As a germ-cell-specific maternal mRNA and RNA binding protein, dead end (dnd1) plays an important role in migration and maintenance of primordial germ cells (PGCs), and therefore, disruption of dnd1 results in no germ cells. However, the effect and duration of maternal dnd1 on PGCs in zygote mutants have not been reported yet. In the present study, CRISPR/Cas9 was used to mutate dnd1 in tilapia. Supported by the maternal dnd1 mRNA, germ cells of the dnd1 homozygous mutants proliferated and migrated normally before 7 dpf (days post fertilization). After the degradation of maternal dnd1 mRNA, significant downregulation of piwil1, piwil2, nanos2, nanos3 and vasa mRNA, and blocked migration of germ cells were observed at 14 dpf. In dnd1 zygote mutants, the number of germ cells was decreased significantly compared with wild type (WT) at 25 dpf, and no germ cell was observed at 30 dpf. Consistently, no expression of vasa and nanos3 was detected in the adult dnd1 mutants by qPCR. Interestingly, Cyp19a1a/cyp19a1a and foxl2 were expressed in dnd1-deficient XX gonads, while Cyp11c1/cyp11c1 and dmrt1 were expressed in dnd1-deficient XY gonads as in WT gonads. Correspondingly, both serum E2 level in XX and 11-KT level in XY fish did not differ significantly between dnd1 mutant and WT fish. Taken together, the present study demonstrates that disruption of dnd1 lead to progressive loss of germ cells, while the somatic cells are not affected in tilapia. The sexual fate of gonads is determined by the genetic sex instead of germ cell number, which makes tilapia a potential surrogate model for germ cell transplantation.