Your search keyword '"Scholman KT"' showing total 8 results

1. From Genome-Wide Association Studies to Cardiac Electrophysiology: Through the Maze of Biological Complexity

Author

Scholman, KT, Meijborg, VMF, Galvez-Monton, C, Lodder, EM, and Boukens, BJ

Subjects

gene expression, GWAS, genetics, cardiac electrophysiology, arrhythmias

Abstract

Genome Wide Association Studies (GWAS) have provided an enormous amount of data on genomic loci associated with cardiac electrophysiology and arrhythmias. Clinical relevance, however, remains unclear since GWAS do not provide a mechanistic explanation for this association. Determining the electrophysiological relevance of variants for arrhythmias would aid development of risk stratification models for patients with arrhythmias. In this review, we give an overview of genetic variants related to ECG intervals and arrhythmogenic pathologies and discuss how these variants may influence cardiac electrophysiology and the occurrence of arrhythmias.

Published

2020

2. Patient-Specific TBX5-G125R Variant Induces Profound Transcriptional Deregulation and Atrial Dysfunction.

Author

van Ouwerkerk AF, Bosada FM, van Duijvenboden K, Houweling AC, Scholman KT, Wakker V, Allaart CP, Uhm JS, Mathijssen IB, Baartscheer T, Postma AV, Barnett P, Verkerk AO, Boukens BJ, and Christoffels VM

Subjects

Amino Acid Substitution, Animals, Atrial Fibrillation genetics, Atrial Fibrillation metabolism, Female, Heart Atria metabolism, Humans, Male, Mice, Mice, Mutant Strains, Abnormalities, Multiple genetics, Abnormalities, Multiple metabolism, Gene Expression Regulation, Heart Defects, Congenital genetics, Heart Defects, Congenital metabolism, Heart Septal Defects, Atrial genetics, Heart Septal Defects, Atrial metabolism, Heterozygote, Lower Extremity Deformities, Congenital genetics, Lower Extremity Deformities, Congenital metabolism, Mutation, Missense, Pedigree, T-Box Domain Proteins genetics, T-Box Domain Proteins metabolism, Upper Extremity Deformities, Congenital genetics, Upper Extremity Deformities, Congenital metabolism

Abstract

Background: The pathogenic missense variant p.G125R in TBX5 (T-box transcription factor 5) causes Holt-Oram syndrome (also known as hand-heart syndrome) and early onset of atrial fibrillation. Revealing how an altered key developmental transcription factor modulates cardiac physiology in vivo will provide unique insights into the mechanisms underlying atrial fibrillation in these patients., Methods: We analyzed ECGs of an extended family pedigree of Holt-Oram syndrome patients. Next, we introduced the TBX5-p.G125R variant in the mouse genome ( Tbx5 G125R ) and performed electrophysiologic analyses (ECG, optical mapping, patch clamp, intracellular calcium measurements), transcriptomics (single-nuclei and tissue RNA sequencing), and epigenetic profiling (assay for transposase-accessible chromatin using sequencing, H3K27ac [histone H3 lysine 27 acetylation] CUT&RUN [cleavage under targets and release under nuclease sequencing])., Results: We discovered high incidence of atrial extra systoles and atrioventricular conduction disturbances in Holt-Oram syndrome patients. Tbx5 G125R/+ mice were morphologically unaffected and displayed variable RR intervals, atrial extra systoles, and susceptibility to atrial fibrillation, reminiscent of TBX5-p.G125R patients. Atrial conduction velocity was not affected but systolic and diastolic intracellular calcium concentrations were decreased and action potentials were prolonged in isolated cardiomyocytes of Tbx5 G125R/+ mice compared with controls. Transcriptional profiling of atria revealed the most profound transcriptional changes in cardiomyocytes versus other cell types, and identified over a thousand coding and noncoding transcripts that were differentially expressed. Epigenetic profiling uncovered thousands of TBX5-p.G125R-sensitive, putative regulatory elements (including enhancers) that gained accessibility in atrial cardiomyocytes. The majority of sites with increased accessibility were occupied by Tbx5. The small group of sites with reduced accessibility was enriched for DNA-binding motifs of members of the SP (specificity protein) and KLF (Krüppel-like factor) families of transcription factors. These data show that Tbx5-p.G125R induces changes in regulatory element activity, alters transcriptional regulation, and changes cardiomyocyte behavior, possibly caused by altered DNA binding and cooperativity properties., Conclusions: Our data reveal that a disease-causing missense variant in TBX5 induces profound changes in the atrial transcriptional regulatory network and epigenetic state in vivo, leading to arrhythmia reminiscent of those seen in human TBX5-p.G125R variant carriers.

