Abstract 12973: Ulk1 Inhibition Ameliorates Ttntv Cardiomyopathy in Adult Zebrafish via Repairing Dysregulated Autophagy and Cellular Senescence

Background: TITIN truncational variants (TTNtv) is the predominant genetic factor for dilated cardiomyopathy (DCM). Therapeutic development for TTNtv DCM has been confounded by allelic heterogeneity (AH), i.e. while truncations in the C-terminal A-domain (TTNtv-As) are pathogenic, truncations in the N-terminal Z-disc domain (TTNtv-Zs) are largely benign. Molecular mechanisms underlying AH remain elusive, partially because of the lack of an in vivo animal model. Objective: We enquire whether zebrafish is a faithful vertebrate model for deciphering AH in TTNtv DCM and for therapeutic development. Methods and Results: Through comparing phenotypes among a series of ttntv -As and ttntv -Zs in adult zebrafish, we detected DCM-like phenotypes only in ttntv -As but not ttntv -Zs. Similar to human TTNtv DCM and corresponding rodent models, zebrafish ttntv -As manifest decreased ejection fraction, enlarged heart size, myofibril dys-organization, compromised exercise capacity, and dysregulated autophagy. Moreover, we noted exaggerated cardiac senescence at the later stage of the pathogenesis of ttntv DCM. Because AH in autophagy dysregulation was also detected in homozygous ttntv-A zebrafish embryos, we screened autophagy genes and identified ulk1 inhibition that is able to repair the dysregulated autophagy. A similar repairing effect of ulk1 inhibition on dysregulated autophagy was noted in an adult heterozygous ttntv-A model, which is sufficient to attenuate the cardiac senescence and improve cardiac function. Conclusion: Our data suggested adult zebrafish as the first vertebrate model that is able to recapitulate AH in TTNtv DCM patients. Conserved phenotypes including autophagy dysregulation are recapitulated in this lower vertebrate model, while cardiac senescence has been suggested as a novel pathological event. Genetic studies in this animal strongly suggest that repairing autophagy dysregulation is a therapeutic avenue for TTNtv DCM, and identified ulk1 as a candidate therapeutic target gene.