Comparative analysis of β-glucosidase activity in non-conventional yeasts

GONZÁLEZ-HERNÁNDEZ, JUAN CARLOS; RAMÍREZ-CONEJO, JUAN DAVID; GARCÍA-AGUIRRE, YOLANDA PATRICIA

doi:10.1590/0001-3765202320221118

Abstract

The objective of this study was to evaluate the β-glucosidase activity in the non-conventional yeasts under cellulose, glucose and sucrose substrates. The participation of the enzyme β-glucosidase and its contribution to the enzymatic degradation of tannins is known. Within the classification of tannins are ellagitannins, molecules of gallic acid and ellagic acid, which are considered as nutraceutical compounds due to the properties that they present and that they can be used in the design of food and new drugs, synthesis of materials with antimicrobial capacity. The extracellular β-glucosidase activity was mainly presented in the Candida and Pichia strains, being the glucose and sucrose media the most capable for inducing the activity that showed maximum values with P. pastoris in glucose (0.1682±0.00 µmol/min mg protein), and C. utilis in cellulose (0.1129±0.1349 µmol/min mg of protein), and sucrose (0.0657±0.0214 µmol/min mg protein). Additionally, I. terricola and P. kluyvery stood out in a qualitative cellulose degradation approach measured by Congo red method (9.60±0.04 mm and 9.20±0.05 mm respectively). These indicate that P. pastoris and C. utilis have potential as β-glucosidase producers, especially when growing under complex carbon sources for biomass conversion, new biofuels production and polyphenol degradation with more manageable bioreactor process.

Key words
β-glucosidase; non-conventional yeasts; biomass conversion; Tannins; Cellulolytic activity

INTRODUCTION

Production of nutraceutical compounds with antimicrobial, antiviral and anticancer activity from tannins degradation has been widely explored where several strains of filamentous fungi, mainly of the genus Aspergillus sp., have been used to transform different vegetal sources rich in these singular variety of polyphenols by the action of enzymes that present hydrolytic activity such as tannase, ellagitannase, and β-glucosidase (Aguilar-Zárate et al. 2013AGUILAR-ZÁRATE P, CHÁVEZ-GONZÁLEZ ML, RODRÍGUEZ-HERRERA R & AGUILAR CN. 2013. Biotechnological production of gallic acid. Handbook on Gallic Acid: Natural Occurrences, Antioxidant Properties and Health Implications. Nova Science Publishers, Inc., Belmares et al. 2004BELMARES R, CONTRERAS-ESQUIVEL JC, RODRÍGUEZ-HERRERA R, CORONEL AR & AGUILAR CN. 2004. Microbial production of tannase: An enzyme with potential use in food industry. Food Sci Technol 8: 57-864., Huang et al. 2008HUANG W, NIU H, LI Z, HE Y, GONG W & GONG G. 2008. Optimization of ellagic acid production from ellagitannins by co-culture and correlation between its yield and activities of relevant enzymes. Bioresour Technol 99(4): 769-775., Shi et al. 2005SHI B, HE Q, YAO K, HUANG W & LI Q. 2005. Production of ellagic acid from degradation of valonea tannins by Aspergillus niger and Candida utilis. J Chem Technol Biotechnol 80(10): 1154-1159.). Nonetheless, the use of filamentous fungi presents an increment in the complexity of large-scale production due to the fermentation time and the formation of hyphae that modifies the rheology of the medium leading to limitations in the mass transference and a more complicated extraction and purification of the products (Gibbs et al. 2000GIBBS PA, SEVIOUR RJ & SCHMID F. 2000. Growth of Filamentous Fungi in Submerged Culture: Problems and Possible Solutions. Crit Rev Biotechnol 20(1): 17-48.). Non-conventional yeasts can contribute to resolving these problems due to their ability to form high cell densities cultures and to express a high number of extracellular proteins in a more manageable bioreactor process than filamentous fungi besides their capability to metabolize non-traditional substrates and lead to varied metabolic pathways make them potential candidates for bioprocesses improvement (Wagner & Alper 2016WAGNER JM & ALPER HS. 2016. Synthetic biology and molecular genetics in non-conventional yeasts: Current tools and future advances. Fungal Genet Biol 89: 126-136.). In the attempt to improve nutraceutical compounds production, we have developed a strategy using non-conventional yeasts to degrade tannins evaluating the activity of the hydrolytic enzymes tannase, ellagitannase, and β-glucosidase giving a particular emphasis on the analysis of β-glucosidase activity for its polyphenol degradation capacity. The β-glucosidase is a cellulase that in synergy with exoglucanases (EC 3.2.1.91) and endoglucanases (EC 3.2.1.4) breaks down the cellulose polymer to release small sugars fragments in a process known as saccharification, this process begins with the action of the endoglucanase that cut off randomly the cellulose polymer and release small fragments that then will be hydrolyzed to form cellobiose by exoglucanases and finally β-glucosidases converts cellobiose to glucose through hydrolysis of the β-1,4 linkages (Mohanram et al. 2013MOHANRAM S, AMAT D, CHOUDHARY J, ARORA A & NAIN L. 2013. Novel perspectives for evolving enzyme cocktails for lignocellulose hydrolysis in biorefineries. Sustain Chem Process 1: 15.). In the application concerning to bioethanol production, the glucose released goes to fermentation proceed by extraction and purification stages. Finally, this study aims to evaluate the β-glucosidase activity in the non-conventional yeasts Debaryomyces hansenii PYC 2968, Debaryomyces hansenii PYC ISA 1510, Candida utilis, Candida parapsilosis, Pichia kluyvery, Issatchenkia terricola and Pichia pastoris under different polymeric (cellulose) and nonpolymeric (glucose and sucrose) substrates to their potential application in biotechnological processes.

