Kif1A also caused increased collagen IV deposition in the fibrous network that normally surrounds the fly heart. Kif1A overexpression in C2C12 myoblasts resulted in specific displacement of the F-actin fibers, probably through a direct interaction with G-actin. These results point to a Kif1A-mediated disruption of F-actin organization as a potential mechanism for the pathogenesis in at least some human CHDs.

Published

2020

18. Correction: A homozygous KAT2B variant modulates the clinical phenotype of ADD3 deficiency in humans and flies.

Author

Sara Gonçalves, Julie Patat, Maria Clara Guida, Noelle Lachaussée, Christelle Arrondel, Martin Helmstädter, Olivia Boyer, Olivier Gribouval, Marie-Claire Gubler, Geraldine Mollet, Marlène Rio, Marina Charbit, Christine Bole-Feysot, Patrick Nitschke, Tobias B Huber, Patricia G Wheeler, Devon Haynes, Jane Juusola, Thierry Billette de Villemeur, Caroline Nava, Alexandra Afenjar, Boris Keren, Rolf Bodmer, Corinne Antignac, and Matias Simons

Subjects

Genetics, QH426-470

Abstract

[This corrects the article DOI: 10.1371/journal.pgen.1007386.].

Published

2018

19. A homozygous KAT2B variant modulates the clinical phenotype of ADD3 deficiency in humans and flies.

Author

Sara Gonçalves, Julie Patat, Maria Clara Guida, Noelle Lachaussée, Christelle Arrondel, Martin Helmstädter, Olivia Boyer, Olivier Gribouval, Marie-Claire Gubler, Geraldine Mollet, Marlène Rio, Marina Charbit, Christine Bole-Feysot, Patrick Nitschke, Tobias B Huber, Patricia G Wheeler, Devon Haynes, Jane Juusola, Thierry Billette de Villemeur, Caroline Nava, Alexandra Afenjar, Boris Keren, Rolf Bodmer, Corinne Antignac, and Matias Simons

Subjects

Genetics, QH426-470

Abstract

Recent evidence suggests that the presence of more than one pathogenic mutation in a single patient is more common than previously anticipated. One of the challenges hereby is to dissect the contribution of each gene mutation, for which animal models such as Drosophila can provide a valuable aid. Here, we identified three families with mutations in ADD3, encoding for adducin-γ, with intellectual disability, microcephaly, cataracts and skeletal defects. In one of the families with additional cardiomyopathy and steroid-resistant nephrotic syndrome (SRNS), we found a homozygous variant in KAT2B, encoding the lysine acetyltransferase 2B, with impact on KAT2B protein levels in patient fibroblasts, suggesting that this second mutation might contribute to the increased disease spectrum. In order to define the contribution of ADD3 and KAT2B mutations for the patient phenotype, we performed functional experiments in the Drosophila model. We found that both mutations were unable to fully rescue the viability of the respective null mutants of the Drosophila homologs, hts and Gcn5, suggesting that they are indeed pathogenic in flies. While the KAT2B/Gcn5 mutation additionally showed a significantly reduced ability to rescue morphological and functional defects of cardiomyocytes and nephrocytes (podocyte-like cells), this was not the case for the ADD3 mutant rescue. Yet, the simultaneous knockdown of KAT2B and ADD3 synergistically impaired kidney and heart function in flies as well as the adhesion and migration capacity of cultured human podocytes, indicating that mutations in both genes may be required for the full clinical manifestation. Altogether, our studies describe the expansion of the phenotypic spectrum in ADD3 deficiency associated with a homozygous likely pathogenic KAT2B variant and thereby identify KAT2B as a susceptibility gene for kidney and heart disease in ADD3-associated disorders.

Published

2018

20. Clueless, a protein required for mitochondrial function, interacts with the PINK1-Parkin complex in Drosophila

Author

Aditya Sen, Sreehari Kalvakuri, Rolf Bodmer, and Rachel T. Cox

Subjects

Clueless, Mitochondria, TOM20, PINK1, Parkin, Medicine, Pathology, RB1-214

Abstract

Loss of mitochondrial function often leads to neurodegeneration and is thought to be one of the underlying causes of neurodegenerative diseases such as Parkinson's disease (PD). However, the precise events linking mitochondrial dysfunction to neuronal death remain elusive. PTEN-induced putative kinase 1 (PINK1) and Parkin (Park), either of which, when mutated, are responsible for early-onset PD, mark individual mitochondria for destruction at the mitochondrial outer membrane. The specific molecular pathways that regulate signaling between the nucleus and mitochondria to sense mitochondrial dysfunction under normal physiological conditions are not well understood. Here, we show that Drosophila Clueless (Clu), a highly conserved protein required for normal mitochondrial function, can associate with Translocase of the outer membrane (TOM) 20, Porin and PINK1, and is thus located at the mitochondrial outer membrane. Previously, we found that clu genetically interacts with park in Drosophila female germ cells. Here, we show that clu also genetically interacts with PINK1, and our epistasis analysis places clu downstream of PINK1 and upstream of park. In addition, Clu forms a complex with PINK1 and Park, further supporting that Clu links mitochondrial function with the PINK1-Park pathway. Lack of Clu causes PINK1 and Park to interact with each other, and clu mutants have decreased mitochondrial protein levels, suggesting that Clu can act as a negative regulator of the PINK1-Park pathway. Taken together, these results suggest that Clu directly modulates mitochondrial function, and that Clu's function contributes to the PINK1-Park pathway of mitochondrial quality control.

Published

2015

21. PGC-1/Spargel Counteracts High-Fat-Diet-Induced Obesity and Cardiac Lipotoxicity Downstream of TOR and Brummer ATGL Lipase

Author

Soda Balla Diop, Jumana Bisharat-Kernizan, Ryan Tyge Birse, Sean Oldham, Karen Ocorr, and Rolf Bodmer

Subjects

Biology (General), QH301-705.5

Abstract

Obesity and metabolic syndrome are associated with an increased risk for lipotoxic cardiomyopathy, which is strongly correlated with excessive accumulation of lipids in the heart. Obesity- and type-2-diabetes-related disorders have been linked to altered expression of the transcriptional cofactor PGC-1α, which regulates the expression of genes involved in energy metabolism. Using Drosophila, we identify PGC-1/spargel (PGC-1/srl) as a key antagonist of high-fat diet (HFD)-induced lipotoxic cardiomyopathy. We find that HFD-induced lipid accumulation and cardiac dysfunction are mimicked by reduced PGC-1/srl function and reversed by PGC-1/srl overexpression. Moreover, HFD feeding lowers PGC-1/srl expression by elevating TOR signaling and inhibiting expression of the Drosophila adipocyte triglyceride lipase (ATGL) (Brummer), both of which function as upstream modulators of PGC-1/srl. The lipogenic transcription factor SREBP also contributes to HFD-induced cardiac lipotoxicity, likely in parallel with PGC-1/srl. These results suggest a regulatory network of key metabolic genes that modulates lipotoxic heart dysfunction.

