Relevance of aromatic and polar amino acids in the specificity of Inulinase ISO3 from Kluyveromyces marxianus: A molecular dynamics approach with an experimental verification.

The Inulinase from Kluyveromyces marxianus ISO3 (Inu-ISO3) is an enzyme able to hydrolyze linear fructans such as chicory inulin as well as branched fructans like agavin. This enzyme was cloned and expressed in Komagataella pastoris to study the role of selected aromatic and polar residues in the catalytic pocket by Alanine scanning. Molecular dynamics (MD) simulations and enzyme kinetics analysis were performed to study the functional consequences of these amino acid substitutions. Site-directed mutagenesis was used to construct the mutants of the enzyme after carrying out the MD simulations between Inu-ISO3 and its substrates. Mutation Trp79:Ala resulted in the total loss of activity when fructans were used as substrates, while with sucrose, the activity decreased by 98 %. In contrast, the mutations Phe113:Ala and Gln236:Ala increased the invertase activity when sucrose was used as a substrate. Although these amino acids are not part of the conserved motifs where the catalytic triad is located, they are essential for the enzyme's activity. In silico and experimental approaches corroborate the relevance of these residues for substrate binding and their influence on enzymatic activity.

TtCel7A: A Native Thermophilic Bifunctional Cellulose/Xylanase Exogluclanase from the Thermophilic Biomass-Degrading Fungus Thielavia terrestris Co3Bag1, and Its Application in Enzymatic Hydrolysis of Agroindustrial Derivatives.

The biomass-degrading thermophilic ascomycete fungus Thielavia terrestris Co3Bag1 produces TtCel7A, a native bifunctional cellulase/xylanase GH7 family. The purified TtCel7A, with an estimated molecular weight of 71 kDa, was biochemically characterized. TtCel7A displayed an optimal pH of 5.5 for both activities and an optimal temperature of 60 and 50 °C for cellulolytic and xylanolytic activities, respectively. The half-lives determined for cellulase activity were 140, 106, and 41 min at 50, 60, and 70 °C, respectively, whereas the half-lives observed for xylanase activity were 24, 10, and 1.4 h at 50, 60, and 70 °C, respectively. The KM and Vmax values were 3.12 mg/mL and 50 U/mg for cellulase activity and 0.17 mg/mL and 42.75 U/mg for xylanase activity. Circular dichroism analysis suggests changes in the secondary structure of TtCel7A in the presence of CMC as the substrate, whereas no modifications were observed with beechwood xylan. TtCel7A displayed the excellent capability to hydrolyze CMC, beechwood xylan, and complex substrates such as oat bran, wheat bran, and sugarcane bagasse, with glucose and cellobiose being the main products released; also, slightly less endo cellulase and xylanase activities were observed. Thus, suggesting TtCel7A has an exo- and endomode of action. Based on the characteristics of the enzyme, it might be considered a good candidate for industrial applications.

In vitro refolding of the structural protein VP1 of parvovirus B19 produces virus-like particles with functional VP1 unique region.

Virus-like particles (VLPs) from Parvovirus B19 (B19V) can be obtained by the self-assembly of the structural proteins VP1 and VP2. It is possible to produce B19V VLPs either from VP2 or a mixture of VP1 and VP2, through its heterologous expression in eukaryotic cells. The difference between VP1 and VP2 protein is a tract of 227 residues located at the N-terminal region of VP1, known as the VP1 unique region (VP1u). This region is critical for B19V infection, including tropism, cell internalization, and lysosomal scape through its phospholipase 2A activity. Herein, we report the in vitro self-assembly of VP1 to form VLPs. These species have phospholipase activity, suggesting that the phospholipase domain is correctly folded. Furthermore, VP1 and VP2 were co-assembled to produce hybrid VLPs which were able to bind and internalize in the non-permissive HepG2 cells, another evidence of the functionality of the in vitro refolded VP1u.

Effect of the single mutation N9Y on the catalytical properties of xylanase Xyn11A from Cellulomonas uda: a biochemical and molecular dynamic simulation analysis.

Cellulomonas uda produces Xyn11A, moderately thermostable xylanase, with optimal activity at 50 °C and pH 6.5. An improvement in the biochemical properties of Xyn11A was achieved by site-directed mutagenesis approach. Wild-type xylanase, Xyn11A-WT, and its mutant Xyn11A-N9Y were expressed in Escherichia coli, and then both enzymes were purified and characterized. Xyn11A-N9Y displayed optimal activity at 60 °C and pH 7.5, an upward shift of 10 °C in the optimum temperature and an upward shift of 1 unit in optimum pH; also, it manifested an 11-fold increase in thermal stability at 60 °C, compared to that displayed by Xyn11A-WT. Molecular dynamics simulations of Xyn11A-WT and Xyn11A-N9Y suggest that the substitution N9Y leads to an array of secondary structure changes at the N-terminal end and an increase in the number of hydrogen bonds in Xyn11A-N9Y. Based on the significant improvements, Xyn11A-N9Y may be considered as a candidate for several biotechnological applications.

