Chaperonin is a double ring-shaped oligomeric protein complex, which captures a protein in the folding intermediate state and assists its folding in an ATP-dependent manner. The chaperonin from a hyperthermophilic archaeum, Thermococcus sp. strain KS-1, is a group II chaperonin and is composed of two distinct subunits, alpha and beta. Although these subunits are highly homologous in sequence, the homo-oligomer of the beta-subunit is more thermostable than that of the alpha-subunit. To identify the region responsible for this difference in thermostability, we constructed domain-exchange mutants. The mutants containing the equatorial domain of the beta-subunit were more resistant to thermal dissociation than the mutants with that of the alpha-subunit. Thermostability of a beta-subunit mutant whose C-terminal 22 residues were replaced with those of the alpha-subunit decreased to the comparable level of that of the alpha-subunit homo-oligomer. These results indicate that the difference in thermostability between alpha- and beta-subunits mainly originates in the C-terminal residues in the equatorial domain, only where they exhibit substantial sequence difference.