Published

2015

22. Cellular Mechanisms of Drosophila Heart Morphogenesis

Author

Georg Vogler and Rolf Bodmer

Subjects

Drosophila, cardiogenesis, morphogenesis, tinman, Cdc42, congenital heart disease, non-muscle myosin, zipper, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Many of the major discoveries in the fields of genetics and developmental biology have been made using the fruit fly, Drosophila melanogaster. With regard to heart development, the conserved network of core cardiac transcription factors that underlies cardiogenesis has been studied in great detail in the fly, and the importance of several signaling pathways that regulate heart morphogenesis, such as Slit/Robo, was first shown in the fly model. Recent technological advances have led to a large increase in the genomic data available from patients with congenital heart disease (CHD). This has highlighted a number of candidate genes and gene networks that are potentially involved in CHD. To validate genes and genetic interactions among candidate CHD-causing alleles and to better understand heart formation in general are major tasks. The specific limitations of the various cardiac model systems currently employed (mammalian and fish models) provide a niche for the fly model, despite its evolutionary distance to vertebrates and humans. Here, we review recent advances made using the Drosophila embryo that identify factors relevant for heart formation. These underline how this model organism still is invaluable for a better understanding of CHD.

Published

2015

23. Genetic architecture of natural variation of cardiac performance from flies to humans

Author

Lionel Spinelli, Saswati Saha, Jaime A Castro Mondragon, Anaïs Kervadec, Michaela Lynott, Laurent Kremmer, Laurence Roder, Sallouha Krifa, Magali Torres, Christine Brun, Georg Vogler, Rolf Bodmer, Alexandre R Colas, Karen Ocorr, Laurent Perrin, Theories and Approaches of Genomic Complexity (TAGC), Aix Marseille Université (AMU)-Institut National de la Santé et de la Recherche Médicale (INSERM), Centre for Molecular Medicine Norway (NCMM), Faculty of Medicine [Oslo], University of Oslo (UiO)-University of Oslo (UiO)-Rigshospitalet [Copenhagen], Copenhagen University Hospital-Copenhagen University Hospital, and Sanford Burnham Prebys Medical Discovery Institute

Subjects

General Immunology and Microbiology, General Neuroscience, Quantitative Trait Loci, Genetic Variation, Heart, General Medicine, General Biochemistry, Genetics and Molecular Biology, [SDV.GEN.GA]Life Sciences [q-bio]/Genetics/Animal genetics, Drosophila melanogaster, Phenotype, Animals, Humans, Gene Regulatory Networks, Genome-Wide Association Study

Abstract

Deciphering the genetic architecture of human cardiac disorders is of fundamental importance but their underlying complexity is a major hurdle. We investigated the natural variation of cardiac performance in the sequenced inbred lines of the Drosophila Genetic Reference Panel (DGRP). Genome-wide associations studies (GWAS) identified genetic networks associated with natural variation of cardiac traits which were used to gain insights as to the molecular and cellular processes affected. Non-coding variants that we identified were used to map potential regulatory non-coding regions, which in turn were employed to predict transcription factors (TFs) binding sites. Cognate TFs, many of which themselves bear polymorphisms associated with variations of cardiac performance, were also validated by heart-specific knockdown. Additionally, we showed that the natural variations associated with variability in cardiac performance affect a set of genes overlapping those associated with average traits but through different variants in the same genes. Furthermore, we showed that phenotypic variability was also associated with natural variation of gene regulatory networks. More importantly, we documented correlations between genes associated with cardiac phenotypes in both flies and humans, which supports a conserved genetic architecture regulating adult cardiac function from arthropods to mammals. Specifically, roles for PAX9 and EGR2 in the regulation of the cardiac rhythm were established in both models, illustrating that the characteristics of natural variations in cardiac function identified in Drosophila can accelerate discovery in humans.

Published

2022

24. Author response: Genetic architecture of natural variation of cardiac performance from flies to humans

Author

Lionel Spinelli, Saswati Saha, Jaime A Castro Mondragon, Anaïs Kervadec, Michaela Lynott, Laurent Kremmer, Laurence Roder, Sallouha Krifa, Magali Torres, Christine Brun, Georg Vogler, Rolf Bodmer, Alexandre R Colas, Karen Ocorr, and Laurent Perrin

Published

2022

25. Author Reply to Peer Reviews of Genetic architecture of natural variation of cardiac performance in flies

Author

Laurent Perrin, Karen Ocorr, Alexandre R. Colas, Rolf Bodmer, Georg Vogler, Christine Brun, Magali Torres, Sallouha Krifa, Laurence Roder, Laurent Kremmer, Anaïs Kervadec, Jaime A Castro-Mondragon, Lionel Spinelli, and Saswati Saha

Published

2022

26. Functional analysis across model systems implicates ribosomal proteins in growth and proliferation defects associated with hypoplastic left heart syndrome

Author

Tanja Nielsen, Anaïs Kervadec, Maria A. Missinato, Michaela Lynott, Xin-Xin I. Zeng, Marie Berenguer, Stanley M. Walls, Analyne Schroeder, Katja Birker, Greg Duester, Paul Grossfeld, Timothy J. Nelson, Timothy M. Olson, Karen Ocorr, Rolf Bodmer, Jeanne L. Theis, Georg Vogler, and Alexandre R. Colas

Abstract

Hypoplastic left heart syndrome (HLHS) is the most lethal congenital heart disease (CHD). The pathogenesis of HLHS is poorly understood and due to the likely oligogenic complexity of the disease, definitive HLHS-causing genes have not yet been identified. Postulating that impaired cardiomyocyte proliferation as a likely important contributing mechanism to HLHS pathogenesis, and we conducted a genome-wide siRNA screen to identify genes affecting proliferation of human iPSC-derived cardiomyocytes (hPSC-CMs). This yielded ribosomal protein (RP) genes as the most prominent class of effectors of CM proliferation. In parallel, whole genome sequencing and rare variant filtering of a cohort of 25 HLHS proband-parent trios with poor clinical outcome revealed enrichment of rare variants of RP genes. In addition, in another familial CHD case of HLHS proband we identified a rare, predicted-damaging promoter variant affectingRPS15Athat was shared between the proband and a distant relative with CHD. Functional testing with an integrated multi-model system approach reinforced the idea that RP genes are major regulators of cardiac growth and proliferation, thus potentially contributing to hypoplastic phenotype observed in HLHS patients. Cardiac knockdown (KD) of RP genes with promoter or coding variants (RPS15A, RPS17, RPL26L1, RPL39, RPS15) reduced proliferation in generic hPSC-CMs and caused malformed hearts, heart-loss or even lethality inDrosophila. In zebrafish, diminishedrps15afunction caused reduced CM numbers, heart looping defects, or weakened contractility, while reducedrps17orrpl39function caused reduced ventricular size or systolic atrial dysfunction, respectively. Importantly, genetic interactions betweenRPS15Aand core cardiac transcription factorsTBX5in CMs,Drosocross, pannierandtinmanin flies, andtbx5andnkx2-7(nkx2-5paralog) in fish, support a specific role for RP genes in heart development. Furthermore,RPS15AKD-induced heart/CM proliferation defects were significantly attenuated byp53KD in both hPSC-CMs and zebrafish, and by Hippo activation (YAP/yorkieoverexpression) in developing fly hearts. Based on these findings, we conclude that RP genes play critical roles in cardiogenesis and constitute an emerging novel class of gene candidates likely involved in HLHS and other CHDs.

