Identification of putative targets of Nkx2-5 in Xenopus laevis using cross-species annotation and microarray gene expression analysis

Breese, Marcus R.

29 February 2012

Indiana University-Purdue University Indianapolis (IUPUI) / The heart is the first organ to form during development in vertebrates and Nkx2-5 is the first marker of cardiac specification. In Xenopus laevis, Nkx2-5 is essential for heart formation, but early targets of this homeodomain transcription factor have not been fully characterized. In order to discover potential early targets of Nkx2-5, synthetic Nkx2-5 mRNA was injected into eight-cell Xenopus laevis embryos and changes in gene expression measured using microarray analysis. While Xenopus laevis is a commonly used model organism for developmental studies, its genome remains poorly annotated. To compensate for this, a cross-species annotation database called CrossGene was constructed. CrossGene was created by exhaustively comparing UniGene transcripts from Homo sapiens, Mus musculus, Rattus norvegicus, Gallus gallus, Xenopus laevis, Danio rerio, Drosophila melanogaster, and Caenorhabditis elegans using the BLAST family of algorithms. Networks were then assembled by recursively combining reciprocal best matches into groups of orthologous genes. Gene ontology annotation from all organisms could then be applied to all members of the reciprocal group. In this way, the CrossGene database was used to augment the existing genomic annotation of Xenopus laevis. Combining cross-species annotation with differential gene expression analysis of Nkx2-5 overexpression led to the discovery of 99 potential targets of Nkx2-5.

Nkx2-5

Cardiogenesis

Gene homology

Bioinformatics

Microarray analysis

Molecular Biology

Development

Heart -- Development

Genetic markers

Bioinformatics

The role of Pod1/Tcf21 in epicardium-derived cells in cardiac development and disease

Braitsch, Caitlin M.

17 September 2013

No description available.

Developmental Biology

epicardium-derived cell

cardiac fibrosis

transcription factor

heart development

smooth muscle

Tcf21

Requirements for Nr2f transcription factors in the maintenance of atrial myocardial identity in vertebrates

Martin, Kendall

02 June 2023

No description available.

Developmental Biology

sinoatrial node

zebrafish

heart development

nr2f1a

nkx2-5

isl1

Imaging the Embryonic Heart with Optical Coherence Tomography

Jenkins, Michael W.

04 April 2008

No description available.

Biomedical Research

optical coherence tomography

embryonic heart

gated imaging

heart development

FUNCTIONAL CHARACTERIZATION OF THE HOLT-ORAM SYNDROME ASSOCIATED TRANSCRIPTION FACTOR Tbx5 DURING EMBRYONIC HEART DEVELOPOMENT

PLAGEMAN, TIMOTHY F., JR.

13 July 2006

No description available.

