Molecular dynamic and docking interaction study of Heterodera glycines serine proteinase with Vigna mungo proteinase inhibitor.

Many plants do produce various defense proteins like proteinase inhibitors (PIs) to protect them against various pests. PIs function as pseudosubstrates of digestive proteinase, which inhibits proteolysis in pests and leads to amino acid deficiency-based mortality. This work reports the structural interaction studies of serine proteinase of Heterodera glycines (SPHG) with Vigna mungo proteinase inhibitor (VMPI). 3D protein structure modeling, validation of SPHG and VMPI, and their putative protein-protein binding sites were predicted. Protein-protein docking followed by molecular dynamic simulation was performed to find the reliable confirmation of SPHG-VMPI complex. Trajectory analysis of each successive conformation concludes better interaction of first loop in comparison with second loop. Lysine residues of first loop were actively participating in complex formation. Overall, this study discloses the structural aspects and interaction mechanisms of VMPI with SPHG, and it would be helpful in the development of pest-resistant genetically modified crops.

Evolutionary and functional analysis of fructose bisphosphate aldolase of plant parasitic nematodes.

The essential and ubiquitous enzyme fructose bisphosphate aldolase (FBPA) has been a good target for controlling the various types of infections caused by pathogens and parasites. The parasitic infections of nematodes are the major concern of scientific community, leading to biochemical characterization of this enzyme. In this work we have developed a small dataset of all types of FBPA sequences collected from publically available databases (EMBL, NCBI and Uni-Port). The Phylogenetic study shows that evolutionary relationships among sequences of FBPA are clustered into three main groups. FBPA sequences of Globodera rostochiensis (FBPA_GR) and Heterodera glycines (FBPA_HG) are placed in group II, sharing the similar evolutionary relationship. The catalytic mechanism of these enzymes depends upon which class of aldolase, it belongs. The class of enzyme has been confirmed on the basis of sequences and structural similarity with template structure of class I FBPA. To confirm catalytic mechanism of above said model structures, the known substrate fructose-1, 6-bisphosphate (FBP) and competitive inhibitor Mannitol-1, 6 bisphosphate (MBP) were docked at known catalytic site of enzyme of interest. The comparative docking analysis shows that enzyme-substrate complex is forming similar Schiff base intermediate and conducts C(3)-C(4) bond cleavage by forming Hydrogen bonding with reaction catalyzing Glu-191, reactive Lys-150, and Schiff base forming Lys-233. On the other hand enzymeinhibitor noncovalent complex is forming cabinolamine precursor and the proton transfer by the formation of hydrogen bond between MBP O(2) with Glu191 enabling stabilization of cabinolamine transition state, which confirms the similar inhibition mechanism. Thus we conclude that Plant Parasitic Nematodes (PPNs) have evolutionary and functional relationship with the class I aldolase enzyme. Hence, FBPA can be targeted to control plant parasitic nematodes.