Published

2022

27. Mitochondrial MICOS complex genes, implicated in hypoplastic left heart syndrome, maintain cardiac contractility and actomyosin integrity

Author

Katja Birker, Natalie J. Kirkland, Jeanne L. Theis, Zachary C. Fogarty, Maria Azzurra Missinato, Sreehari Kalvakuri, Paul Grossfeld, Adam J. Engler, Karen Ocorr, Timothy J. Nelson, Alexandre R. Colas, Timothy M. Olson, Georg Vogler, and Rolf Bodmer

Abstract

Hypoplastic left heart syndrome (HLHS) is a severe congenital heart disease (CHD) with a likely oligogenic etiology, but our understanding of the genetic complexities and pathogenic mechanisms leading to HLHS is limited. We therefore performed whole genome sequencing (WGS) on a large cohort of HLHS patients and their families to identify candidate genes that were then tested in Drosophila heart model for functional and structural requirements. Bioinformatic analysis of WGS data from an index family comprised of a HLHS proband born to consanguineous parents and postulated to have a homozygous recessive disease etiology, prioritized 9 candidate genes with rare, predicted damaging homozygous variants. Of the candidate HLHS gene homologs tested, cardiac-specific knockdown (KD) of mitochondrial MICOS complex subunit dCHCHD3/6 resulted in drastically compromised heart contractility, diminished levels of sarcomeric actin and myosin, reduced cardiac ATP levels, and mitochondrial fission-fusion defects. Interestingly, these heart defects were similar to those inflicted by cardiac KD of ATP synthase subunits of the electron transport chain (ETC), consistent with the MICOS complex’s role in maintaining cristae morphology and ETC complex assembly. Analysis of 183 genomes of HLHS patient-parent trios revealed five additional HLHS probands with rare, predicted damaging variants in CHCHD3 or CHCHD6. Hypothesizing an oligogenic basis for HLHS, we tested 60 additional prioritized candidate genes in these cases for genetic interactions with CHCHD3/6 in sensitized fly hearts. Moderate KD of CHCHD3/6 in combination with Cdk12 (activator of RNA polymerase II), RNF149 (E3 ubiquitin ligase), or SPTBN1 (scaffolding protein) caused synergistic heart defects, suggesting the potential involvement of a diverse set of pathways in HLHS. Further elucidation of novel candidate genes and genetic interactions of potentially disease-contributing pathways is expected to lead to a better understanding of HLHS and other CHDs.

Published

2022

28. ROS Regulate Cardiac Function via a Distinct Paracrine Mechanism

Author

Hui-Ying Lim, Weidong Wang, Jianming Chen, Karen Ocorr, and Rolf Bodmer

Subjects

Biology (General), QH301-705.5

Abstract

Reactive oxygen species (ROS) can act cell autonomously and in a paracrine manner by diffusing into nearby cells. Here, we reveal a ROS-mediated paracrine signaling mechanism that does not require entry of ROS into target cells. We found that under physiological conditions, nonmyocytic pericardial cells (PCs) of the Drosophila heart contain elevated levels of ROS compared to the neighboring cardiomyocytes (CMs). We show that ROS in PCs act in a paracrine manner to regulate normal cardiac function, not by diffusing into the CMs to exert their function, but by eliciting a downstream D-MKK3-D-p38 MAPK signaling cascade in PCs that acts on the CMs to regulate their function. We find that ROS-D-p38 signaling in PCs during development is also important for establishing normal adult cardiac function. Our results provide evidence for a previously unrecognized role of ROS in mediating PC/CM interactions that significantly modulates heart function.

Published

2014

29. Nascent Polypeptide Associated Complex–alphaand Signal Recognition Particle are required for cardiac development and remodeling

Author

Analyne M. Schroeder, Georg Vogler, Alexandre R. Colas, and Rolf Bodmer

Abstract

Congenital Heart Disease (CHD) is driven by a strong genetic predisposition, yet only a small subset of patients (∼20%) are diagnosed with a precise genetic cause. Therefore, expanding the pool of genes associated with CHD and establishing the functional relationships between genes can assemble a more comprehensive genetic network to better understand cardiac development and pathogenesis. In our studies, we identified protein biogenesis cofactors Nascent polypeptide Associated Complex (NAC) and Signal Recognition Particle (SRP) that bind disparate subsets of emerging nascent polypeptides at the ribosome exit site to direct polypeptide fates, as novel regulators of cell differentiation and cardiac morphogenesis. Knockdown (KD) of the alpha-(Nacα)or beta- subunit (bicaudal, bic)of NAC in the developingDrosophilaheart led to disruption of cardiac remodeling during pupal stages resulting in an adult fly with no heart. Heart loss was rescued by combined KD ofNacαwith theHoxgeneAbd-B.Consistent with a central role for this interaction in the regulation of cardiogenesis, KD ofNacαin Cardiac Progenitors derived from human iPSCs impaired cardiac differentiation while co-KD with mammalianHoxgenesHOXC12 and HOXD12rescued this phenotype. The effect ofNacαKD on the fly heart was temporally regulated, in that KD in embryo or in pupae caused only a partial loss of the heart, whereas KD during both stages led to heart loss similar to continuous KD throughout life. This suggests thatNacαKD already in the embryo may reprogram cells leading to aberrant cardiac remodeling during pupal stages. Lastly, KD of several SRP subunits individually in the fly heart produced a range of cardiac phenotypes that targeted specific segments and cell types, indicating spatially regulated activities of SRP components in the heart. Together, these data suggest that despite NAC and SRP ubiquitous presence, they displayed spatially and temporally fine-tuned activities for proper cardiac morphogenesis.Nacα’sinteraction with cardiac-specificHoxgene functions builds upon the novel role of this pathway and expands our understanding of the complex genetic networks involved in cardiac development and pathogenesis.

Published

2022

30. A new method for detection and quantification of heartbeat parameters in Drosophila, zebrafish, and embryonic mouse hearts

Author

Martin Fink, Carles Callol-Massot, Angela Chu, Pilar Ruiz-Lozano, Juan Carlos Izpisua Belmonte, Wayne Giles, Rolf Bodmer, and Karen Ocorr

Subjects

Biology (General), QH301-705.5

Abstract

The genetic basis of heart development is remarkably conserved from Drosophila to mammals, and insights from flies have greatly informed our understanding of vertebrate heart development. Recent evidence suggests that many aspects of heart function are also conserved and the genes involved in heart development also play roles in adult heart function. We have developed a Drosophila heart preparation and movement analysis algorithm that allows quantification of functional parameters. Our methodology combines high-speed optical recording of beating hearts with a robust, semi-automated analysis to accurately detect and quantify, on a beat-to-beat basis, not only heart rate but also diastolic and systolic intervals, systolic and diastolic diameters, percent fractional shortening, contraction wave velocity, and cardiac arrhythmicity. Here, we present a detailed analysis of hearts from adult Drosophila, 2–3-day-old zebrafish larva, and 8-day-old mouse embryos, indicating that our methodology is potentially applicable to an array of biological models. We detect progressive age-related changes in fly hearts as well as subtle but distinct cardiac deficits in Tbx5 heterozygote mutant zebrafish. Our methodology for quantifying cardiac function in these genetically tractable model systems should provide valuable insights into the genetics of heart function.