Biology, Molecular

Tbx5

Holt Oram Syndrome

Transcription factor

Embryonic heart development

KLF2 IS REQUIRED FOR NORMAL MOUSE CARDIOVASCULAR DEVELOPMENT

Chiplunkar, Aditi Raghunath

22 January 2013

Krüppel-like factor 2 (KLF2) is expressed in endothelial cells in the developing heart, particularly in areas of high shear stress, such as the atrioventricular (AV) canal. KLF2 ablation leads to myocardial thinning, high output cardiac failure and death by mouse embryonic day 14.5 (E14.5) in a mixed genetic background. This work identifies an earlier and more fundamental role for KLF2 in mouse cardiac development in FVB/N mice. FVB/N KLF2-/- embryos die earlier, by E11.5. E9.5 FVB/N KLF2-/- hearts have multiple, disorganized cell layers lining the AV cushions, the primordia of the AV valves, rather than the normal single layer. By E10.5, traditional and endothelial-specific FVB/N KLF2-/- AV cushions are hypocellular, suggesting that the cells accumulating at the AV canal have a defect in endothelial to mesenchymal transformation (EMT). E10.5 FVB/N KLF2-/- hearts have reduced glycosaminoglycans in the cardiac jelly, correlating with the reduced EMT. However, the number of mesenchymal cells migrating from FVB/N KLF2-/- AV explants into a collagen matrix is reduced considerably compared to wild-type, suggesting that the EMT defect is not due solely to abnormal cardiac jelly. Echocardiography of E10.5 FVB/N KLF2-/- embryos indicates that they have abnormal heart function compared to wild-type. E10.5 C57BL/6 KLF2-/- hearts have largely normal AV cushions. However, E10.5 FVB/N and C57BL/6 KLF2-/- embryos have a delay in the formation of the atrial septum that is not observed in a defined mixed background. KLF2 ablation results in reduced Sox9, UDP-glucose dehydrogenase (UGDH), Gata4 and Tbx5 mRNA in FVB/N AV canals. KLF2 binds to the Gata4, Tbx5 and UGDH promoters in chromatin immunoprecipitation assays, indicating that KLF2 could directly regulate these genes. Thus KLF2 plays a role in EMT, through its regulation of important cardiovascular genes. E10.5 FVB/N KLF2-/- embryos show gaps in the endothelial lining at the dorsal aorta and a number of blood cells localized outside the aorta suggesting either hemorrhaging or inability of the hematopoietic progenitors to reach the aortic endothelium and enter circulation. This is not observed in KLF2-/- embryos in a mixed genetic background. In conclusion, KLF2-/- cardiovascular phenotypes are genetic background-dependent. KLF4 is another member of the Krüppel-like transcription factor family phylogenetically close to KLF2. It is known to play an important role in vascular regulation. Our studies show that in vascular development KLF4 plays a complementary role to KLF2, indicated by cranial hemorrhaging in E9.5 KLF2-/-KLF4-/- embryos in an undefined mixed background. This phenotype is absent in either of the single knockouts. The role of KLF2 and KLF4 in vascular development has not been studied as much as adult vascular regulation. This study begins to define the roles of these two transcription factors in development of blood vessels. Congenital heart and valve defects are a common cause of infant mortality. KLF2 has never been studied in this context. Thus this work is important for a better understanding of the biology of valve development.

KLF2

Heart development

Mouse embryo

EMT

AV cushion

KLF4

Vascular development

Medical Genetics

Medical Sciences

Medicine and Health Sciences

Bedeutung von Plakophilin 2 für die Bildung von Zellverbindungen zwischen Herzmuskelzellen und die Morphogenese des Herzens

Großmann, Katja Susann

05 January 2006

Plakophiline sind Proteine der Armadillo-Familie, die eine Funktion während der Embryonalentwicklung und im adulten Organismus aufweisen. Mutationen in Genen, die für diese Proteine kodieren, führen häufig zu Krankheiten. In dieser Arbeit wird der Phänotyp von Plakophilin 2-defizienten Mausembryonen untersucht, welche Probleme in der Morphogenese des Herzens und dessen Stabilität aufzeigen. Feine Risse in der Herzwand in den Tagen 10.5-11 der Embryogenese führen zu Blutfluss in die Perikardialhöhle und resultieren in embryonalem Tod. In Abwesenheit von Plakophilin 2 löst sich das Zytoskelett-bindende Protein Desmoplakin aus den Zellverbindungen der Kardiomyozyten und bildet Aggregate im Zytoplasma. Im Gegensatz dazu bleiben Zellverbindungen der Epithelien unverändert. Die molekulare Analyse des betroffenen Gewebes lässt eine essentielle Rolle für Plakophilin 2 in der Organisation der Zellverbindungen im Herz ableiten. Besonderen Wert bekamen diese Untersuchungen, als es gelang, die erarbeiteten Zusammenhänge mit einer Krankheit beim Menschen zu koppeln. Beachtlicherweise wurden bei mehr als 25% der an Arrhythmogener-Rechts-Ventikulärer-Kardiomyophathie (ARVC) erkrankten Menschen, Mutationen im Gen für Plakophilin 2 gefunden. / Plakophilins are proteins of the armadillo family that function in embryonic development and in the adult, and when mutated can cause disease. We have ablated the plakophilin 2 gene in mice. The resulting mutant mice exhibit lethal alterations in heart morphogenesis and stability at mid-gestation (E10.5–E11), characterized by reduced trabeculation, disarrayed cytoskeleton, ruptures of cardiac walls, and blood leakage into the pericardiac cavity. In the absence of plakophilin 2, the cytoskeletal linker protein desmoplakin dissociates from the plaques of the adhering junctions that connect the cardiomyocytes and forms granular aggregates in the cytoplasm. By contrast, embryonic epithelia show normal junctions. Thus, we conclude that plakophilin 2 is important for the assembly of junctional proteins and represents an essential morphogenic factor and architectural component of the heart. Interestingly we identified heterozygous mutations in the Plakophilin 2 gene in 32 out of 120 patients suffering from arrhythmogenic right ventricular cardiomyopathy (ARVC). ARVC is associated with fibrofatty replacement of cardiac myocytes, ventricular tachyarrhythmias and sudden cardiac death. Many of the identified mutations lead to an early STOP in protein translation and reduced expression of Plakophilin 2 protein likely due to RNA or protein degradation. Since loss of one functional allele of Plakophilin 2 leads to ARVC, we want to investigate the occurrence of typical ARVC-phenotypes in heterozygous Plakophilin 2 mice in future to provide a new insight into possible molecular mechanisms of ARVC.