MATERIALS AND METHODS

Non-conventional Yeastes and media

D. hansenii PYC 2968 and D. hansenii PYC ISA 1510 were obtained from the Higher Institute of Agronomy (Lisbon, Portugal) whereas C. utilis, C. parapsilosis, P. kluyvery, I. terricola, and P. pastoris were provided from the Instituto Tecnológico de Morelia, Biochemistry Laboratory (Morelia, Mexico). All strains were maintained in a modified Yeast Extract Peptone Dextrose medium (YEPD: In the evaluation of β-glucosidase activity, glucose, sucrose and carboxymethylcellulose (20 g/L) were used as inducing substrates) containing MgSO₄ (0.5 g/ L), K₂HPO₄ (1 g/L), KH₂PO₄ (1 g/L), Na₂HPO₄ (3 g/L), CaCl₂ (0.02 g/L), casein peptone (10 g/L), yeast extract (10 g/L), glucose (20 g/L) and agar (20g/L) sterilized for 15 min at 121 °C and incubated for 24 h at 32 °C after inoculation.

Cellulolytic activity and halo essays by Congo Red

The cellulolytic activity was measured through a modification of the method proposed by Teather & Wood (1982)TEATHER RM & WOOD PJ. 1982. Use of congo red-polysaccharide interaction in enumeration and characterization of cellulolytic bacteria from the bovine rumen. Appl Environ Biotechnol 43(4): 777-780.. Yeasts were grown in the modified YEPD medium using carboxymethylcellulose CMC (10 g/L) as a carbon source for 48 h at 32 °C and Congo Red (1 % w/w) was added for 15 min as an indicator of cellulose degradation due to its ability to form a complex with this polymer indicated as a red coloration that disappears and leaves a degradation halo when cellulose is hydrolyzed (Pointing 1999POINTING CA. 1999. Qualitative methods for the determination of lignocellulotyc enzyme production by tropical fungi. Funga Divers 2: 17-33., Zhang et al. 2006ZHANG HP, HIMMEL ME & MIELENZ JR. 2006. Outlook for cellulase improvent: Screening and selection strategies. Biotechnol Adv 24: 452-481.), then the plates were washed out applying HCl solution (0.1M) for 15 min and the size of the halos was measured. For the halo experiments, it was carried out in the same way as described, but the Petri dish was inoculated at an initial concentration of 1 X 10⁷ cells / mL of each strain evaluated.