Published

2009

31. Age-dependent Lamin remodeling induces cardiac dysfunction via dysregulation of cardiac transcriptional programs

Author

Pranjali Beri, Geo Vogler, Natalie J. Kirkland, Rolf Bodmer, Bill Hum, James D. Hocker, Edward G. Lakatta, Mingyi Wang, Bing Ren, Alexander J. Whitehead, and Adam J. Engler

Subjects

medicine.medical_specialty, Aging, business.industry, 1.1 Normal biological development and functioning, Age dependent, Cardiovascular, Cardiac dysfunction, Endocrinology, Heart Disease, Internal medicine, Genetics, Medicine, 2.1 Biological and endogenous factors, business, Lamin

Abstract

As we age, structural changes contribute to progressive decline in organ function, which in the heart acts through poorly characterized mechanisms. Utilizing the rapidly aging fruit fly model with its significant homology to the human cardiac proteome, we found that cardiomyocytes exhibit progressive loss of Lamin C (mammalian Lamin A/C homologue) with age. Unlike other tissues and laminopathies, we observe decreasing nuclear size, while nuclear stiffness increases. Premature genetic reduction of Lamin C phenocopies aging’s effects on the nucleus, and subsequently decreases heart contractility and sarcomere organization. Surprisingly, Lamin C reduction downregulates myogenic transcription factors and cytoskeletal regulators, possibly via reduced chromatin accessibility. Subsequently, we find an adult-specific role for cardiac transcription factors and show that maintenance of Lamin C sustains their expression and prevents age-dependent cardiac decline. Our findings are conserved in aged non-human primates and mice, demonstrating age-dependent nuclear remodeling is a major mechanism contributing to cardiac dysfunction.

Published

2021

32. Atrial Fibrillation Genomics: Discovery and Translation

Author

Karen Ocorr, Rolf Bodmer, Evan D. Muse, David H. Yoo, Alexandre R. Colas, and Christopher J. Larson

Subjects

business.industry, Drug discovery, Atrial fibrillation, Genomics, Genome-wide association study, Computational biology, Disease, medicine.disease, Precision medicine, Digital health, medicine, Cardiology and Cardiovascular Medicine, business, Genetic association

Abstract

Our understanding of the fundamental cellular and molecular factors leading to atrial fibrillation (AF) remains stagnant despite significant advancement in ablation and device technologies. Diagnosis and prevention strategies fall behind that of treatment, but expanding knowledge in AF genetics holds the potential to drive progress. We aim to review how an understanding of the genetic contributions to AF can guide an approach to individualized risk stratification and novel avenues in drug discovery. Rare familial forms of AF identified monogenic contributions to the development of AF. Genome-wide association studies (GWAS) further identified single-nucleotide polymorphisms (SNPs) suggesting polygenic and multiplex nature of this common disease. Polygenic risk scores accounting for the multitude of associated SNPs that each confer mildly elevated risk have been developed to translate genetic information into clinical practice, though shortcomings remain. Additionally, novel laboratory methods have been empowered by recent genetic findings to enhance drug discovery efforts. AF is increasingly recognized as a disease with a significant genetic component. With expanding sequencing technologies and accessibility, polygenic risk scores can help identify high risk individuals. Advancement in digital health tools, artificial intelligence and machine learning based on standard electrocardiograms, and genomic driven drug discovery may be integrated to deliver a sophisticated level of precision medicine in this modern era of emphasis on prevention. Randomized, prospective studies to demonstrate clinical benefits of these available tools are needed to validate this approach.

Published

2021

33. Klf15 Is Critical for the Development and Differentiation of Drosophila Nephrocytes.

Author

Jessica R Ivy, Maik Drechsler, James H Catterson, Rolf Bodmer, Karen Ocorr, Achim Paululat, and Paul S Hartley

Subjects

Medicine, Science

Abstract

Insect nephrocytes are highly endocytic scavenger cells that represent the only invertebrate model for the study of human kidney podocytes. Despite their importance, nephrocyte development is largely uncharacterised. This work tested whether the insect ortholog of mammalian Kidney Krüppel-Like Factor (Klf15), a transcription factor required for mammalian podocyte differentiation, was required for insect nephrocyte development. It was found that expression of Drosophila Klf15 (dKlf15, previously known as Bteb2) was restricted to the only two nephrocyte populations in Drosophila, the garland cells and pericardial nephrocytes. Loss of dKlf15 function led to attrition of both nephrocyte populations and sensitised larvae to the xenotoxin silver nitrate. Although pericardial nephrocytes in dKlf15 loss of function mutants were specified during embryogenesis, they failed to express the slit diaphragm gene sticks and stones and did not form slit diaphragms. Conditional silencing of dKlf15 in adults led to reduced surface expression of the endocytic receptor Amnionless and loss of in vivo scavenger function. Over-expression of dKlf15 increased nephrocyte numbers and rescued age-dependent decline in nephrocyte function. The data place dKlf15 upstream of sns and Amnionless in a nephrocyte-restricted differentiation pathway and suggest dKlf15 expression is both necessary and sufficient to sustain nephrocyte differentiation. These findings explain the physiological relevance of dKlf15 in Drosophila and imply that the role of KLF15 in human podocytes is evolutionarily conserved.

Published

2015

34. Atrial Fibrillation Genomics: Discovery and Translation

Author

David H, Yoo, Rolf, Bodmer, Karen, Ocorr, Christopher J, Larson, Alexandre R, Colas, and Evan D, Muse

Subjects

Artificial Intelligence, Atrial Fibrillation, Humans, Genetic Predisposition to Disease, Genomics, Prospective Studies, Genome-Wide Association Study

Abstract

Our understanding of the fundamental cellular and molecular factors leading to atrial fibrillation (AF) remains stagnant despite significant advancement in ablation and device technologies. Diagnosis and prevention strategies fall behind that of treatment, but expanding knowledge in AF genetics holds the potential to drive progress. We aim to review how an understanding of the genetic contributions to AF can guide an approach to individualized risk stratification and novel avenues in drug discovery.Rare familial forms of AF identified monogenic contributions to the development of AF. Genome-wide association studies (GWAS) further identified single-nucleotide polymorphisms (SNPs) suggesting polygenic and multiplex nature of this common disease. Polygenic risk scores accounting for the multitude of associated SNPs that each confer mildly elevated risk have been developed to translate genetic information into clinical practice, though shortcomings remain. Additionally, novel laboratory methods have been empowered by recent genetic findings to enhance drug discovery efforts. AF is increasingly recognized as a disease with a significant genetic component. With expanding sequencing technologies and accessibility, polygenic risk scores can help identify high risk individuals. Advancement in digital health tools, artificial intelligence and machine learning based on standard electrocardiograms, and genomic driven drug discovery may be integrated to deliver a sophisticated level of precision medicine in this modern era of emphasis on prevention. Randomized, prospective studies to demonstrate clinical benefits of these available tools are needed to validate this approach.

Published

2021

35. Genetic architecture of natural variation of cardiac performance: from flies to Humans

Author

Alexandre R. Colas, Rolf Bodmer, Laurent Kremmer, Georg Vogler, Laurence Röder, Anaïs Kervadec, Karen Ocorr, Laurent Perrin, Krifa Sallouha, Lionel Spinelli, Magali Torres, Jaime A. Castro-Mondragon, Saswati Saha, and Christine Brun

Subjects

Cardiac function curve, 0303 health sciences, Computational biology, Biology, Genome, Phenotype, Genetic architecture, 03 medical and health sciences, 0302 clinical medicine, Natural population growth, 030220 oncology & carcinogenesis, Epistasis, Gene, Function (biology), 030304 developmental biology

