Alkaline pH-dependent differential unfolding characteristics of mesophilic and thermophilic homologs of dimeric serine hydroxymethyltransferase.

Environmental variables such as pH can significantly influence the folding and stability of a protein molecule. In the present investigation, we compared the alkaline pH-induced unfolding of two homologous serine hydroxymethyltransferase from mesophilic Bacillus subtilis (bsSHMT) and thermophilic Bacillus stearothermophilus (bstSHMT) using various biophysical techniques. The thermophilic enzyme bstSHMT was found to be more resistant to alkaline denaturation compared to its mesophilic counterpart, bsSHMT. Unfolding studies using domain-swapped chimera, constructed by swapping the C-terminal domain of these two wild-type proteins, revealed that C-terminal domain plays a pivotal role in the folding, stability and subunit interaction of these proteins. Primary amino acid sequence analysis of the proteins showed that bsSHMT has six unconserved lysine residues in C-terminal domain, which are absent in bstSHMT. Chemical modification of lysine side chains resulted in stabilization of monomers, only in case of bsSHMT. Moreover, comparison between homology model of bsSHMT with the crystal structure of bstSHMT revealed that a small stretch of 11 amino acids at the end of C-terminal domain was found protruding outside the molecule as a flexible coiled structure in bsSHMT. Taken together these findings suggest that possibly the presence of these non-identical lysine moieties and a small extension of C-terminal domain may be responsible for low stability of bsSHMT under alkaline pH condition.

The C-terminal domain of dimeric serine hydroxymethyltransferase plays a key role in stabilization of the quaternary structure and cooperative unfolding of protein: domain swapping studies with enzymes having high sequence identity.

The serine hydroxymethyltransferase from Bacillus subtilis (bsSHMT) and B. stearothermophilus (bstSHMT) are both homodimers and share approximately 77% sequence identity; however, they show very different thermal stabilities and unfolding pathways. For investigating the role of N- and C-terminal domains in stability and unfolding of dimeric SHMTs, we have swapped the structural domains between bs- and bstSHMT and generated the two novel chimeric proteins bsbstc and bstbsc, respectively. The chimeras had secondary structure, tyrosine, and pyridoxal-5'-phosphate microenvironment similar to that of the wild-type proteins. The chimeras showed enzymatic activity slightly higher than that of the wild-type proteins. Interestingly, the guanidium chloride (GdmCl)-induced unfolding showed that unlike the wild-type bsSHMT, which undergoes dissociation of native dimer into monomers at low guanidium chloride (GdmCl) concentration, resulting in a non-cooperative unfolding of enzyme, its chimera bsbstc, having the C-terminal domain of bstSHMT was resistant to low GdmCl concentration and showed a GdmCl-induced cooperative unfolding from native dimer to unfolded monomer. In contrast, the wild-type dimeric bstSHMT was resistant to low GdmCl concentration and showed a GdmCl-induced cooperative unfolding, whereas its chimera bstbsc, having the C- terminal domain of bsSHMT, showed dissociation of native dimer into monomer at low GdmCl concentration and a GdmCl-induced non-cooperative unfolding. These results clearly demonstrate that the C-terminal domain of dimeric SHMT plays a vital role in stabilization of the oligomeric structure of the native enzyme hence modulating its unfolding pathway.