Systematic studies of the interactions between a model polyphenol compound and microbial ß-glucosidases.

Lignin is a major obstacle for cost-effective conversion of cellulose into fermentable sugars. Non-productive adsorption onto insoluble lignin fragments and interactions with soluble phenols are important inhibition mechanisms of cellulases, including ß-glucosidases. Here, we examined the inhibitory effect of tannic acid (TAN), a model polyphenolic compound, on ß-glucosidases from the bacterium Thermotoga petrophila (TpBGL1 and TpBGL3) and archaeon Pyrococcus furiosus (PfBGL1). The results revealed that the inhibition effects on ß-glucosidases were TAN concentration-dependent. TpBGL1 and TpBGL3 were more tolerant to the presence of TAN when compared with PfBGL1, while TpBGL1 was less inhibited when compared with TpBGL3. In an attempt to better understand the inhibitory effect, the interaction between TAN and ß-glucosidases were analyzed by isothermal titration calorimetry (ITC). Furthermore, the exposed hydrophobic surface areas in ß-glucosidases were analyzed using a fluorescent probe and compared with the results of inhibition and ITC. The binding constants determined by ITC for the interactions between TAN and ß-glucosidases presented the same order of magnitude. However, the number of binding sites and exposed hydrophobic surface areas varied for the ß-glucosidases studied. The binding between TAN and ß-glucosidases were driven by enthalpic effects and with an unfavorable negative change in entropy upon binding. Furthermore, the data suggest that there is a high correlation between exposed hydrophobic surface areas and the number of binding sites on the inhibition of microbial ß-glucosidases by TAN. These studies can be useful for biotechnological applications.

Characterization and Low-Resolution Structure of an Extremely Thermostable Esterase of Potential Biotechnological Interest from Pyrococcus furiosus.

Enzymes isolated from extremophiles often exhibit superior performance and potential industrial applications. There are several advantages performing biocatalysis at elevated temperatures, including enhanced reaction rates, increased substrate solubility and decreased risks of contamination. Furthermore, thermophilic enzymes usually exhibit high resistance against many organic solvents and detergents, and are also more resistant to proteolytic attack. In this study, we subcloned and characterized an esterase from the hyperthermophilic archaeon Pyrococcus furiosus (Pf_Est) that exhibits optimal activity around 80 °C using naphthol-derived substrates and p-nitrophenyl palmitate (pNPP). According to the circular dichroism spectra, the secondary structure of P. furiosus esterase, which is predominantly formed by a ß-sheet structure, is very stable, even after incubation at 120°C. We performed SAXS to determine the low-resolution structure of Pf_Est, which is monomeric in solution at 80 °C and has a molecular weight of 28 kDa. The Km and V max values for this esterase acting on pNPP were 0.53 mmol/L and 6.5 × 10-3 U, respectively. Pf_Est was most active in the immiscible solvents and retained more than 50 % in miscible solvents. Moreover, Pf_Est possesses transesterification capacity, presenting better results when isobutanol was used as an acyl acceptor (2.69 ± 0.14 × 10-2 µmol/min mg) and the highest hydrolytic activity toward olive oil among different types of oils testes in this study. Collectively, these biophysical and catalytic properties are of interest for several biotechnological applications that require harsh conditions, including high temperature and the presence of organic solvents.

Comparative analysis of three hyperthermophilic GH1 and GH3 family members with industrial potential.

Beta-glucosidases (BGLs) are enzymes of great potential for several industrial processes, since they catalyze the cleavage of glucosidic bonds in cellobiose and other short cellooligosaccharides. However, features such as good stability to temperature, pH, ions and chemicals are required characteristics for industrial applications. This work aimed to provide a comparative biochemical analysis of three thermostable BGLs from Pyrococcus furiosus and Thermotoga petrophila. The genes PfBgl1 (GH1 from P. furiosus), TpBgl1 (GH1 from T. petrophila) and TpBgl3 (GH3 from T. petrophila) were cloned and proteins were expressed in Escherichia coli. The purified enzymes are hyperthermophilic, showing highest activity at temperatures above 80°C at acidic (TpBgl3 and PfBgl1) and neutral (TpBgl1) pHs. The BGLs showed greatest stability to temperature mainly at pH 6.0. Activities using a set of different substrates suggested that TpBgl3 (GH3) is more specific than GH1 family members. In addition, the influence of six monosaccharides on BGL catalysis was assayed. While PfBgl1 and TpBgl3 seemed to be weakly inhibited by monosaccharides, TpBgl1 was activated, with xylose showing the strongest activation. Under the conditions tested, TpBgl1 showed the highest inhibition constant (Ki=1100.00mM) when compared with several BGLs previously characterized. The BGLs studied have potential for industrial use, specifically the enzymes belonging to the GH1 family, due to its broad substrate specificity and weak inhibition by glucose and other saccharides.

Studying the expression of a lipase from Pyrococcus furiosus using response surfaces.

The need to find more stable catalysts has encouraged the study of naturally resilient enzymes, such as those found in extremophile organisms. In the present work, the influence of rare codons on the expression in Escherichia coli of the lipase Pf2001Δ60 from Pyrococcus furiosus was evaluated. Expression was carried out in two E. coli strains, BL21(DE3)pLysS and the rare tRNA supplemented Rosetta(DE3)pLysS. 3(2) factorial design was used to appraise the influence of temperature and inducer concentration on enzyme expression every hour for the 4-h expression period. Four response surfaces were constructed for each time, and the statistical parameters were evaluated. Lipase production was twice as high for Rosetta(DE3)pLysS than for BL21(DE3)pLysS. The factorial design indicated that optimal expression occurred at 30 °C after 4h, with lipase production of 240 U/L. The analysis of statistical parameters during the expression time showed that the velocity at which the enzyme was produced affected cell growth and maximum activity, with a higher speed leading to lower expression and cell growth. The presence of rare tRNAs prevented bottlenecks in lipase expression, and the experimental design was shown to be important for maximizing the production strategies and minimizing the metabolic load to which the host is subjected.