Decoration of virus-like particles with an enzymatic activity of biomedical interest.

The natural properties of virus-like particles (VLPs), like their nanometric size, polyvalence, monodispersity and biocompatibility, had called the attention of scientists from different fields. VLPs constitute an excellent platform for the development nanomaterials with a broad spectrum of applications, ranging from physics of soft matter to the development of vaccines and biological nanocarriers. To expand the repertoire of functions of VLPs, they can be decorated with different molecules. In this research, the α-glucosidase Ima1p of Saccharomyces cerevisiae was attached to the surface of in vitro assembled VLPs of parvovirus B19, by using the SpyTag/SpyCatcher system. The resulting particles were structurally characterized displaying a noticeable increase in size compared to the non-decorated VLPs. The study of the biochemical properties of the coupled enzyme indicate that it increased its Vmax by three-fold toward p-nitrophenyl-α-D-glucopyranoside (p-NPG) as substrate. In addition, the linked enzyme displayed a notorious 10 °C shift in its optimal temperature, from 35 °C for the non-attached enzyme, to 45 °C for the enzyme attached to VLPs. The decorated VLPs were also able to act on glycogen; therefore, these particles may be further developed as part of the therapy for treatment of lysosomal storage diseases derived from defects in the human acid α-glucosidase.

The thermophilic biomass-degrading fungus Thielavia terrestris Co3Bag1 produces a hyperthermophilic and thermostable ß-1,4-xylanase with exo- and endo-activity.

A hyperthermophilic and thermostable xylanase of 82 kDa (TtXynA) was purified from the culture supernatant of T. terrestris Co3Bag1, grown on carboxymethyl cellulose (CMC), and characterized biochemically. TtXynA showed optimal xylanolytic activity at pH 5.5 and at 85 °C, and retained more than 90% of its activity at a broad pH range (4.5-10). The enzyme is highly thermostable with a half-life of 23.1 days at 65 °C, and active in the presence of several metal ions. Circular dichroism spectra strongly suggest the enzyme gains secondary structures when temperature increases. TtXynA displayed higher substrate affinity and higher catalytic efficiency towards beechwood xylan than towards birchwood xylan, oat-spelt xylan, and CMC. According to its final hydrolysis products, TtXynA displays endo-/exo-activity, yielded xylobiose, an unknown oligosaccharide containing about five residues of xylose and a small amount of xylose on beechwood xylan. Finally, this report represents the description of the first fungal hyperthermophilic xylanase which is produced by T. terrestris Co3Bag1. Since TtXynA displays relevant biochemical properties, it may be a suitable candidate for biotechnological applications carried out at high temperatures, like the enzymatic pretreatment of plant biomass for the production of bioethanol.

Improvement of catalytical properties of two invertases highly tolerant to sucrose after expression in Pichia pastoris. Effect of glycosylation on enzyme properties.

Zymomonas mobilis genes encoding INVA and INVB were expressed in Pichia pastoris, under the control of the strong AOX1 promoter, and the recombinant enzymes were named INVAAOX1 and INVBAOX1. The expression levels of INVAAOX1 (1660 U/mg) and INVBAOX1 (1993 U/mg) in P. pastoris were 9- and 7-fold higher than those observed for the native INVA and INVB proteins in Z. mobilis. INVAAOX1 and INVBAOX1 displayed a 2- to 3-fold higher substrate affinity, and a 2- to 200-fold higher catalytic efficiency (kcat/KM) than that observed for native INVA and INVB from Z. mobilis. Positive Schiff staining of INVAAOX1 and INVBAOX1 suggested a glycoprotein nature of both invertases. After deglycosylation of these enzymes, denoted D-INVAAOX1 and D-INVBAOX1, they exhibited a 1.3- and 3-fold lower catalytic efficiency (107 and 164 s(-1) mM(-1), respectively), and a 1.3- to 5-fold lower thermal stability than the glycosylated forms at temperatures of 35-45 °C. After deglycosylation no effect was observed in optimal pH, being of 5.5 for INVAAOX1, INVBAOX1, D-INVAAOX1 and D-INVBAOX1. The invertase activity of both enzymes increased in 80% (INVAAOX1) and 20% (INVBAOX1) in the presence of Mn(2+) at 1 mM and 5 mM, respectively. INVAAOX1 and INVBAOX1 were highly active at sucrose concentrations of up to 400 and 300 mM, respectively; however, the tolerance to sucrose decreased to 300 mM for D-INVAAOX1. Our findings suggest that glycosylation of INVAAOX1 and INVBAOX1 plays an important role in their thermal stability, catalytic efficiency, and tolerance to sucrose. In conclusion, the expression of INVA and INVB from Z. mobilis in P. pastoris yields new catalysts with improved catalytic properties, making them suitable candidates for a number of industrial applications or for the improvement of ethanol production from cane molasses.