The protein VP2, matured from the polyprotein, which was encoded by the genome of infectious bursal disease virus (IBDV), is the primary host-protective immunogen of IBDV. According to VP2-452H subviral particle (SVP) analysis, the determination crystal structure and enzyme-linked immunosorbent assay (ELSIA), showed thar His-tag was not exposed on the surface of VP2-452H SVPs. Thus illustrate that the His-tag apparently did not attribute to the effective purification of this protein by IMAC. An affinity must have existed between the protein VP2 and the immobilized metal ions to achieve SVP binding with Ni-NTA resin. Accordingly, the IBDV generated from DF-1 cell culture and non-tagged VP2-441 SVP generated from a baculovirus-insect cell expression system were purified by IMAC. The purification of IBDV viron through IMAC obtained a 60.5% recovery, and the IMAC-purified IBDV has a similar morphology to the wild-type IBDV with a diameter of 65 nm through electron microscope observation. For SVP formed by VP2-441 purified by IMAC a recovery 92% and a purity of also 92% of mature VP2 were obtained. SVP formed by VP2-441 exhibited a diameter approximately 25 nm. These results obtained from the above experiments can demonstrate 1) the protein VP2 does have interaction with immobilized nickel ion; and 2) the protein VP2 can assist both IBDV viron and SVPs to have the affinity with Ni-NTA resin. The recombinant protein VP2-441, i.e., a structural protein VP2 of infectious bursal disease (IBD) virus, can self-assemble into T=1 subviral particles (SVPs) in baculovirus expression system. These SVPs are not to have multiple his-tags on the surface which result in an efficient purification by immobilized metal-ion affinity chromatography (IMAC). This study aimed at getting more insight into the interaction between VP2-441 SVPs and immobilized metal (Ni2+) ions at molecular level. First of all, large quantity of highly purified VP2-441 SVPs obtained by a one-step purification process allowed the performance of equilibrium adsorption measurements and subsequent determinations of binding constants by fitting two isotherm models, i.e., Temkin and Langmuir-Freundlich. Two general conclusion are obtained, first, the maximum bound VP2-441 SVPs per volume resin is limited because the pore size of IMA gel (ca. 24 nm in diameter) is similar to that of SVPs (20 – 25 nm) and the diffusion of the latter into the pores is hindered. The other is that SVPs have an extremely high affinity to the immobilized Ni+2 ions because the dissociate constants obtained from different models are in the scale of 10-9 M, which suggested the interaction mimicking that between an antigen and its antibody. The high binding strength is derived from a multiple-site binding between VP2-441 SVPs and Ni2+ ions as demonstrated by a concave-up Scatchard plot. Finally, we found that the adsorption of SVPs can be well described by Temkin model. A detail understanding of SVP-immobilized metal ion interactions can provide useful strategies for conducting preparative-scale separations of SVPs or even a real virus using IMAC.