Plakophilin 2

Adhäsion

Herzentwicklung

Kardiomyopathie

Plakophilin 2

adhesion

heart development

cardiomyopathy

570 Biowissenschaften, Biologie

32 Biologie

XG 6350

ddc:570

Gene Expression in Embryonic Chick Heart Development

Sneesby, Kyra, n/a

January 2003

Establishment of the biochemical and molecular nature of cardiac development is essential for us to understand the relationship between genetic and morphological aspects of heart formation. The molecular mechanisms that underly heart development are still not clearly defined. To address this issue we have used two approaches to identify genes involved in early chick cardiac development. Differential display previously conducted in our laboratory led to the identification of two gene fragments differentially expressed in the heart that are further described in this thesis. The full-length cDNA sequence of both eukaryotic translation initiation factor-2b (eIF-2b) and NADH cytochrome b5 reductase (b5R) were isolated using library screening. The upreglation of these genes during heart development is expected given the heart is the first functional organ to form in vertebrates and protein synthesis and cell metabolism at this stage of development is maximal. Limitations in the differential display approach led to the development and optimisation of a subtractive hybridisation approach for use with small amounts of cells or tissue. To focus on cardiac gene expression during the initial phases of heart development, subtractive hybridization was performed between the cardiogenic lateral plate mesoderm of Hamburger and Hamilton stage 4 embryos and the heart primordia of stage 9 embryos. Of the 87 independent clones identified by this procedure, 59 matched known sequences with high homology, 25 matched unknown expressed sequence tag (EST) sequences with high homology, and 3 did not match any known sequence on the database. Known genes isolated included those involved in transcription, translation, cell signalling, RNA processing, and energy production. Two of these genes, high mobility group phosphoprotein A2 (HMGA2) and C1-20C, an unknown gene, were chosen for further characterisation. The role of each gene in early chick heart development and indeed development in general, was addressed using techniques such as in situ hybridisation, transfection analysis, in ovo electroporation and RNAi. HMGA2 is a nuclear phosphoprotein commonly referred to as an architectural transcription factor due to its ability to modulate DNA conformation. In keeping with this function, HMGA2/GFP fusion protein was shown to localise to the nucleus and in particular, the nucleolus. In situ hybridisation analysis suggested a role for HMGA2 in heart and somite development. HMGA2 expression was first detected at HH stage 5 in the lateral plate mesoderm, a region synonymous with cells specified to the cardiac fate. HMGA2 was also strongly expressed in the presomitic segmental plate mesoderm and as somites developed from the segmental plate mesoderm, the expression of HMGA2 showed an increasingly more restricted domain corresponding to the level of maturation of the somite. Restriction of HMGA2 expression was first detected in the dorsal region of the epithelial somite, then the dorsomedial lip of the dermomyotome, and finally the migrating epaxial myotome cells. The novel intronless gene, C1-20C, predicts a protein of 148 amino acids containing a putative zinc finger binding domain and prenyl binding motif. Zinc binding assays showed that the zinc finger domain of C1-20C/MBP fusion protein bound over six times the quantity of zinc compared to MBP alone, although not in a 1:1 stoichiometric molar ratio. C1-20C/GFP fusion protein was shown to localise to as yet unidentified intracellular cytoplasmic vesicular compartments. These compartments did not colocalise with the endosome/lysosome pathway, aparently ruling out a role for C1-20C in protein trafficking, recycling or degradation. Expression of C1-20C in the chick embryo suggests a possible role in heart and notochord development and preliminary results using siRNA suggest that C1-20C is involved in normal heart looping.

