Nuclear envelope spectrin‐repeat proteins (Nesprins) are part of the LINC (LInker of Nucleoskeleton and Cytoskeleton) complex, which plays a vital role in the binding of F‐actin cytoskeleton to the nuclear envelope. Nesprins are crucial in maintaining the integrity of the nuclear membrane. Nuclear membrane movement is a fundamental aspect in cell migration and muscle development. Previous work has demonstrated that Nesprins may be associated with myosin‐dependent tension, which has implications in muscular dystrophy due to the role that nesprins play in muscle cells. We hypothesize that expressing dominant‐negative nesprin in Danio rerio (zebrafish) embryos would result in defects in the migration of facial branchiomotor neurons and also cause disruptions in nuclear positioning in multinucleated muscle cells. To test this hypothesis, we use transient transgenic expression of dominant Nesprin in cranial motor neurons using the islet1 promoter. We quantify the extent of migration in neurons with inactive Nesprin. In addition, we express dominant‐negative Nesprin in muscle cells using a heat shock promoter and explore the positioning of nuclei in developing skeletal muscle myofibrils. Our preliminary data shows that transgenic zebrafish embryos with expression of dominant‐negative nesprin have disruptions and defects in tangential FBMN migration. However, with further experimentation and data collection in progress, we hope to analyze our findings for statistical significance. Our goal is to gain insight into the function of Nesprins in embryo development to better devise therapeutic strategies for patients with mutations in Nesprins.This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.