Epstein-Barr virus, which is a world-spread virus, infects over 90% of mankind and is highly associated with several malignancies. As the only protein kinase encoded by EBV, BGLF4, phosphorylates several viral and cellular proteins to optimize the cellular environment for viral replication and nuclear egress of viral nucleocapsid. Previous findings demonstrated that EBV protein kinase, BGLF4, which expressed in EBV early lytic replication, can help the translocation of viral primase-helicase complex from the cytoplasm into nucleus, but the detailed mechanisms remained unknown. Recent studies revealed that a cellular heat shock protein 40 family member (Hsp40s), DNAJB6, is involved in diverse cellular functions including proteins transport and also implicated in numerous pathologies and infectious virus diseases. In this study, we showed that cytoplasmic EBV BSLF1 (primase) could translocate into the nucleus in the presence of DNAJB6a while BBLF2/3 (primase-associated factor) and BBLF4 (helicase) retained in cytoplasm by immuno-fluorescence assay. BSLF1 and BGLF4 was co-immunoprecipitated by DNAJB6a and DNAJB6b, suggesting that DNAJB6a may promote the translocation of EBV primase through direct interaction. Notably, we found that DNAJB6a and DNAJB6b showed different effects on EBV replication. When DNAJB6a was knockdown in EBV positive NA and Akata B cells, it decreased viral DNA replication and virion secretion; while knocking-down DNAJB6b, it increased both viral replication rate and secretion in Akata B cells. The results may emphasize the ratio of DNAJB6 isoforms in affecting viral replication. Moreover, we found that BGLF4 changed the distribution of DNAJB6b from cytoplasm to nucleus. Taken together, we suggested that DNAJB6 and the kinase activity of BGLF4 are required for the nuclear import of BSLF1 and DNAJB6 isoforms affect the viral DNA replication and virion secretion in NA and B cells.