Congenital heart disease (CHD) occurs in approximately 8 out of 1000 live births and effects 1.3 million newborns per year worldwide. While there is evidence to indicate that CHD does have a genetic basis, most of CHD burden remains unexplained genetically. New genomics technologies can efficiently identify variations in the genomes of CHD patients, but only a small percentage have second unrelated alleles to validate them as disease causing. Therefore there is a pressing need to develop functional assays to evaluate these candidate genes for CHD. There are two main goals for these functional assays: 1) provide evidence supporting candidate genes as disease causing and 2) identify the mechanism for the candidate gene on normal development and the disease state. Here we develop Xenopus as a rapid model system for testing CHD genes and apply advanced optical imaging methods to detect cardiac phenotypes. Xenopus is as an important animal model of congenital heart disease: large numbers of embryos can be readily manipulated, protein expression can be knocked-down using antisense morpholino oligos, and the heart is easily visualized. To expand the CHD spectrum that can be modeling in Xenopus, we need better microscale cardiac imaging methods. During the R21 phase, we will test two technologies, optic coherence tomography (OCT) and our novel hemoglobin contrast subtraction angiography (HCSA) to demonstrate that microscale imaging of Xenopus can be used to screen CHD genomic hits. Optic coherence tomography is an optical imaging system that can capture microscopic structures at high acquisition speeds allowing high-resolution phenotyping of dynamic heart structures. Hemoglobin contrast subtraction angiography (HCSA) is a noninvasive, nondestructive, quantitative microangiographic method that exploits the hemoglobin as an endogenous flow contrast agent during color imaging enabling us to delineate abnormal structures as well as quantify biomechanical phenotypes. In the R33 phase, our overall goal is to apply these methods to facilitate detailed high-resolution structural phenotypin of tadpole hearts that can be used to quickly test CHD candidate genes for cardiac phenotypes. This will allow us to identify cardiac phenotypes in CHD candidate genes that have no previous role in cardiac development and serve as a springboard for future mechanistic studies.

Public Health Relevance

Many infants are born with 'holes' in their heart which is known as congenital heart disease. New genome technologies allow us to investigate the genes that may cause congenital heart disease. In this proposal, we will apply new methods to image frog hearts as a way to test these genes to see if they do affect formation of the heart. (End of Abstract)

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Exploratory/Developmental Grants Phase II (R33)
Project #
5R33HL120783-05
Application #
9417059
Study Section
Special Emphasis Panel (ZHL1)
Program Officer
Schramm, Charlene A
Project Start
2014-03-10
Project End
2019-02-28
Budget Start
2018-03-01
Budget End
2019-02-28
Support Year
5
Fiscal Year
2018
Total Cost
Indirect Cost
Name
Yale University
Department
Pediatrics
Type
Schools of Medicine
DUNS #
043207562
City
New Haven
State
CT
Country
United States
Zip Code
Kulkarni, Saurabh S; Griffin, John N; Date, Priya P et al. (2018) WDR5 Stabilizes Actin Architecture to Promote Multiciliated Cell Formation. Dev Cell 46:595-610.e3
Garfinkel, Alexandra MacColl; Khokha, Mustafa K (2017) An interspecies heart-to-heart: Using Xenopus to uncover the genetic basis of congenital heart disease. Curr Pathobiol Rep 5:187-196
Pierce, Richard W; Merola, Jonathan; Lavik, John Paul et al. (2017) A p190BRhoGAP mutation and prolonged RhoB activation in fatal systemic capillary leak syndrome. J Exp Med 214:3497-3505
Deniz, Engin; Jonas, Stephan; Hooper, Michael et al. (2017) Analysis of Craniocardiac Malformations in Xenopus using Optical Coherence Tomography. Sci Rep 7:42506
Moreno-Mateos, Miguel A; Fernandez, Juan P; Rouet, Romain et al. (2017) CRISPR-Cpf1 mediates efficient homology-directed repair and temperature-controlled genome editing. Nat Commun 8:2024
Robson, Andrew; Owens, Nick D L; Baserga, Susan J et al. (2016) Expression of ribosomopathy genes during Xenopus tropicalis embryogenesis. BMC Dev Biol 16:38
Duncan, Anna R; Khokha, Mustafa K (2016) Xenopus as a model organism for birth defects-Congenital heart disease and heterotaxy. Semin Cell Dev Biol 51:73-9
Huang, Brendan K; Gamm, Ute A; Jonas, Stephan et al. (2015) Quantitative optical coherence tomography imaging of intermediate flow defect phenotypes in ciliary physiology and pathophysiology. J Biomed Opt 20:030502
Bhattacharya, Dipankan; Marfo, Chris A; Li, Davis et al. (2015) CRISPR/Cas9: An inexpensive, efficient loss of function tool to screen human disease genes in Xenopus. Dev Biol 408:196-204
Huang, Brendan K; Gamm, Ute A; Bhandari, Vineet et al. (2015) Three-dimensional, three-vector-component velocimetry of cilia-driven fluid flow using correlation-based approaches in optical coherence tomography. Biomed Opt Express 6:3515-38

Showing the most recent 10 out of 11 publications