In order to investigate how structural modifications interfere with protein stability, we modified a (beta alpha)-unit in E.coli triosephosphate isomerase (TIM), a typical (beta alpha)-barrel protein, assuming that the pseudosymmetrical beta-barrel can be divided into eight successive loop/beta-strand/loop/alpha-helix motifs. We replaced the eighth (beta alpha)-unit of E.coli TIM with the corresponding chicken (beta alpha)-unit. The substitution, involving the replacement of 10 of the 23 residues of this (beta alpha)-unit, was evaluated first by modelling, then experimentally. Modelling by homology suggests how the amino acid replacements might be accommodated in the hybrid E.coli/chicken TIM (ETIM8CHI). Both natural and hybrid recombinant TIMs, overproduced in E.coli, were purified to homogeneity and characterized as to their stability and kinetics. Our kinetic studies show that the modification performed here leads to an active enzyme. The stability studies indicate that the stability of ETIM8CHI is comparable to that of the wild type TIM.