Published

2022

3. Variant Intronic Enhancer Controls SCN10A-short Expression and Heart Conduction.

Author

Man JCK, Bosada FM, Scholman KT, Offerhaus JA, Walsh R, van Duijvenboden K, van Eif VWW, Bezzina CR, Verkerk AO, Boukens BJ, Barnett P, and Christoffels VM

Subjects

Action Potentials genetics, Animals, Biomarkers, Cardiac Conduction System Disease diagnosis, Cardiac Conduction System Disease genetics, Cardiac Conduction System Disease physiopathology, Cardiac Electrophysiology, Disease Susceptibility, Electrocardiography, Female, Genetic Association Studies, Male, Mice, NAV1.5 Voltage-Gated Sodium Channel genetics, Quantitative Trait Loci, Quantitative Trait, Heritable, Enhancer Elements, Genetic, Gene Expression Regulation, Heart Conduction System physiology, Introns, NAV1.8 Voltage-Gated Sodium Channel genetics

Abstract

Background: Genetic variants in SCN10A , encoding the neuronal voltage-gated sodium channel Na V 1.8, are strongly associated with atrial fibrillation, Brugada syndrome, cardiac conduction velocities, and heart rate. The cardiac function of SCN10A has not been resolved, however, and diverging mechanisms have been proposed. Here, we investigated the cardiac expression of SCN10A and the function of a variant-sensitive intronic enhancer previously linked to the regulation of SCN5A , encoding the major essential cardiac sodium channel Na V 1.5., Methods: The expression of SCN10A was investigated in mouse and human hearts. With the use of CRISPR/Cas9 genome editing, the mouse intronic enhancer was disrupted, and mutant mice were characterized by transcriptomic and electrophysiological analyses. The association of genetic variants at SCN5A-SCN10A enhancer regions and gene expression were evaluated by genome-wide association studies single-nucleotide polymorphism mapping and expression quantitative trait loci analysis., Results: We found that cardiomyocytes of the atria, sinoatrial node, and ventricular conduction system express a short transcript comprising the last 7 exons of the gene ( Scn10a-short ). Transcription occurs from an intronic enhancer-promoter complex, whereas full-length Scn10a transcript was undetectable in the human and mouse heart. Expression quantitative trait loci analysis revealed that the genetic variants in linkage disequilibrium with genetic variant rs6801957 in the intronic enhancer associate with SCN10A transcript levels in the heart. Genetic modification of the enhancer in the mouse genome led to reduced cardiac Scn10a-short expression in atria and ventricles, reduced cardiac sodium current in atrial cardiomyocytes, atrial conduction slowing and arrhythmia, whereas the expression of Scn5a , the presumed enhancer target gene, remained unaffected. In patch-clamp transfection experiments, expression of Scn10a-short -encoded Na V 1.8-short increased Na V 1.5-mediated sodium current. We propose that noncoding genetic variation modulates transcriptional regulation of Scn10a-short in cardiomyocytes that impacts Na V 1.5-mediated sodium current and heart rhythm., Conclusions: Genetic variants in and around SCN10A modulate enhancer function and expression of a cardiac-specific SCN10A-short transcript. We propose that noncoding genetic variation modulates transcriptional regulation of a functional C-terminal portion of Na V 1.8 in cardiomyocytes that impacts on Na V 1.5 function, cardiac conduction velocities, and arrhythmia susceptibility.

Published

2021

4. From Genome-Wide Association Studies to Cardiac Electrophysiology: Through the Maze of Biological Complexity.

Author

Scholman KT, Meijborg VMF, Gálvez-Montón C, Lodder EM, and Boukens BJ

Abstract

Genome Wide Association Studies (GWAS) have provided an enormous amount of data on genomic loci associated with cardiac electrophysiology and arrhythmias. Clinical relevance, however, remains unclear since GWAS do not provide a mechanistic explanation for this association. Determining the electrophysiological relevance of variants for arrhythmias would aid development of risk stratification models for patients with arrhythmias. In this review, we give an overview of genetic variants related to ECG intervals and arrhythmogenic pathologies and discuss how these variants may influence cardiac electrophysiology and the occurrence of arrhythmias., (Copyright © 2020 Scholman, Meijborg, Gálvez-Montón, Lodder and Boukens.)