heart

heart development

heart formation

gene expression

molecular genetics

chick heart

chick embryo

phosphoproteins

HMGA2

high mobility group phosphoprotein A2

Role Of Nitric Oxide In Embryonic Heart Development And Adult Aortic Valve Disease

Liu, Yin

22 May 2014

Congenital heart disease (CHD) is the most common birth defect in infants. Identifying factors that are critical to embryonic heart development or CHDs in general could further our understanding of the disease and may lead to new strategies of its prevention and treatment. Endothelial nitric oxide synthase (NOS3/eNOS) is known for many important biological functions including vasodilation, vascular homeostasis and angiogenesis. Previous studies have shown that deficiency in NOS3 results in congenital septal defects, cardiac hypertrophy and postnatal heart failure. In addition, NOS3 is pivotal to morphogenesis of aortic valve and myocardial capillary development. The aim of my thesis was to investigate the role of NOS3 in the embryonic and adult heart. I discovered that NOS3 deficiency resulted in coronary artery hypoplasia in fetal mice and spontaneous myocardial infarction in postnatal hearts. Coronary artery diameters, vessel density and volume were significantly decreased in NOS3-/- mice at postnatal day 0. Lack of NOS3 also down-regulated the expression of Gata4, Wilms tumor-1, vascular endothelial growth factor, basic fibroblast growth factor and erythropoietin in the embryonic heart at E12.5, and inhibited migration of epicardial cells into the myocardium. In addition, my data show that the overall size and length of mitral and tricuspid valves were decreased in NOS3-/- compared with WT mice. Echocardiographic assessment showed significant regurgitation of mitral and tricuspid valves during systole in NOS3-/- mice. Immunostaining of Snail1 was performed in the embryonic heart. Snail1 positive and total mesenchymal cells in the AV cushion were decreased in NOS3-/- compared with WT mice at E10.5 and E12.5. Finally, in the adult aortic valves, NOS3 is important in inhibition of thrombosis formation. Deficiency in NOS3 leads to aortic valve thrombosis and calcification. At 12 months old, 72% (13/18) of NOS3-/- mice showed severe spontaneous aortic valve thrombosis compared with WT mice (0/12). Ex vivo culture of aortic valves showed that platelet aggregation and adhesion were significantly increased in NOS3-/- aortic valves compared with WT aortic valves. There was also a significant regurgitation of the aortic valve during systole in the NOS3-/- compared with WT mice. In addition, NOS3 deficiency resulted in significant aortic valve stenosis, calcification and fibrosis. In summary, these data suggest NOS3 plays a critical role in embryonic heart development and morphogenesis of coronary arteries and inhibits thrombosis formation in the adult aortic valves.

NOS3

heart development

aortic valves

coronary artery

atrioventricular valves

thrombosis

Cellular and Molecular Physiology

Developmental Biology

Molecular genetics

Investigating Hemodynamics of the Developing Embryonic Heart using Optical Coherence Tomography

Peterson, Lindsy Marie

03 June 2015

No description available.

Biomedical Engineering

Developmental Biology

optical coherence tomography

doppler

hemodynamics

embryonic heart development

shear stress

absolute flow

aortic arch