Growth kinetics

Growth kinetics were performed in the modified YEPD medium without agar and modifying the carbon source with glucose, cellulose, and sucrose (20 g/L) for 32 h at 32 °C and 180 rpm in a SI-300R orbital incubator. Samples were collected every 4 hours for cell concentration, potential for hydrogen (pH), reducing sugars, proteins, and β-glucosidase activity quantification. Logistic Model was applied to adjust growth curves and kinetical parameters were obtained (González-Hernández et al. 2015GONZÁLEZ-HERNÁNDEZ JC, ALCÁNTAR-COVARRUBIAS MA & CORTÉS-ROJO C. 2015. Producción de trehalosa a partir de levaduras no-convencionales. Rev Mex Ing Quím 4(1): 11-23.).

Analytical techniques

Cell concentration was quantified via direct count in Neubauer chamber using 100 μL of the fermentation medium and methylene blue (1% v/v) for staining viable cells according to the technique taken and modified from González-Hernández et al. (2015)GONZÁLEZ-HERNÁNDEZ JC, ALCÁNTAR-COVARRUBIAS MA & CORTÉS-ROJO C. 2015. Producción de trehalosa a partir de levaduras no-convencionales. Rev Mex Ing Quím 4(1): 11-23. and pH variations were measured with a potentiometer (Hanna Instruments).

Reducing sugars were quantified through the method proposed by Miller (1959)MILLER GL. 1959. Use of Dinitrosalicylic Acid Reagent for Determination of Reducing Sugar. Anal Chem 31(3): 426-428. using 1 mL of the centrifuged fermentation medium, the pellet was discharged and 10 μL of the supernatant were mixed with 3,5-dinitrosalicylic acid (DNS) for 5 min at 100 °C in a water bath (Felisa), the reaction was stopped by cooling it down into an ice bath for a posterior measure in a spectrophotometer Perkin Elmer Lambda 35 at 540 nm.

Extracellular proteins were analyzed by the Bradford technique (Bradford 1976BRADFORD MM. 1976. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Chem 72(1-2): 248-254.) using 50 μL of the supernatant mixed with Bradford reagent and quantified in a spectrophotometer Perkin Elmer Lambda 35 at 595 nm.

β -glucosidase activity

The enzymatic assays were performed according to a modification of the protocol proposed by González-Pombo et al. (2011)GONZÁLEZ-POMBO P, FARIÑA L, CARRAU F & BATISTA-VIERA FBM. 2011. A novel extracellular β-glucosidase from Issatchenkia terricola: isolation, immobilization and application for aroma enhancement of white Muscat wine. Process Biochem 46(1): 385-389. that quantifies the release of p-nitrophenyl due to p-nitrophenyl-β-D-glucopyranoside hydrolysys by β-glucosidase, using an aliquot of 1 mL centrifuged and afterward separated from the pellet, then 100 μL of the supernatant were mixed with 900 μL of p-nitrophenyl-β-D-glucopyranoside in phosphate/citrate buffer (5 mM) and this reaction mixture was incubated for 1 h at 40 °C in a water bath (Felisa), the reaction was stopped with sodium carbonate solution (20% w/v), kept 30 min in incubation and measured in a Perkin Elmer Lambda 35 spectrophotometer at 400 nm.

Statistical analysis

The experiments carried out are a completely randomized design, in which the effect of different substrates (20 g / L) on non-conventional yeasts is being evaluated. Statistical analysis was performed using one-way ANOVA employing GraphPad Prism v8.01 for Windows (San Diego, California USA). Differences between measurements were considered significant when p values were lower than 0.05 and a further Tukey´s LSD test was performed for significant treatments. For the fit of the logistic model for kinetic data, the results were obtained with the JMP 6.0® program.

RESULTS

Cellulolytic activity

The qualitative evaluation performed on Congo Red media presented white areas of degradation mainly by the strains C. parapsilosis and P. kluyveri followed by D. hansenii PYC ISA 1510, I. terricola and C. utilis, even though, these results are not conclusive since the area can not be measured (Supplementary Material - Figure S1), this made necessary the implementation of a semiquantitative approach by inoculating an initial cell concentration of 1x10⁷ cell/mL at the center of the plates (Figure S2). The results obtained indicated that the best cellulolytic activity was presented by I. terrícola with degradation halos of 9.60±0.04 mm, followed by P. kluyveri, C. parapsilosis, and C. utilis, with 9.20±0.05, 8.67±0.03, and 8.57±0.04 mm respectively (Suplementary Material - Table SI).

