Binding of AMP to two of the four subunits of pig kidney fructose-1,6-bisphosphatase induces the allosteric transition.

To study the allosteric transition in pig kidney fructose 1,6-bisphosphatase (FBPase), we constructed hybrids in which subunits have either their active or regulatory sites rendered nonfunctional by specific mutations. This was accomplished by the coexpression of the enzyme from a plasmid that contained two slightly different copies of the cDNA. To resolve and purify each of the hybrid enzymes, six aspartic acid codons were added before the termination codon of one of the cDNAs. The addition of these Asp residues to the protein did not alter the kinetic or allosteric properties of the resulting FBPase. Expression of the enzyme from a dual-gene plasmid resulted in the production of a set of five different enzymes (two homotetramers and three hybrid tetramers) that could be purified by a combination of affinity and anion-exchange chromatography because of the differential charge on each of these species. The hybrid with one subunit that only had a functional regulatory site (R) and three subunits that only had a functional active site (A) exhibited biphasic AMP inhibition. Analysis of these data suggest that the binding of AMP to the R subunit is able to globally alter the activity of the other three A subunits. The hybrid composed of two R and two A subunits is completely inhibited at an AMP concentration of approximately 0.5 mM, 100-fold less than the concentration required to fully inhibit the A(4) enzyme. The monophasic nature of this cooperative inhibition suggests that the AMP binding to the two R subunits is sufficient to completely inhibit the enzyme and suggests that the binding of AMP to only two of the four subunits of the enzyme induces the global allosteric transition from the R to the T state.