Crystallization of Bowman-Birk type protease inhibitor (peanut) and its complex with trypsin

A salt-bridge stabilized C-terminal hook is critical for the dimerization of a Bowman Birk inhibitor

Legume Bowman-Birk inhibitors (BBIs) that inhibit mammalian proteases exist as dimers in solution. The structural basis governing dimerization of HGI-III (horsegram seed BBI) was investigated. An intra-monomer salt bridge (D76-K71) stabilizes an atypical hook-like conformation at the C-terminus. We postulate that this hook, positions D75 to enable an inter-monomer salt-bridge D75(a)-K24(b), which results in dimerization. We verify this by K71A and D76A mutations of HGI-III. The mutants were both monomers, likely due to destabilization of the C-terminal hook. Dimerization was sustained in a double mutant K71D/D76K that was anticipated to form a similar hook critical for dimerization. Conversely, K24(b) that interacts with D75(a) of the loop is the specificity determining residue that interacts with trypsin to inhibit its activity. The inter-monomer salt bridge D75(a)-K24(b) must be disrupted for the inhibition of trypsin, requiring HGI-III to transition into a monomer. Size exclusion studies and a model of HGI-III-trypsin complex support this notion. Interestingly, isoforms of the inhibitor present in germinated seeds (HGGIs) are monomers; and most strikingly, the C-termini of these inhibitors are truncated with the loss the C-terminal hook critical for dimerization. The tendency of HGI-III to self-associate seems to relate to its physiological function of a storage protein.

Functional expression of horsegram (Dolichos biflorus) Bowman-Birk inhibitor and its self-association

Horsegram (Dolichos biflorus), a protein-rich leguminous pulse, native to Southeast Asia and tropical Africa, contains multiple forms of Bowman-Birk inhibitors. The major Bowman-Birk inhibitor from horsegram (HGI-III) was cloned and functionally expressed in Escherichiacoli (rHGI), which moved as a dimer in solution similar to the natural inhibitor. The biochemical characterization of rHGI also points to its close resemblance with HGI-III not only in its structure but also in its inhibitory characteristics. To explore the electrostatic interactions involved in the dimerization, a site-directed mutagenesis approach was used. The role of reactive site residue K24 and the C-terminal Asp in the structure and stability of the dimer was accomplished by mutating K24 and D75/76. The mutants produced in this study confirm that the self-association of HGI-III is indeed due to the electrostatic interaction between K24 of one monomer and D75/76 of the second monomer, in agreement with our previous data. The functional expression of a Bowman-Birk inhibitor minus a fusion tag serves as a platform to study the structural and functional effects of the special pattern of seven conserved disulphide bridges.