Growth kinetics

It was observed through the short duration of the exponential phase that the metabolism of the analyzed yeasts was accelerated when utilizing glucose as the carbon source making it a suitable substrate for yeast growth, on the other hand, the adaptation phase of I. terricola was lower compared to the rest of the yeasts reaching the stationary phase at around hour 5 and for most of the strains this phase was reached in the hour 10 with the exception of D. hansenii PYC ISA 1510 (6 h) as shown in Figure 1a.

Figure 1
Growth kinetics in non-conventional yeasts during induction with (a) glucose, (b) sucrose, and (c) cellulose. The results are representative data from n = 2.

Sucrose evaluation presented a similar behavior to glucose kinetics showing a prolonged exponential growth phase that started at around 2 h and reached stationaty phase at around 8 h for C. utilis and D. hansenii PYC 2968 and at 12 h for the rest of the yeasts. See Figure 1b.

Finally, cellulose evaluation presented a lower growth in comparison with the other carbon sources, as seen in Figure 1c, prolonged exponential growth phases are observed for most of the strains that reached the stationary phase between 10 h and 14 h showing a low capacity to metabolize this carbon source, duplication times and the specific growth rates data is displayed in Table I.

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Table I
Duplication time (tD) and specific growth rate (µ) in non-conventional induced with Glucose, Sucrose, and Cellulose. The data are presented as mean ± standard deviation, n=2.

The doubling times (tD) show us that for all the strains evaluated, the medium with cellulose presents the highest doubling times, therefore the metabolic capacity of the strains is diminished in this medium.

The specific growth rates (µ) in the non-conventional yeasts evaluated decreased when changing the growth medium from glucose to sucrose and cellulose, with the exception of the C. utilis strain, which presented a higher growth rate in the medium with sucrose. The strains that best adapted to growth on cellulose were from the genus Candida, particularly C. utilis, followed by C. parapsilosis.

pH

We described the pH decrement for glucose and sucrose media have a similar behavior (Figure 2a and 2b) possibly due to the release of protons and organic acids caused by the fermentation process (Serrano et al. 1986SERRANO R, KIELLANDBRANDT MC & FINK GR. 1986. Yeast Plasma-Membrane Atpase Is Essential for Growth and Has Homology with (Na++K+), K+- and Ca-2+-Atpases. Nature 319(6055): 689-693., González-Hernández et al. 2015GONZÁLEZ-HERNÁNDEZ JC, ALCÁNTAR-COVARRUBIAS MA & CORTÉS-ROJO C. 2015. Producción de trehalosa a partir de levaduras no-convencionales. Rev Mex Ing Quím 4(1): 11-23.). The strain C. utilis exhibited constant acidification of the media when evaluated on glucose and sucrose, but when the fermentation was performed using cellulose, an alkalinization tendency was observed (Figure 2c). It is observed that in the medium with YPD the yeasts tend to decrease the pH in the exponential phase due to the activity of the ATPase of the plasmatic membrane, which participates in the regulation of internal pH by pumping protons out of cells, subsequent to this shows an increase in pH at the beginning of the stationary phase due to a process of homeostasis (Serrano et al. 1986SERRANO R, KIELLANDBRANDT MC & FINK GR. 1986. Yeast Plasma-Membrane Atpase Is Essential for Growth and Has Homology with (Na++K+), K+- and Ca-2+-Atpases. Nature 319(6055): 689-693.).

Figure 2
pH comparison for the growth in non-conventional yeasts during induction with (a) glucose, (b) sucrose, and (c) cellulose. The results are representative data from n = 2.

