Computational study enlightens the structural role of the alcohol acyltransferase DFGWG motif
| LEADER | caa a22 4500 | ||
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| 001 | 60551304X | ||
| 003 | CHVBK | ||
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| 007 | cr unu---uuuuu | ||
| 008 | 210128e20150801xx s 000 0 eng | ||
| 024 | 7 | 0 | |a 10.1007/s00894-015-2762-6 |2 doi |
| 035 | |a (NATIONALLICENCE)springer-10.1007/s00894-015-2762-6 | ||
| 245 | 0 | 0 | |a Computational study enlightens the structural role of the alcohol acyltransferase DFGWG motif |h [Elektronische Daten] |c [Luis Morales-Quintana, María Moya-León, Raúl Herrera] |
| 520 | 3 | |a Alcohol acyltransferases (AAT) catalyze the esterification reaction of alcohols and acyl-CoA into esters in fruits and flowers. Despite the high divergence between AAT enzymes, two important and conserved motifs are shared: the catalytic HxxxD motif, and the DFGWG motif. The latter is proposed to play a structural role; however, its function remains unclear. The DFGWG motif is located in loop 21 and stabilized by a hydrogen bond between residues Y52 and D381. Also, this motif is distant from the HxxxD motif, and most probably without a direct role in the substrate interaction. To evaluate the role of the DFGWG motif, in silico analysis was performed in the VpAAT1 protein. Three mutants (Y52F, D381A and D381E) were evaluated. Major changes (size and shape) in the solvent channels were found, although no differences were revealed in the entire 3D structure. Molecular dynamics simulations and docking studies described unfavorable energies for interaction of the mutant proteins with different substrates, as well as unfavored ligand orientations in the solvent channel. Additionally, we examined the contribution of different energetic parameters to the total free energy of protein-ligand complexes by the MM-GBSA method. The complexes differed mainly in their van der Waals contributions and have unfavorable electrostatic interactions. VpAAT1, Y52F and D381A mutants showed a dramatic reduction in the binding capacity to several substrates, which is related to differences in electrostatic potential on the protein surfaces, suggesting that D381 from the DFGWG motif and residue Y52 play a crucial role in maintenance of the adequate solvent channel structure required for catalysis. Graphical abstract Molecular docking, molecular dynamics (MD) simulations and MM-GBSA free energy calculations were employed to obtain quantitative estimates for the binding free energies of wild type Vasconcellea pubescens alcohol acyltransferase (VpAAT1-WT) and the protein mutants. Left VpAAT1 model structure in cartoon representation showing the solvent channel in the middle of the structure. Center, right Changes in shape and structure in the solvent channel of Y52F and D381A mutant proteins, respectively, compared to WT. The results obtained reveal that the interaction between D381 and Y52 residues is important for the maintenance of solvent channel structure | |
| 540 | |a Springer-Verlag Berlin Heidelberg, 2015 | ||
| 690 | 7 | |a Alcohol acyltransferase |2 nationallicence | |
| 690 | 7 | |a Ester biosynthesis |2 nationallicence | |
| 690 | 7 | |a In silico site-directed mutagenesis |2 nationallicence | |
| 690 | 7 | |a Molecular dynamics simulations |2 nationallicence | |
| 690 | 7 | |a MM-GBSA |2 nationallicence | |
| 690 | 7 | |a Vasconcellea pubescens |2 nationallicence | |
| 700 | 1 | |a Morales-Quintana |D Luis |u Laboratorio de Fisiología Vegetal y Genética Molecular, Instituto de Ciencias Biológicas, Universidad de Talca, Casilla 747, Talca, Chile |4 aut | |
| 700 | 1 | |a Moya-León |D María |u Laboratorio de Fisiología Vegetal y Genética Molecular, Instituto de Ciencias Biológicas, Universidad de Talca, Casilla 747, Talca, Chile |4 aut | |
| 700 | 1 | |a Herrera |D Raúl |u Laboratorio de Fisiología Vegetal y Genética Molecular, Instituto de Ciencias Biológicas, Universidad de Talca, Casilla 747, Talca, Chile |4 aut | |
| 773 | 0 | |t Journal of Molecular Modeling |d Springer Berlin Heidelberg |g 21/8(2015-08-01), 1-10 |x 1610-2940 |q 21:8<1 |1 2015 |2 21 |o 894 | |
| 856 | 4 | 0 | |u https://doi.org/10.1007/s00894-015-2762-6 |q text/html |z Onlinezugriff via DOI |
| 898 | |a BK010053 |b XK010053 |c XK010000 | ||
| 900 | 7 | |a Metadata rights reserved |b Springer special CC-BY-NC licence |2 nationallicence | |
| 908 | |D 1 |a research-article |2 jats | ||
| 949 | |B NATIONALLICENCE |F NATIONALLICENCE |b NL-springer | ||
| 950 | |B NATIONALLICENCE |P 856 |E 40 |u https://doi.org/10.1007/s00894-015-2762-6 |q text/html |z Onlinezugriff via DOI | ||
| 950 | |B NATIONALLICENCE |P 700 |E 1- |a Morales-Quintana |D Luis |u Laboratorio de Fisiología Vegetal y Genética Molecular, Instituto de Ciencias Biológicas, Universidad de Talca, Casilla 747, Talca, Chile |4 aut | ||
| 950 | |B NATIONALLICENCE |P 700 |E 1- |a Moya-León |D María |u Laboratorio de Fisiología Vegetal y Genética Molecular, Instituto de Ciencias Biológicas, Universidad de Talca, Casilla 747, Talca, Chile |4 aut | ||
| 950 | |B NATIONALLICENCE |P 700 |E 1- |a Herrera |D Raúl |u Laboratorio de Fisiología Vegetal y Genética Molecular, Instituto de Ciencias Biológicas, Universidad de Talca, Casilla 747, Talca, Chile |4 aut | ||
| 950 | |B NATIONALLICENCE |P 773 |E 0- |t Journal of Molecular Modeling |d Springer Berlin Heidelberg |g 21/8(2015-08-01), 1-10 |x 1610-2940 |q 21:8<1 |1 2015 |2 21 |o 894 | ||