Congenital heart defects have been linked to numerous genes, but many of the genes responsible are not yet identified. The purpose of this research is to identify the unknown genetic causes of human congenital heart defects, utilizing zebrafish as a model organism. Using CRISPR-Cas9 to edit the genome of zebrafish, we are creating mutations in genes we predict are involved in human congenital heart defects. Our lab has used a CRISPR-based screen in zebrafish to identify new genes that, when knocked out, lead to defective heart development in zebrafish embryos. For this research project, our questions are: Can we associate specific, CRISPR-induced genetic mutations in these genes with our heart-defective zebrafish embryos? And, can we genetically engineer heritable mutations in these respective genes in zebrafish? The methods used in this project involve using several sets of DNA oligonucleotide primers to assess where and how the CRISPR reagents have altered the screened candidate genes. We have analyzed three genes—grpel1, pomp, and psmd6—each with four CRISPR target sites. The primer testing and animal genotyping have been done using PCR, gel electrophoresis, and gel imaging, with genotyping also requiring restriction digests. Our results have been promising. First, we determined which CRISPR target sites are effective for each gene. Second, we successfully identified CRISPR-induced mutations in F0-generation animals for each of these three genes. Third, for the pomp gene, we identified germline-transmission of a specific CRISPR mutation corresponding with heart-defective embryos. This result identifies pomp as a new candidate gene for heart defects. A key implication of these findings is that we can successfully create lineages of zebrafish carrying mutations in these new heart defect genes. Our work will allow for further testing and a better understanding of the genetics behind heart development.