The alkalinization tendency of the extracellular pH is an important condition that influences or even determines many aspects of cell biology, such as growth and differentiation. Lamb & Mitchell (2003)LAMB TM & MITCHELL AP. 2003. The transcription factor Rim101p governs ion tolerance and cell differentiation by direct repression of the regulatory genes NRG1 and SMP1 in Saccharomyces cerevisiae. Mol Cell Biol 23: 677-686. proposed that a secondary effect of external alkalinization may be due to nutrient and ion limitation (Bensen et al. 2004BENSEN ES, MARTIN SJ, LI M, BERMAN J & DAVIS DA. 2004. Transcriptional profiling in Candida albicans reveals new adaptive responses to extracellular pH and functions for Rim101p. Mol Microbiol 54: 1335-1351.) arising from disruption of the plasma membrane proton gradient (PMP). However, we did not test for a PMP disruption resulting from the pH gradient. Based on our DNS substrate results, it is suggested that it may be nutrient limitation (this behavior is more visual in the presence of sucrose and cellulose as substrate), which would not allow efficient plasma membrane ATPase activity. Alkalization mainly occurred to C. utilis and P. kluyveri yeasts, where the final pH values were increased by 0.9 and 0.8 units each compared to the initial value. Additionally, pH values between 6 and 7.5 have been reported as optimal for β-glucosidase production, and as a variable that has major influence over the enzymatic activity (Granados & Valderrama 2003GRANADOS L & VALDERRAMA J. 2003. Evaluación de la actividad proteolítica y amilolítica de Actinomycetes termofílicos aislados a partir de pilas de composta. Tesis de Microbiología Industrial. Facultad de ciencias. Pontificia Universidad Javeriana. Bogota, Colombia.).

Reducing sugars

The analysis of reducing sugars presents different behaviors in each of the carbon sources evaluated showing a decrement for all the strains in the media supplied with glucose (Figure 3a), on the other hand, for sucrose and cellulose media it is not possible to calculate the concentration of reducing sugars by this technique due to the characteristics of the carbon source as observed in Figures 3b and 3c, respectively. However, for fermentations with sucrose as carbon source, a gradual increase in the concentration and subsequent decay is exhibited attributed to the decomposition of sucrose to its reducing sugars components, fructose and glucose, being visible in D. hansenii PYC ISA 1510, P. kluyvery and C. utilis, where the increase of reducing sugars is observed around the hour 8 for D. hansenii PYC ISA 1510 and around the hour 12 for P. kluyvery and C. utilis.

Figure 3
Reducing sugars uptake for the growth in non-conventional yeasts during induction with (a) glucose, (b) sucrose, and (c) cellulose. The results are representative data from n = 2.

β-glucosidase activity

As presented in Figure 4a for the evaluation of the enzymatic activity with glucose, P. pastoris exhibited higher enzymatic activity than the remaining strains that started at around 12 h (0.1044±0.00 µmol/min mg of protein) and reached a maximum value at 28 h (0.1682±0.00 µmol/min mg of protein), followed by C. parapsilosis with a maximum at 28 h (0.0768±0.0103 µmol/min mg of protein), C. utilis (0.0734±0.00), D. hansenii PYC ISA 1510 (0.0548±0.0047), I. terrícola (0.054±0.0000), D. hansenii PYC 2968 (0.052±0.0072), and P. kluyvery (0.051±0.000 µmol/min mg of protein) in descending order at 28 h.

Figure 4
β-glucosidase activity in non-conventional yeasts during induction with (a) glucose, (b) sucrose, and (c) cellulose. The results are representative data from n = 2.

Figure 4b exhibits the corresponding enzymatic activities to medium with sucrose, where the highest enzymatic activity was presented by C. utilis and P. pastoris, both of them showed a similar behavior, having a considerable increase at 20 h, reaching its maximum value at 28 h, with 0.0657±0.0214 and 0.0635±0.0027 µmol/min mg of protein, respectively followed by I. terricola (0.0558±0.0659 µmol/min mg of protein), D. hansenii PYC 2968 (0.0516±0.0102 µmol/min mg of protein), P. kluyvery (0.0468±0.0150 µmol/min mg of protein), D. hansenii PYC ISA 1510 (0.0365±0.0162 µmol/min mg of protein), and C. parapsilosis (0.0162±0.0036 µmol/min mg of protein).

