An Undergraduate Course in CRISPR/Cas9-Mediated Gene Editing in Zebrafish.

We have developed a one-credit semester-long research experience for undergraduate students that involves the use of CRISPR/Cas9 to edit genes in zebrafish. The course is available to students at all stages of their undergraduate training and can be taken up to four times. Students select a gene of interest to edit as the basis of their semester-long project. To select a gene, exploration of developmental processes and human disease is encouraged. As part of the course, students use basic bioinformatic tools, design guide RNAs, inject zebrafish embryos, and analyze both the molecular consequences of gene editing and phenotypic outcomes. Over the 10 years we have offered the course, enrollment has grown from less than 10 students to more than 60 students per semester. Each year, we choose a different gene editing strategy to explore based on recent publications of gene editing methodologies. These have included making CRISPants, targeted integrations, and large gene deletions. In this study, we present how we structure the course and our assessment of the course over the past 3 years.

Tagging the tjp1a Gene in Zebrafish with Monomeric Red Fluorescent Protein Using Biotin Homology Arms.

Tjp1a and other tight junction and adherens proteins play important roles in cell-cell adhesion, scaffolding, and forming seals between cells in epithelial and endothelial tissues. In this study, we labeled Tjp1a of zebrafish with the monomeric red fluorescent protein (mRFP) using CRISPR/Cas9-mediated targeted integration of biotin-labeled polymerase chain reaction (PCR) generated templates. Labeling Tjp1a with RFP allowed us to follow membrane and junctional dynamics of epithelial and endothelial cells throughout zebrafish embryo development. For targeted integration, we used short 35 bp homology arms on each side of the Cas9 genomic target site at the C-terminal of the coding sequence in tjp1a. Through PCR using 5' biotinylated primers containing the homology arms, we generated a double-stranded template for homology directed repair containing a flexible linker followed by RFP. Cas9 protein was complexed with the tjp1a gRNA before mixing with the repair template and microinjected into one-cell zebrafish embryos. We confirmed and recovered a precise integration allele at the desired site at the tjp1a C-terminus. Examination of fluorescence reveals RFP cell-cell junctional labeling using confocal imaging. We are currently using this stable tjp1a-mRFPis86 line to examine the behavior and interactions between cells during vascular formation in zebrafish.