Published

2020

5. Identification of atrial fibrillation associated genes and functional non-coding variants.

Author

van Ouwerkerk AF, Bosada FM, van Duijvenboden K, Hill MC, Montefiori LE, Scholman KT, Liu J, de Vries AAF, Boukens BJ, Ellinor PT, Goumans MJTH, Efimov IR, Nobrega MA, Barnett P, Martin JF, and Christoffels VM

Subjects

Animals, Cell Line, Chromatin genetics, Epigenomics methods, Gene Expression Profiling methods, Genetic Variation, Heart Atria cytology, Heart Atria metabolism, Humans, Mice, Myocytes, Cardiac cytology, Myocytes, Cardiac metabolism, Atrial Fibrillation genetics, Genetic Predisposition to Disease genetics, Genome-Wide Association Study methods, Polymorphism, Single Nucleotide, Regulatory Sequences, Nucleic Acid genetics

Abstract

Disease-associated genetic variants that lie in non-coding regions found by genome-wide association studies are thought to alter the functionality of transcription regulatory elements and target gene expression. To uncover causal genetic variants, variant regulatory elements and their target genes, here we cross-reference human transcriptomic, epigenomic and chromatin conformation datasets. Of 104 genetic variant regions associated with atrial fibrillation candidate target genes are prioritized. We optimize EMERGE enhancer prediction and use accessible chromatin profiles of human atrial cardiomyocytes to more accurately predict cardiac regulatory elements and identify hundreds of sub-threshold variants that co-localize with regulatory elements. Removal of mouse homologues of atrial fibrillation-associated regions in vivo uncovers a distal regulatory region involved in Gja1 (Cx43) expression. Our analyses provide a shortlist of genes likely affected by atrial fibrillation-associated variants and provide variant regulatory elements in each region that link genetic variation and target gene regulation, helping to focus future investigations.

Published

2019

6. Neurokinin-3 receptor activation selectively prolongs atrial refractoriness by inhibition of a background K + channel.

Author

Veldkamp MW, Geuzebroek GSC, Baartscheer A, Verkerk AO, Schumacher CA, Suarez GG, Berger WR, Casini S, van Amersfoorth SCM, Scholman KT, Driessen AHG, Belterman CNW, van Ginneken ACG, de Groot JR, de Bakker JMT, Remme CA, Boukens BJ, and Coronel R

Subjects

Action Potentials, Animals, Arrhythmias, Cardiac, Atrial Fibrillation, Atrial Function, Humans, Potassium Channel Blockers, Rabbits, Receptors, Neurokinin-3 metabolism, Heart Atria metabolism, Potassium Channels metabolism, Receptors, Neurokinin-3 physiology

Abstract

The cardiac autonomic nervous system (ANS) controls normal atrial electrical function. The cardiac ANS produces various neuropeptides, among which the neurokinins, whose actions on atrial electrophysiology are largely unknown. We here demonstrate that the neurokinin substance-P (Sub-P) activates a neurokinin-3 receptor (NK-3R) in rabbit, prolonging action potential (AP) duration through inhibition of a background potassium current. In contrast, ventricular AP duration was unaffected by NK-3R activation. NK-3R stimulation lengthened atrial repolarization in intact rabbit hearts and consequently suppressed arrhythmia duration and occurrence in a rabbit isolated heart model of atrial fibrillation (AF). In human atrial appendages, the phenomenon of NK-3R mediated lengthening of atrial repolarization was also observed. Our findings thus uncover a pathway to selectively modulate atrial AP duration by activation of a hitherto unidentified neurokinin-3 receptor in the membrane of atrial myocytes. NK-3R stimulation may therefore represent an anti-arrhythmic concept to suppress re-entry-based atrial tachyarrhythmias, including AF.

Published

2018

7. Tomo-Seq Identifies SOX9 as a Key Regulator of Cardiac Fibrosis During Ischemic Injury.

Author

Lacraz GPA, Junker JP, Gladka MM, Molenaar B, Scholman KT, Vigil-Garcia M, Versteeg D, de Ruiter H, Vermunt MW, Creyghton MP, Huibers MMH, de Jonge N, van Oudenaarden A, and van Rooij E

Subjects

Collagen Type I biosynthesis, Collagen Type I genetics, Female, Fibrosis, High-Throughput Nucleotide Sequencing, Humans, Male, Muscle Proteins genetics, Myocardial Ischemia genetics, SOX9 Transcription Factor genetics, Gene Expression Regulation, Muscle Proteins biosynthesis, Myocardial Ischemia metabolism, Myocardium metabolism, SOX9 Transcription Factor biosynthesis