Abstract

Background Deciphering the genetic architecture of cardiac disorders is of fundamental importance but their underlying complexity is a major hurdle. Drosophila has gained importance as a useful model to study heart development and function and allows the analysis of organismal traits in a physiologically relevant and accessible system. Our aim was to (i) identify in flies the loci associated to natural variations of cardiac performances among a natural population, (ii) decipher how these variants interact with each other and with the environment to impact cardiac traits, (iii) gain insights about the molecular and cellular processes affected, (iv) determine whether the genetic architecture of cardiac disorders is conserved with humans. Methods and Results We investigated the genetic architecture of natural variations of cardiac performance in the sequenced inbred lines of the Drosophila Genetic Reference Panel (DGRP). Genome Wide Associations (GWA) for single markers and epistatic interactions identified genetic networks associated with natural variations of cardiac traits that were extensively validated in vivo. Non-coding variants were used to map potential regulatory non-coding regions which in turn were employed to predict Transcription Factors (TFs) binding sites. Cognate TFs, many of which themselves bear polymorphisms associated with variations of cardiac performance, were validated by heart specific knockdown. We also analyzed natural variations of cardiac traits variance that revealed unique features of their micro-environmental plasticity. More importantly, correlations between genes associated with cardiac phenotypes both in flies and in humans support the conserved genetic architecture of cardiac functioning from arthropods to mammals. The characteristics of natural variations in cardiac function established in Drosophila may thus guide the analysis of cardiac disorders in humans. Using human iPSC-derived cardiomyocytes, we indeed characterized a conserved function for PAX9 and EGR2 in the regulation of the cardiac rhythm Conclusion In-depth analysis of the genetic architecture of natural variations of cardiac performance in flies combined with functional validations in vivo and in human iPSC-CM represents a major achievement in understanding the mechanisms underlying the genetic architecture of these complex traits and a valuable resource for the identification of genes and mechanisms involved in cardiac disorders in humans.

Published

2021

36. Screening assays for heart function mutants in Drosophila

Author

Robert J. Wessells and Rolf Bodmer

Subjects

Biology (General), QH301-705.5

Abstract

The rapid life cycle and genetic tractability of Drosophila make it an ideal organism for large-scale genetic screens. Here we describe a novel assay for pupal heart rate and rhythmicity, as well as techniques to measure adult cardiac stress response. These assays can be powerfully combined to concurrently screen for both mutations affecting cardiac function and mutations affecting the age-dependent decline in adult cardiac stress response. Mutations identified in such screens have the potential to contribute greatly to the understanding of both congenital heart disease and the regulation of age-dependent decline in cardiac function in the human population.

Published

2004

37. As time flies by: Investigating cardiac aging in the short-lived Drosophila model

Author

Rolf Bodmer, Paul S. Hartley, Anthony Cammarato, Anna C. Blice-Baum, Peter D. Adams, and Maria Clara Guida

Subjects

0301 basic medicine, Cardiac function curve, Senescence, Aging, ved/biology.organism_classification_rank.species, Disease, 030204 cardiovascular system & hematology, Article, Epigenesis, Genetic, 03 medical and health sciences, 0302 clinical medicine, Animals, Humans, Model organism, Exercise, Molecular Biology, Drosophila, biology, ved/biology, Heart, biology.organism_classification, Drosophila melanogaster, 030104 developmental biology, Proteostasis, Models, Animal, Molecular Medicine, Neuroscience

Abstract

Aging is associated with a decline in heart function across the tissue, cellular, and molecular levels. The risk of cardiovascular disease grows significantly over time, and as developed countries continue to see an increase in lifespan, the cost of cardiovascular healthcare for the elderly will undoubtedly rise. The molecular basis for cardiac function deterioration with age is multifaceted and not entirely clear, and there is a limit to what investigations can be performed on human subjects or mammalian models. Drosophila melanogaster has emerged as a useful model organism for studying aging in a short timeframe, benefitting from a suite of molecular and genetic tools and displaying highly conserved traits of cardiac senescence. Here, we discuss recent advances in our understanding of cardiac aging and how the fruit fly has aided in these developments.

Published

2019

38. Intergenerational inheritance of high fat diet-induced cardiac lipotoxicity in Drosophila

Author

Antonello Mai, Maria Clara Guida, Soda Balla Diop, Paula Coutinho Toto, Ryan Birse, Peter D. Adams, Alessandra Dall’Agnese, Pier Lorenzo Puri, and Rolf Bodmer

Subjects

0301 basic medicine, Male, Heart disease, Cardiomyopathy, General Physics and Astronomy, 02 engineering and technology, Animals, Genetically Modified, Histones, Drosophila Proteins, Positive Transcriptional Elongation Factor B, lcsh:Science, 2. Zero hunger, Multidisciplinary, 021001 nanoscience & nanotechnology, Genetically modified organism, Lipotoxicity, Drosophila, Female, 0210 nano-technology, Cardiomyopathies, medicine.medical_specialty, Offspring, Science, Biology, Diet, High-Fat, Methylation, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Internal medicine, medicine, Animals, Humans, Genetic Predisposition to Disease, Obesity, Triglycerides, Myocardium, fungi, General Chemistry, Lipase, medicine.disease, Lipid Metabolism, Disease Models, Animal, 030104 developmental biology, Endocrinology, Heart failure, Adipose triglyceride lipase, lcsh:Q

Abstract

Obesity is strongly correlated with lipotoxic cardiomyopathy, heart failure and thus mortality. The incidence of obesity has reached alarming proportions worldwide, and increasing evidence suggests that the parents’ nutritional status may predispose their offspring to lipotoxic cardiomyopathy. However, to date, mechanisms underlying intergenerational heart disease risks have yet to be elucidated. Here we report that cardiac dysfunction induced by high-fat-diet (HFD) persists for two subsequent generations in Drosophila and is associated with reduced expression of two key metabolic regulators, adipose triglyceride lipase (ATGL/bmm) and transcriptional cofactor PGC-1. We provide evidence that targeted expression of ATGL/bmm in the offspring of HFD-fed parents protects them, and the subsequent generation, from cardio-lipotoxicity. Furthermore, we find that intergenerational inheritance of lipotoxic cardiomyopathy correlates with elevated systemic H3K27 trimethylation. Lowering H3K27 trimethylation genetically or pharmacologically in the offspring of HFD-fed parents prevents cardiac pathology. This suggests that metabolic homeostasis is epigenetically regulated across generations., Animal studies have shown that the nutritional status of parents can predispose the offspring to obesity and obesity-related diseases. Here the authors show that cardiac dysfunction induced by a high-fat diet persists for two generations in Drosophila, and that targeted expression of ATGL/bmm in the offspring, as well as inhibition of H3K27 trimethylation, is cardioprotective.

Published

2019

39. Conserved Role of the Large Conductance Calcium-Activated Potassium Channel, K Ca 1.1, in Sinus Node Function and Arrhythmia Risk

Author

Georg Vogler, Diane Fatkin, Katja Birker, Christiana Leimena, Ann-Kristin Altekoester, Peter C. M. Molenaar, Karen Ocorr, David G. Allen, Richard P. Harvey, Halina Dobrzynski, Inken G. Huttner, Arie Jacoby, Magdalena Soka, Renee Johnson, Andrew Atkinson, Vesna Nikolova-Krstevski, Adam P. Hill, Rolf Bodmer, Yue-Kun Ju, Sreehari Kalvakuri, Santiago Pineda, Dirk F. van Helden, Charles D. Cox, Dennis L. Kuchar, Monique Ohanian, and Gunjan Trivedi

Subjects

0301 basic medicine, Bradycardia, medicine.medical_specialty, Chemistry, Conductance, Atrial fibrillation, General Medicine, 030204 cardiovascular system & hematology, medicine.disease, Calcium-activated potassium channel, Sinus node function, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Internal medicine, medicine, Cardiology, medicine.symptom, Atrium (heart)