The evaluated non conventional yeasts metabolized cellulose as shown in Figure 4c, however, C. utilis is the only one that exhibited outstanding enzymatic activity starting at 20 h (0.0145±0.01 µmol/min mg of protein) and reaching the maximum activity at 28 h (0.1129±0.1349 µmol/min mg of protein) followed by C. parapsilosis that presented activity at 20 h (0.0211±0.0038 µmol/min mg of protein) and had a maximum level at 24 h (0.0412±0.0269 µmol/min mg of protein), subsequently, I. terrícola, P. kluyvery, P. pastoris, D. hansenii PYC ISA 1510, and D. hansenii PYC 2968 reached the maximum enzymatic activity at 20 h (0.0340±0.00 µmol/min mg of protein), 20 h (0.0189±0.00 µmol/min mg of protein), 28 h (0.0077±0.0042 µmol/min mg of protein), 28 h (0.0071±0.0029 µmol/min mg of protein), and 28 h (0.0038±0.0009 µmol/min mg of protein) respectively. The results indicate that yeasts of the genus Candida and Pichia are producers of β-glucosidase, which is correlated to previous research, including intracellular and extracellular activity (Polachek et al. 1987, Rosi et al. 1994ROSI I, VINELLA M & DOMIZIO P. 1994. Characterization of β-glucosidase activity in yeasts of oenological origin. J Appl Bacteriol 77(5): 519-527., Mateo & Maicas 2016MATEO JJ & MAICAS S. 2016. Application of non-saccharomyces yeasts to wine-making process. Fermentation 2(14): 2030014.).

DISCUSSION

It is important to mention that C. parapsilosis and C. utilis exhibited better adaptation to the media due to its high biomass production and growth rate, but these results can provide only a general panorama on yeasts enzymatic activity.

These results compared with the ones obtained by Lu et al. (2005)LU W, WANG H, YANG Z & NIE Y. 2005. Isolation and characterización of mesophilic cellulose-degrading bacteria from flower stalks-vegetable waste co-composting system. J Gen Appl Microbiol 51: 353-360. who reported degradation halos of 6.4 cm for mesophilic bacteria collected from flower stems showed significantly lower activity for this research reaching nearly 15% of the halo size shown in bacteria. On the other hand, degradation halos of 0.2, 0.3 and 0.35 mm were reported by Gaitan & Pérez (2007)GAITAN BDM & PÉREZ PLI. 2007. Aislamiento y evaluación de microorganismos celulolíticos a partir de residuos vegetales frescos y en compost generados en un cultivo de crisantemo (Dendranthema grandiflora). Tesis de Microbiología Industrial. Facultad de Ciencias. Pontificia Universidad Javeriana. Bogota, Colombia. for cellulose-degrading bacteria isolated from a Dendranthema grandiflora culture, that presents a guideline to consider non-conventional yeasts as potential cellulolytic microorganism with a more hydrolytic activity than several bacterial strains (Figures S1 and S2).

The specific growth rate for glucose evaluation is maintained at similar values and within the expected range, when changing the carbon source, it can be observed a decrement in the growth rate. On the other hand, duplication time gives us information about the yeast metabolism employed as an indicator of the effect, either positive or negative, of a substrate on microorganisms growth and we can observe that for glucose I. terricola had the shortest duplication time followed by D. hansenii PYC 2968 and P. kluyvery, for sucrose, C. utilis had better adaptation to the medium followed by D. hansenii PYC 2968 and C. parapsilosis, and finally for the media with cellulose the three best-adapted yeasts were C. parapsilosis, C. utilis and D. hansenii PYC 2968, which were the yeasts that metabolize the three carbon sources with the lowest duplication times meaning that they can be utilized in degradation processes with complex carbon sources having a positive effect.

C. utilis is the microorganism best adapted to the different carbon sources according to the duplication times that were higher than most of the strains, also enzymatic activity stood out for its ability to metabolize complex molecules such as cellulose, sucrose and simple substrates such as glucose. In the same way, C. parapsilosis displayed a positive effect on cellulose degradation, similar to the enzymatic activity in the medium with glucose, this strain also presented outstanding results in Congo essays, I. terricola, on the other hand, exhibited viable enzymatic activity with sucrose and cellulose and P. pastoris is a microorganism whose enzymatic activity is benefited in simpler substrates.