Abstract

Background: Cardiac ischemic injury induces a pathological remodeling response, which can ultimately lead to heart failure. Detailed mechanistic insights into molecular signaling pathways relevant for different aspects of cardiac remodeling will support the identification of novel therapeutic targets., Methods: Although genome-wide transcriptome analysis on diseased tissues has greatly advanced our understanding of the regulatory networks that drive pathological changes in the heart, this approach has been disadvantaged by the fact that the signals are derived from tissue homogenates. Here we used tomo-seq to obtain a genome-wide gene expression signature with high spatial resolution spanning from the infarcted area to the remote to identify new regulators of cardiac remodeling. Cardiac tissue samples from patients suffering from ischemic heart disease were used to validate our findings., Results: Tracing transcriptional differences with a high spatial resolution across the infarcted heart enabled us to identify gene clusters that share a comparable expression profile. The spatial distribution patterns indicated a separation of expressional changes for genes involved in specific aspects of cardiac remodeling, such as fibrosis, cardiomyocyte hypertrophy, and calcium handling ( Col1a2 , Nppa , and Serca2 ). Subsequent correlation analysis allowed for the identification of novel factors that share a comparable transcriptional regulation pattern across the infarcted tissue. The strong correlation between the expression levels of these known marker genes and the expression of the coregulated genes could be confirmed in human ischemic cardiac tissue samples. Follow-up analysis identified SOX9 as common transcriptional regulator of a large portion of the fibrosis-related genes that become activated under conditions of ischemic injury. Lineage-tracing experiments indicated that the majority of COL1-positive fibroblasts stem from a pool of SOX9-expressing cells, and in vivo loss of Sox9 blunted the cardiac fibrotic response on ischemic injury. The colocalization between SOX9 and COL1 could also be confirmed in patients suffering from ischemic heart disease., Conclusions: Based on the exact local expression cues, tomo-seq can serve to reveal novel genes and key transcription factors involved in specific aspects of cardiac remodeling. Using tomo-seq, we were able to unveil the unknown relevance of SOX9 as a key regulator of cardiac fibrosis, pointing to SOX9 as a potential therapeutic target for cardiac fibrosis., (© 2017 American Heart Association, Inc.)

Published

2017

8. Genome-wide analysis reveals NRP1 as a direct HIF1α-E2F7 target in the regulation of motorneuron guidance in vivo.

Author

de Bruin A, A Cornelissen PW, Kirchmaier BC, Mokry M, Iich E, Nirmala E, Liang KH, D Végh AM, Scholman KT, Groot Koerkamp MJ, Holstege FC, Cuppen E, Schulte-Merker S, and Bakker WJ

Subjects

Animals, Binding Sites, Cell Hypoxia genetics, Cell Line, Tumor, E2F7 Transcription Factor metabolism, Genome-Wide Association Study, HeLa Cells, Humans, Hypoxia-Inducible Factor 1, alpha Subunit metabolism, In Situ Hybridization, Morpholinos genetics, Neuropilin-1 metabolism, RNA Interference, RNA, Small Interfering genetics, Transcription, Genetic genetics, Zebrafish embryology, Axon Guidance genetics, E2F7 Transcription Factor genetics, Hypoxia-Inducible Factor 1, alpha Subunit genetics, Motor Neurons metabolism, Neuropilin-1 genetics, Zebrafish genetics

Abstract

In this study, we explored the existence of a transcriptional network co-regulated by E2F7 and HIF1α, as we show that expression of E2F7, like HIF1α, is induced in hypoxia, and because of the previously reported ability of E2F7 to interact with HIF1α. Our genome-wide analysis uncovers a transcriptional network that is directly controlled by HIF1α and E2F7, and demonstrates both stimulatory and repressive functions of the HIF1α -E2F7 complex. Among this network we reveal Neuropilin 1 (NRP1) as a HIF1α-E2F7 repressed gene. By performing in vitro and in vivo reporter assays we demonstrate that the HIF1α-E2F7 mediated NRP1 repression depends on a 41 base pairs 'E2F-binding site hub', providing a molecular mechanism for a previously unanticipated role for HIF1α in transcriptional repression. To explore the biological significance of this regulation we performed in situ hybridizations and observed enhanced nrp1a expression in spinal motorneurons (MN) of zebrafish embryos, upon morpholino-inhibition of e2f7/8 or hif1α Consistent with the chemo-repellent role of nrp1a, morpholino-inhibition of e2f7/8 or hif1α caused MN truncations, which was rescued in TALEN-induced nrp1a(hu10012) mutants, and phenocopied in e2f7/8 mutant zebrafish. Therefore, we conclude that repression of NRP1 by the HIF1α-E2F7 complex regulates MN axon guidance in vivo., (© The Author(s) 2015. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2016