To gain insight into the folding of large proteins, we constructed a bovine beta-lactoglobulin (beta-lg) dimeric mutant, A34C/C121A beta-lg. In the mutant, a free thiol group of wild-type beta-lg at Cys121 was removed and two beta-lg molecules were linked by a disulfide bridge through Cys34 created at the dimer's interface. Under strongly native conditions at low concentrations of urea, the refolding yield of A34C/C121A beta-lg was low when monitored by heteronuclear NMR spectroscopy. However, under marginally native conditions, the yield improved notably, although the refolding was still slow. H-D exchange pulse labeling monitored using heteronuclear NMR spectroscopy indicated that A34C/C121A beta-lg forms a folding intermediate similar to monomeric C121A beta-lg in spite of its slow folding. These results indicate that the rapid formation of folding intermediates driven by local interactions occurs in a manner independent of the molecular size and that, if the non-native interactions are too strong, the kinetic trap is set, leading to a glasslike misfolded state. The results suggest the important roles of marginal stability and pathways in making the folding of large proteins possible.