Abstract

Background: KCNMA1 encodes the α-subunit of the large-conductance Ca 2+ -activated K + channel, K Ca 1.1, and lies within a linkage interval for atrial fibrillation (AF). Insights into the cardiac functions of K Ca 1.1 are limited, and KCNMA1 has not been investigated as an AF candidate gene. Methods: The KCNMA1 gene was sequenced in 118 patients with familial AF. The role of K Ca 1.1 in normal cardiac structure and function was evaluated in humans, mice, zebrafish, and fly. A novel KCNMA1 variant was functionally characterized. Results: A complex KCNMA1 variant was identified in 1 kindred with AF. To evaluate potential disease mechanisms, we first evaluated the distribution of K Ca 1.1 in normal hearts using immunostaining and immunogold electron microscopy. K Ca 1.1 was seen throughout the atria and ventricles in humans and mice, with strong expression in the sinus node. In an ex vivo murine sinoatrial node preparation, addition of the K Ca 1.1 antagonist, paxilline, blunted the increase in beating rate induced by adrenergic receptor stimulation. Knockdown of the K Ca 1.1 ortholog, kcnma1b , in zebrafish embryos resulted in sinus bradycardia with dilatation and reduced contraction of the atrium and ventricle. Genetic inactivation of the Drosophila K Ca 1.1 ortholog, slo , systemically or in adult stages, also slowed the heartbeat and produced fibrillatory cardiac contractions. Electrophysiological characterization of slo -deficient flies revealed bursts of action potentials, reflecting increased events of fibrillatory arrhythmias. Flies with cardiac-specific overexpression of the human KCNMA1 mutant also showed increased heart period and bursts of action potentials, similar to the K Ca 1.1 loss-of-function models. Conclusions: Our data point to a highly conserved role of K Ca 1.1 in sinus node function in humans, mice, zebrafish, and fly and suggest that K Ca 1.1 loss of function may predispose to AF.

Published

2021

40. Conserved Role of the Large Conductance Calcium-Activated Potassium Channel, K

Author

Santiago, Pineda, Vesna, Nikolova-Krstevski, Christiana, Leimena, Andrew J, Atkinson, Ann-Kristin, Altekoester, Charles D, Cox, Arie, Jacoby, Inken G, Huttner, Yue-Kun, Ju, Magdalena, Soka, Monique, Ohanian, Gunjan, Trivedi, Sreehari, Kalvakuri, Katja, Birker, Renee, Johnson, Peter, Molenaar, Dennis, Kuchar, David G, Allen, Dirk F, van Helden, Richard P, Harvey, Adam P, Hill, Rolf, Bodmer, Georg, Vogler, Halina, Dobrzynski, Karen, Ocorr, and Diane, Fatkin

Subjects

Embryo, Nonmammalian, Indoles, Polymorphism, Genetic, Action Potentials, Original Articles, Zebrafish Proteins, Atrial Function, Myocardial Contraction, Pedigree, Mice, Atrial Fibrillation, Animals, Humans, RNA Interference, Heart Atria, RNA, Small Interfering, Large-Conductance Calcium-Activated Potassium Channel alpha Subunits, Zebrafish, Sinoatrial Node

Abstract

BACKGROUND: KCNMA1 encodes the α-subunit of the large-conductance Ca(2+)-activated K(+) channel, K(Ca)1.1, and lies within a linkage interval for atrial fibrillation (AF). Insights into the cardiac functions of K(Ca)1.1 are limited, and KCNMA1 has not been investigated as an AF candidate gene. METHODS: The KCNMA1 gene was sequenced in 118 patients with familial AF. The role of K(Ca)1.1 in normal cardiac structure and function was evaluated in humans, mice, zebrafish, and fly. A novel KCNMA1 variant was functionally characterized. RESULTS: A complex KCNMA1 variant was identified in 1 kindred with AF. To evaluate potential disease mechanisms, we first evaluated the distribution of K(Ca)1.1 in normal hearts using immunostaining and immunogold electron microscopy. K(Ca)1.1 was seen throughout the atria and ventricles in humans and mice, with strong expression in the sinus node. In an ex vivo murine sinoatrial node preparation, addition of the K(Ca)1.1 antagonist, paxilline, blunted the increase in beating rate induced by adrenergic receptor stimulation. Knockdown of the K(Ca)1.1 ortholog, kcnma1b, in zebrafish embryos resulted in sinus bradycardia with dilatation and reduced contraction of the atrium and ventricle. Genetic inactivation of the Drosophila K(Ca)1.1 ortholog, slo, systemically or in adult stages, also slowed the heartbeat and produced fibrillatory cardiac contractions. Electrophysiological characterization of slo-deficient flies revealed bursts of action potentials, reflecting increased events of fibrillatory arrhythmias. Flies with cardiac-specific overexpression of the human KCNMA1 mutant also showed increased heart period and bursts of action potentials, similar to the K(Ca)1.1 loss-of-function models. CONCLUSIONS: Our data point to a highly conserved role of K(Ca)1.1 in sinus node function in humans, mice, zebrafish, and fly and suggest that K(Ca)1.1 loss of function may predispose to AF.

Published

2021

41. Single-cell sequencing of theDrosophilaembryonic heart and muscle cells during differentiation and maturation

Author

Rolf Bodmer, Marco Tamayo, Yoav Altman, Bill Hum, and Georg Vogler

Subjects

Transcriptome, Heart morphogenesis, Cell type, Single cell sequencing, Embryonic heart, Gene regulatory network, Myocyte, Biology, Transcription factor, Cell biology

Abstract

The developingDrosophilaheart consists of cardioblasts that differentiate into different types of cardiomyocytes and pericardial cells. A large body of work has identified numerous genes and pathways involved in heart specification and differentiation, downstream of cardiac transcription factors, such as Tinman (NKX2-5) and Dorsocross1/2/3 (TBX5). The advent of single-cell RNA sequencing (scRNAseq) technology allowed us for the first time to describe the transcriptome of different cardiac cell types in theDrosophilamodel at high resolution. Here, we applied scRNAseq on sorted cells of late-stageDrosophilaembryos expressing a cardiac GFP reporter. We find distinct expression profiles of cardioblasts as they mature to cardiomyocytes, as well as discretely clustering pericardial cells, including a set expressing Tinman that potentially assist in heart morphogenesis. In addition, we describe other cell types that were sequenced as by-catch due to low but distinct extracardiac expression of the GFP reporter. Our studies on wildtype cardioblasts will be the foundation for investigating developmental profiles in mutant backgrounds and for generating gene regulatory networks at single-cell resolution during cardiogenesis.

Published

2021

42. X-gal Staining of Drosophila Embryos Compatible with Antibody Staining or In Situ Hybridization

Author

Ming-Tsan Su, Krista Golden, and Rolf Bodmer

Subjects

Biology (General), QH301-705.5

Published

1998

43. Multiplexin promotes heart but not aorta morphogenesis by polarized enhancement of slit/robo activity at the heart lumen.

