Generation and characterization of zebrafish f9l mutant confirmed that f9l is f10 like gene.

Aim: This study aimed to create an f9l mutant zebrafish using clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated protein 9 (Cas9) and characterize its coagulation properties to investigate its functional similarity to human FX and explore the potential synergy between f9l and f10 .

Methods: Three gRNAs targeting exon 8 encoded by the catalytic domain of the f9l gene were injected into 300 single-cell zebrafish embryos using CRISPR/Cas9 technology. DNA from the resulting adults was extracted from tail tips, and PCR was used to detect indels. The identified founder mutant was bred to homozygosity, and functional assays, kinetic Russel viper venom time, bleeding assay in adults, and venous laser injury on larvae were conducted to assess its hemostatic function. Additionally, f10 was knocked down in f9l homozygous embryos using f10 antisense morpholinos to study their interaction by monitoring its survival.

Results: DNA from 60 adults was screened for indels, resulting in a fish with a heritable complex mutation involving one insertion and two deletions in exon 8. The f9l homozygous mutants exhibited impaired F10 activity, mild bleeding after mechanical injury, and developmental deformities in early larval stages. The caudal vein thrombosis assay showed variable occlusion times, indicating a bleeding phenotype with incomplete penetrance. Knocking down f10 in f9l homozygous embryos resulted in 50% mortality within five dpf, compared to f9l homozygous embryos injected with control morpholinos.

Conclusion: In summary, we generated f9l knockout and showed it is a paralog to f10. We also found a synergy between f9l and f10 genes, highlighting its importance in hemostasis.