Some investigations for β-glucosidases activity in non-conventional yeasts are presented in Table II and Figure 5, only the studies conducted by Sim & Hang (1996)SIM SL & HANG YD. 1996. Research Note: Sauerkraut Brine: A potential substrate for production of yeast β-Glucosidase. J Food Sci Technol 29(4): 365-367., Yanai & Sato (1999) and Turan & Zheng (2005)TURAN Y & ZHENG M. 2005. Purification and characterization of an intracellular β-glucosidase from Methylotropic yeast Pichia pastoris. Biochem (Moscow) 70(12): 1363-1368. report enzymatic activity in units comparable to the ones expressed in this research, in comparison to these studies, P. pastoris evaluated on glucose media and C. utilis evaluated on cellulose are similar to what has been reported, nonetheless, other results may not be comparable in magnitude, however, others non conventional yeasts can be found in literature for β-glucosidase activity such as the ones of the genus Kloeckera, Candida, Debaryomyces, Rhodotorula, Pichia, Zygosaccharomyces, Brettanomyces, and Kluyveromyces (Strauss et al. 2001STRAUSS MLA, JOLLY NP, LAMBRECHTS MG & VAN RENSBURG P. 2001. Screening for the production of extracellular hydrolytic enzymes by non-Saccharomyces wine yeasts. J Appl Microbiol 91: 182-190., Rodriguez et al. 2004RODRÍGUEZ ME, LOPES CA, VAN BROOCK M, VALLÉS S, RAMÓN D & CABALLERO AC. 2004. Screening and typing of Patagonian wine yeasts for glycosidase activities. J Appl Microbiol 96: 84-95., Cordero-Otero et al. 2003CORDERO-OTERO RR, ÚBEDA-IRANZO JF, BRIONES-PÉREZ AI, POTGIETER NM, VILLENA A, PRETORIUS IS & VAN RENSURVHD P. 2003. Characterization of the β-glucosidase activity produced by enological strains of non-Saccharomyces yeasts. J Food Sci 68: 2564-2569., Arévalo-Villena et al. 2006ARÉVALO-VILLENA M, ÚBEDA-IRANZO JF, GUNDLLAPALLI SB, CORDERO-OTERO RR & BRIONES-PÉREZ AI. 2006. Characterization of an exocellular β-glucosidase from Debaryomyces pseudopolymorphus. Enzyme Microb Technol 39: 229-234.). Non-conventional yeasts studied in this work have also been explored as an alternative for microorganisms capable of producing the enzyme tannase which together with β-glucosidase are capable of degrading ellagitannins, which has multiple applications in the food and pharmaceutical industry. The activity on of both enzymes is very important due to their ability to produce ellagic acid (Márquez-López et al. 2020aMÁRQUEZ-LÓPEZ A, AYALA-FLORES F, MACÍAS-PURECO S, CHÁVEZ-PARGA MC, VALENCIA FLORES DC, MAYA-YESCAS R & GONZÁLEZ-HERNÁNDEZ JC. 2020a. Extract of Ellagitannins starting with Strawberries (Fragaria sp.) and Blackberries (Rubus sp.). J Food Sci Technolo 40(2): 430-439., bMÁRQUEZ-LÓPEZ A, RAMÍREZ-CONEJO JD, CHÁVEZ-PARGA MC, VALENCIA FLORES DC, ZAMUDIO JARAMILLO MA, GONZÁLEZ RODRÍGUEZ H & GONZÁLEZ-HERNÁNDEZ JC. 2020b. Comparative analysis of enzymatic activity of tannase in non-conventional yeasts to produce ellagic acid. J Food Sci Technol 40(3): 557-563.). It is also important to mention the enzymatic bioprospecting that is being carried out on these non-conventional yeasts native to spontaneous fermentation in the production of artisanal mezcal in the Etucúaro, Michoacán, as well as others that were isolated from sawmills in Ciudad Hidalgo, Michoacan.

Figure 5
β-glucosidase activity in non-conventional yeasts at 28 h of growth. 5a) Describe the comparison of all yeasts with each substrate is shown with glucose (column 1-7), cellulose (column 8-14) and sucrose (column 15-21). 5b) Comparison of each yeast independently for each substrate: 1) P. pastoris , 2) D. hansenii PYC 2968, 3) D. hansenii ISA 1510, 4) C. utilis, 5) P. kluyvery, 6) I. terrícola, 7) C. parapsilosis. Different letters mean statistical difference in Tukey test for α = 0.05, n = 2.

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Table II
Comparison of the β-glucosidase activity reported in non-conventional yeasts.

Our results obtained show a large standard deviation in the case of C. utilis grown on cellulose, as well as I. terricola grown on sucrose. However, the results obtained show that yeasts of the genus Candida and Pichia are producers of β-glucosidase, which have been reported with intracellular and extracellular activity (Rosi et al. 1994ROSI I, VINELLA M & DOMIZIO P. 1994. Characterization of β-glucosidase activity in yeasts of oenological origin. J Appl Bacteriol 77(5): 519-527.).

