Journal:JBSD:39

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[B] <scene name='Journal:JBSD:39/Cv/16'>Structural Variability</scene>: In accordance with the structure of a typical IRD belonging to Pin-II PI family, the predicted structures of CanPI also have <scene name='Journal:JBSD:39/Cv/7'>three antiparallel &#946; sheets joined by disordered loops containing the reactive site and stabilized by four disulfide bonds</scene>. It was thought that the disulfide bonds act as structural scaffold to hold the reactive site in a relatively rigid conformation and provide thermal and proteolytic stability. A single 3<sub>10</sub>-helix of one turn is also present in the structure, the disordered loop is held by disulfide bond in IRD-7 and -12 whereas by a network of intra molecular hydrogen bonds in IRD-9. <scene name='Journal:JBSD:39/Cv/13'>IRD-7</scene> <span style="color:salmon;background-color:black;font-weight:bold;">(colored in salmon)</span> and <scene name='Journal:JBSD:39/Cv/9'>IRD-12</scene> <span style="color:deeppink;background-color:black;font-weight:bold;">(in deeppink)</span> have 4 disulfide bonds, whereas <scene name='Journal:JBSD:39/Cv/14'>IRD-9</scene> <font color='magenta'><b>(in magenta)</b></font> has only 2 disulfide bonds. Furthermore, post-simulation analysis of the intramolecular hydrogen bonds illustrated that IRD-9 with two disulfide bonds (C7-C25 and C8-C37) less, has a relatively higher density of intra-molecular hydrogen bonds as compared to IRD-7 and -12. These intramolecular hydrogen bonds might be substituting the two lost disulfide bonds of IRD-9 to stabilize the protein structure in the active conformation and might be protecting the molecules from a hydrophobic collapse. The replaced serine residues in the place of two cysteines C7 and C8 in IRD-9 may be contributing to the increased number of hydrogen bonds.
[B] <scene name='Journal:JBSD:39/Cv/16'>Structural Variability</scene>: In accordance with the structure of a typical IRD belonging to Pin-II PI family, the predicted structures of CanPI also have <scene name='Journal:JBSD:39/Cv/7'>three antiparallel &#946; sheets joined by disordered loops containing the reactive site and stabilized by four disulfide bonds</scene>. It was thought that the disulfide bonds act as structural scaffold to hold the reactive site in a relatively rigid conformation and provide thermal and proteolytic stability. A single 3<sub>10</sub>-helix of one turn is also present in the structure, the disordered loop is held by disulfide bond in IRD-7 and -12 whereas by a network of intra molecular hydrogen bonds in IRD-9. <scene name='Journal:JBSD:39/Cv/13'>IRD-7</scene> <span style="color:salmon;background-color:black;font-weight:bold;">(colored in salmon)</span> and <scene name='Journal:JBSD:39/Cv/9'>IRD-12</scene> <span style="color:deeppink;background-color:black;font-weight:bold;">(in deeppink)</span> have 4 disulfide bonds, whereas <scene name='Journal:JBSD:39/Cv/14'>IRD-9</scene> <font color='magenta'><b>(in magenta)</b></font> has only 2 disulfide bonds. Furthermore, post-simulation analysis of the intramolecular hydrogen bonds illustrated that IRD-9 with two disulfide bonds (C7-C25 and C8-C37) less, has a relatively higher density of intra-molecular hydrogen bonds as compared to IRD-7 and -12. These intramolecular hydrogen bonds might be substituting the two lost disulfide bonds of IRD-9 to stabilize the protein structure in the active conformation and might be protecting the molecules from a hydrophobic collapse. The replaced serine residues in the place of two cysteines C7 and C8 in IRD-9 may be contributing to the increased number of hydrogen bonds.
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[C] The molecular models of the IRD bound HaTry predicted several atomic interactions with a reactive loop of inhibitors that also explained the contribution of the solvent exposed reactive loop. There are several hydrogen bonds in the <scene name='Journal:JBSD:39/Ird9/3'>IRD-9-HaTry complex</scene>. ARG-39 from <scene name='Journal:JBSD:39/Cv/17'>IRD-12</scene> reactive site formed two hydrogen bonds with the residues of the HaTry active site. In <scene name='Journal:JBSD:39/Ird9/2'>case of IRD-7</scene>, side chain of LYS-39 residue of reactive loop form one hydrogen bond each, with carboxyl oxygen atom of HIS-50. There are additional hydrogen bond exist between side chain of CYS-37 form reactive loop of IRD-9 and -12, with carboxyl oxygen atom of ILE-210 and ARG-109 residue from HaTry. Although the interaction of active site of enzymes with all the three inhibitors were similar in nature, significant differences were observed in making the weak interaction like hydrogen bonding and van der Waal’s interactions, which resulted in differential binding free energy of the complexes. IRD-9 forms the maximum number of stable hydrogen bonds with the active site residues (HIS-50, ASP-95 and SER-207) of the HaTry and which were maintained for longer duration. Although IRD-12 forms relatively more hydrogen bonds, but they are very unstable as reflected by their fluctuating nature. MD simulations provides structural insight into an importance of inter/intra molecular hydrogen bonds and its effect on the interaction between protease and PIs. The results of this analysis were corroborated with previous reports. Post simulation analysis also explained experimentally observed increase in binding affinity, hence activity of IRD-9 towards proteases. See also <ref name="Barrette-Ng">PMID: 12684499</ref> <ref name="Dunse">PMID: 20696921</ref> <ref name="Tamhane">PMID: 19393726</ref> <ref name="Tamhane1">PMID: 15715970</ref>.
+
[C] The molecular models of the IRD bound HaTry predicted several atomic interactions with a reactive loop of inhibitors that also explained the contribution of the solvent exposed reactive loop. There are several hydrogen bonds in the <scene name='Journal:JBSD:39/Ird9/3'>IRD-9-HaTry complex</scene>. ARG-39 from <scene name='Journal:JBSD:39/Cv/17'>IRD-12</scene> reactive site formed two hydrogen bonds with the residues of the HaTry active site. In <scene name='Journal:JBSD:39/Ird9/2'>case of IRD-7</scene>, side chain of LYS-39 residue of reactive loop form one hydrogen bond each, with carboxyl oxygen atom of HIS-50. MD simulations provides structural insight into an importance of inter/intra molecular hydrogen bonds and its effect on the interaction between protease and PIs. The results of this analysis were corroborated with previous reports. Post simulation analysis also explained experimentally observed increase in binding affinity, hence activity of IRD-9 towards proteases. See also <ref name="Barrette-Ng">PMID: 12684499</ref> <ref name="Dunse">PMID: 20696921</ref> <ref name="Tamhane">PMID: 19393726</ref> <ref name="Tamhane1">PMID: 15715970</ref>.
</StructureSection>
</StructureSection>
<references/>
<references/>
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Revision as of 10:16, 2 December 2012

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  1. REF
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  12. Schirra HJ, Guarino RF, Anderson MA, Craik DJ. Selective removal of individual disulfide bonds within a potato type II serine proteinase inhibitor from Nicotiana alata reveals differential stabilization of the reactive-site loop. J Mol Biol. 2010 Jan 22;395(3):609-26. Epub 2009 Nov 17. PMID:19925809 doi:10.1016/j.jmb.2009.11.031
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