Author

Nofar Harpaz, Elly Ordan, Karen Ocorr, Rolf Bodmer, and Talila Volk

Subjects

Genetics, QH426-470

Abstract

The Drosophila heart tube represents a structure that similarly to vertebrates' primary heart tube exhibits a large lumen; the mechanisms promoting heart tube morphology in both Drosophila and vertebrates are poorly understood. We identified Multiplexin (Mp), the Drosophila orthologue of mammalian Collagen-XV/XVIII, and the only structural heart-specific protein described so far in Drosophila, as necessary and sufficient for shaping the heart tube lumen, but not that of the aorta. Mp is expressed specifically at the stage of heart tube closure, in a polarized fashion, uniquely along the cardioblasts luminal membrane, and its absence results in an extremely small heart tube lumen. Importantly, Mp forms a protein complex with Slit, and interacts genetically with both slit and robo in the formation of the heart tube. Overexpression of Mp in cardioblasts promotes a large heart lumen in a Slit-dependent manner. Moreover, Mp alters Slit distribution, and promotes the formation of multiple Slit endocytic vesicles, similarly to the effect of overexpression of Robo in these cells. Our data are consistent with Mp-dependent enhancement of Slit/Robo activity and signaling, presumably by affecting Slit protein stabilization, specifically at the lumen side of the heart tube. This activity results with a Slit-dependent, local reduction of F-actin levels at the heart luminal membrane, necessary for forming the large heart tube lumen. Consequently, lack of Mp results in decreased diastolic capacity, leading to reduced heart contractility, as measured in live fly hearts. In summary, these findings show that the polarized localization of Mp controls the direction, timing, and presumably the extent of Slit/Robo activity and signaling at the luminal membrane of the heart cardioblasts. This regulation is essential for the morphogenetic changes that sculpt the heart tube in Drosophila, and possibly in forming the vertebrates primary heart tube.

Published

2013

44. Survival response to increased ceramide involves metabolic adaptation through novel regulators of glycolysis and lipolysis.

Author

Niraj K Nirala, Motiur Rahman, Stanley M Walls, Alka Singh, Lihua Julie Zhu, Takeshi Bamba, Eiichiro Fukusaki, Sargur M Srideshikan, Greg L Harris, Y Tony Ip, Rolf Bodmer, and Usha R Acharya

Subjects

Genetics, QH426-470

Abstract

The sphingolipid ceramide elicits several stress responses, however, organisms survive despite increased ceramide but how they do so is poorly understood. We demonstrate here that the AKT/FOXO pathway regulates survival in increased ceramide environment by metabolic adaptation involving changes in glycolysis and lipolysis through novel downstream targets. We show that ceramide kinase mutants accumulate ceramide and this leads to reduction in energy levels due to compromised oxidative phosphorylation. Mutants show increased activation of Akt and a consequent decrease in FOXO levels. These changes lead to enhanced glycolysis by upregulating the activity of phosphoglyceromutase, enolase, pyruvate kinase, and lactate dehydrogenase to provide energy. A second major consequence of AKT/FOXO reprogramming in the mutants is the increased mobilization of lipid from the gut through novel lipase targets, CG8093 and CG6277 for energy contribution. Ubiquitous reduction of these targets by knockdown experiments results in semi or total lethality of the mutants, demonstrating the importance of activating them. The efficiency of these adaptive mechanisms decreases with age and leads to reduction in adult life span of the mutants. In particular, mutants develop cardiac dysfunction with age, likely reflecting the high energy requirement of a well-functioning heart. The lipases also regulate physiological triacylglycerol homeostasis and are important for energy metabolism since midgut specific reduction of them in wild type flies results in increased sensitivity to starvation and accumulation of triglycerides leading to cardiac defects. The central findings of increased AKT activation, decreased FOXO level and activation of phosphoglyceromutase and pyruvate kinase are also observed in mice heterozygous for ceramide transfer protein suggesting a conserved role of this pathway in mammals. These data reveal novel glycolytic and non-autonomous lipolytic pathways in response to increased ceramide for sustenance of high energy demanding organ functions like the heart.

Published

2013

45. Complex genetic architecture of cardiac disease in a wild type inbred strain of Drosophila melanogaster.

Author

Zhi Zhang, Benjamin Hsieh, Amy Poe, Julie Anderson, Karen Ocorr, Greg Gibson, and Rolf Bodmer

Subjects

Medicine, Science

Abstract

Natural populations of the fruit fly, Drosophila melanogaster, segregate genetic variation that leads to cardiac disease phenotypes. One nearly isogenic line from a North Carolina peach orchard, WE70, is shown to harbor two genetically distinct heart phenotypes: elevated incidence of arrhythmias, and a dramatically constricted heart diameter in both diastole and systole, with resemblance to restrictive cardiomyopathy in humans. Assuming the source to be rare variants of large effect, we performed Bulked Segregant Analysis using genomic DNA hybridization to Affymetrix chips to detect single feature polymorphisms, but found that the mutant phenotypes are more likely to have a polygenic basis. Further mapping efforts revealed a complex architecture wherein the constricted cardiomyopathy phenotype was observed in individual whole chromosome substitution lines, implying that variants on both major autosomes are sufficient to produce the phenotype. A panel of 170 Recombinant Inbred Lines (RIL) was generated, and a small subset of mutant lines selected, but these each complemented both whole chromosome substitutions, implying a non-additive (epistatic) contribution to the "disease" phenotype. Low coverage whole genome sequencing was also used to attempt to map chromosomal regions contributing to both the cardiomyopathy and arrhythmia, but a polygenic architecture had to be again inferred to be most likely. These results show that an apparently simple rare phenotype can have a complex genetic basis that would be refractory to mapping by deep sequencing in pedigrees. We present this as a cautionary tale regarding assumptions related to attempts to map new disease mutations on the assumption that probands carry a single causal mutation.

Published

2013

46. Huntington's disease induced cardiac amyloidosis is reversed by modulating protein folding and oxidative stress pathways in the Drosophila heart.

Author

Girish C Melkani, Adriana S Trujillo, Raul Ramos, Rolf Bodmer, Sanford I Bernstein, and Karen Ocorr

Subjects

Genetics, QH426-470

Abstract

Amyloid-like inclusions have been associated with Huntington's disease (HD), which is caused by expanded polyglutamine repeats in the Huntingtin protein. HD patients exhibit a high incidence of cardiovascular events, presumably as a result of accumulation of toxic amyloid-like inclusions. We have generated a Drosophila model of cardiac amyloidosis that exhibits accumulation of PolyQ aggregates and oxidative stress in myocardial cells, upon heart-specific expression of Huntingtin protein fragments (Htt-PolyQ) with disease-causing poly-glutamine repeats (PolyQ-46, PolyQ-72, and PolyQ-102). Cardiac expression of GFP-tagged Htt-PolyQs resulted in PolyQ length-dependent functional defects that included increased incidence of arrhythmias and extreme cardiac dilation, accompanied by a significant decrease in contractility. Structural and ultrastructural analysis of the myocardial cells revealed reduced myofibrillar content, myofibrillar disorganization, mitochondrial defects and the presence of PolyQ-GFP positive aggregates. Cardiac-specific expression of disease causing Poly-Q also shortens lifespan of flies dramatically. To further confirm the involvement of oxidative stress or protein unfolding and to understand the mechanism of PolyQ induced cardiomyopathy, we co-expressed expanded PolyQ-72 with the antioxidant superoxide dismutase (SOD) or the myosin chaperone UNC-45. Co-expression of SOD suppressed PolyQ-72 induced mitochondrial defects and partially suppressed aggregation as well as myofibrillar disorganization. However, co-expression of UNC-45 dramatically suppressed PolyQ-72 induced aggregation and partially suppressed myofibrillar disorganization. Moreover, co-expression of both UNC-45 and SOD more efficiently suppressed GFP-positive aggregates, myofibrillar disorganization and physiological cardiac defects induced by PolyQ-72 than did either treatment alone. Our results demonstrate that mutant-PolyQ induces aggregates, disrupts the sarcomeric organization of contractile proteins, leads to mitochondrial dysfunction and increases oxidative stress in cardiomyocytes leading to abnormal cardiac function. We conclude that modulation of both protein unfolding and oxidative stress pathways in the Drosophila heart model can ameliorate the detrimental PolyQ effects, thus providing unique insights into the genetic mechanisms underlying amyloid-induced cardiac failure in HD patients.

Published

2013

47. A Drosophila model of high sugar diet-induced cardiomyopathy.

Author

Jianbo Na, Laura Palanker Musselman, Jay Pendse, Thomas J Baranski, Rolf Bodmer, Karen Ocorr, and Ross Cagan

Subjects

Genetics, QH426-470

Abstract

Diets high in carbohydrates have long been linked to progressive heart dysfunction, yet the mechanisms by which chronic high sugar leads to heart failure remain poorly understood. Here we combine diet, genetics, and physiology to establish an adult Drosophila melanogaster model of chronic high sugar-induced heart disease. We demonstrate deterioration of heart function accompanied by fibrosis-like collagen accumulation, insulin signaling defects, and fat accumulation. The result was a shorter life span that was more severe in the presence of reduced insulin and P38 signaling. We provide evidence of a role for hexosamine flux, a metabolic pathway accessed by glucose. Increased hexosamine flux led to heart function defects and structural damage; conversely, cardiac-specific reduction of pathway activity prevented sugar-induced heart dysfunction. Our data establish Drosophila as a useful system for exploring specific aspects of diet-induced heart dysfunction and emphasize enzymes within the hexosamine biosynthetic pathway as candidate therapeutic targets.

Published

2013

48. Patient-specific genomics and cross-species functional analysis implicate LRP2 in hypoplastic left heart syndrome

Author

Megan M. O’Byrne, Anaïs Kervadec, Almudena Martinez-Fernandez, Zeng Xi, Rolf Bodmer, Katja Birker, Timothy J. Nelson, Xing Li, Paul Grossfeld, Andre Terzic, Georg Vogler, Jeanne L. Theis, Stanley M. Walls, Karen Ocorr, Jared M. Evans, Alexandre R. Colas, James N. Kezos, Zachary C. Fogarty, Timothy M. Olson, Tanja Nielsen, and Maria A. Missinato

Subjects

Male, 0301 basic medicine, Proband, Candidate gene, QH301-705.5, Science, Genomics, Bioinformatics, General Biochemistry, Genetics and Molecular Biology, Hypoplastic left heart syndrome, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Humans, Biology (General), Zebrafish, Gene knockdown, iPSC, D. melanogaster, General Immunology and Microbiology, biology, Heart development, General Neuroscience, cardiogenesis, Heart, Genetics and Genomics, hypoplastic left heart syndrome, General Medicine, medicine.disease, biology.organism_classification, LRP2, congenital heart disease, Tools and Resources, lipoproteins, Low Density Lipoprotein Receptor-Related Protein-2, Drosophila melanogaster, 030104 developmental biology, Medicine, Female, 030217 neurology & neurosurgery, Human

Abstract

Congenital heart diseases (CHDs), including hypoplastic left heart syndrome (HLHS), are genetically complex and poorly understood. Here, a multidisciplinary platform was established to functionally evaluate novel CHD gene candidates, based on whole-genome and iPSC RNA sequencing of a HLHS family-trio. Filtering for rare variants and altered expression in proband iPSCs prioritized 10 candidates. siRNA/RNAi-mediated knockdown in healthy human iPSC-derived cardiomyocytes (hiPSC-CM) and in developingDrosophilaand zebrafish hearts revealed that LDL receptor-related proteinLRP2is required for cardiomyocyte proliferation and differentiation. Consistent with hypoplastic heart defects, compared to parents the proband’s iPSC-CMs exhibited reduced proliferation. Interestingly, rare, predicted-damaging LRP2 variants were enriched in a HLHS cohort; however, understanding their contribution to HLHS requires further investigation. Collectively, we have established a multi-species high-throughput platform to rapidly evaluate candidate genes and their interactions during heart development, which are crucial first steps toward deciphering oligogenic underpinnings of CHDs, including hypoplastic left hearts.

Published

2020

49. Author response: Patient-specific genomics and cross-species functional analysis implicate LRP2 in hypoplastic left heart syndrome

Author

Paul Grossfeld, Maria A. Missinato, Megan M. O’Byrne, Almudena Martinez-Fernandez, Katja Birker, Jared M. Evans, James N. Kezos, Anaïs Kervadec, Rolf Bodmer, Georg Vogler, Timothy J. Nelson, Jeanne L. Theis, Zeng Xi, Zachary C. Fogarty, Timothy M. Olson, Karen Ocorr, Tanja Nielsen, Alexandre R. Colas, Andre Terzic, Xing Li, and Stanley M. Walls

Subjects

medicine.medical_specialty, business.industry, Internal medicine, medicine, Cardiology, Genomics, Patient specific, medicine.disease, LRP2, business, Functional analysis (psychology), Hypoplastic left heart syndrome

Published

2020

50. Identification ofMYOM2as a candidate gene in hypertrophic cardiomyopathy and Tetralogy of Fallot and its functional evaluation in theDrosophilaheart

Author

Marcel Grunert, Georg Vogler, Christian Mühlfeld, Tanja Nielsen, Andreas Perrot, Rolf Bodmer, Emilie Auxerre-Plantié, Cemil Özcelik, Faramarz Matinmehr, Cristobal G. dos Remedios, Theresia Kraft, Dennis Harries, Olga Olejniczak, and Silke Sperling

Subjects

Myomesin, Genetics, Candidate gene, biology, Heart malformation, Myosin binding, biology.protein, medicine, Hypertrophic cardiomyopathy, MYH6, MYOM2, medicine.disease, Tetralogy of Fallot

Abstract

The causal genetic underpinnings of congenital heart diseases, which are often complex and with multigenic background, are still far from understood. Moreover, there are also predominantly monogenic heart defects, such as cardiomyopathies, with known disease genes for the majority of cases. In this study, we identified mutations in myomesin 2 (MYOM2) in patients with Tetralogy of Fallot (TOF), the most common cyanotic heart malformation, as well as in patients with hypertrophic cardiomyopathy (HCM), who do not exhibit any mutations in the known disease genes. MYOM2 is a major component of the myofibrillar M-band of the sarcomere and a hub gene within interactions of sarcomere genes. We show that patient-derived cardiomyocytes exhibit myofibrillar disarray and reduced passive force with increasing sarcomere lengths. Moreover, our comprehensive functional analyses in theDrosophilaanimal model reveal that the so far uncharacterized fly geneCG14964may be an ortholog ofMYOM2, as well as other myosin binding proteins (henceforth named asDrosophilaMyomesin andMyosin Binding protein (dMnM)). Its partial loss-of-function or moderate cardiac knockdown results in cardiac dilation, whereas more severely reduced function causes a constricted phenotype and an increase in sarcomere myosin protein. Moreover, compound heterozygous combinations ofCG14964and the sarcomere geneMhc(MYH6/7) exhibited synergistic genetic interactions. In summary, our results suggest thatMYOM2not only plays a critical role in maintaining robust heart function but may also be a candidate gene for heart diseases such as HCM and TOF, as it is clearly involved in the development of the heart.SUMMARY STATEMENTMYOM2plays a critical role in establishing or maintaining robust heart function and is a candidate gene for heart diseases such as hypertrophic cardiomyopathy and Tetralogy of Fallot.

Published

2020