In addition, it can be seen that the enzymatic activity is closely correlated with growth, presenting the maximum during the stationary phase (hour 28 of growth kinetics). Glucose and sucrose were better inducers of β-glucosidase activity than cellulose which (Figure 5), regardless of its complex structure and large number of β-1-4 bonds, did not induce the presence of the enzyme of interest in non-conventional yeasts studied. However, it has been shown that other less complex sources, constituents of cellulose such as cellobiose, can act more effectively as an inducer (Villena et al. 2007VILLENA MA, IRANZO JFÚ & PÉREZ AIB. 2007: β-Glucosidase activity in wine yeasts: Application in enology. Enzyme Microb Technol 40: 420-425.). Cellulose has a complex structure, which can represent difficulties for hydrolysis due to effects such as the contact area between the enzyme and the molecule, the crystallinity of the cellulose, and the dimensions of the fiber pores. (Buschle-Diller et al. 1994BUSCHLE-DILLER G, ZERONIAN SH, PAN N & YOON MY. 1994. Enzymatic Hydrolysis of Cotton, Linen, Ramie, and Viscose Rayon Fabrics. Tex Res J 64: 270-279.).

In Figure 5, a multiple comparison procedure was applied to determine which means of the enzyme activity assays are significantly different. As a first part, the β-glucosidase activity of all the strains is compared with the glucose substrate (columns 1-7). when sucrose was used as a substrate (columns 8-14); finally, with cellulose as a substrate (columns 15-21) and as a second analysis, each yeast is compared independently for each substrate (Figure 5b).

The one-factor analysis of variance procedure for the β-glucosidase enzymatic activity with the evaluated substrates gives us the result that with glucose there are statistically significant differences between the means, where P. pastoris had the best β-glucosidase activity (Figure 5a). Likewise, it is described that with the presence of sucrose and cellulose used as substrates, when comparing the enzymatic activity between the studied strains, there are no statistically significant differences (Figure 5a).

Figure 5b describes the statistical analysis evaluating the differences of each strain against the different substrates used. The statistical analysis gives us the result that the strains D. hansenii PYC 2968, D. hansenii ISA 1510, C. parapsilosis and P. pastoris show statistically significant differences of the enzymatic activity when comparing the result obtained with glucose against cellulose as substrates. In Figures 5a and 5b it is described which strains show statistically significant differences at the 95.0% confidence level. The method used to discriminate between the means was Tukey’s Honestly Significant Difference (HSD) procedure.

CONCLUSION

The extracellular β-glucosidase activity was mainly presented in the Candida and Pichia strains, being the glucose and sucrose media the most capable for inducing the activity that showed maximum values with P. pastoris in glucose (0.1682±0.00 µmol/min mg protein), and C. utilis in cellulose (0.1129±0.1349 µmol/min mg of protein), and sucrose (0.0657±0.0214µmol/min mg protein). Additionally, I. terricola and P. kluyvery stood out in a qualitative cellulose degradation approach measured by Congo red method (9.60±0.04 mm and 9.20±0.05 mm respectively).

On the other hand, the minimum values were obtained for P. kluyvery in the medium with glucose (0.0512±0.00 µmol/min mg of protein) followed by C. parapsilosis in the medium with sucrose (0.0162±0.0036 µmol/min mg of protein) and D. hansenii PYC 2968 in the medium with cellulose (0.0038±0.0009 µmol/min mg of protein). These data indicate that P. pastoris and C. utilis have the potential as β-glucosidase producers for cellulose degradation, especially when growing under complex carbon sources favoring their introduction in renewable and more efficient processes.

ACKNOWLEDGMENTS

Partial donations from the call to Proyectos de Desarrollo e Innovación Tecnológica para 2022 del TecNM, with the project titled Análisis comparativo de la actividad enzimática de β-glucosidasa en levaduras no-convencionales bajo diferentes fuentes de sustrato (13590.22-P).

SUPPLEMENTARY MATERIAL

Figures S1, S2.

Table SI.

REFERENCES

AGUILAR-ZÁRATE P, CHÁVEZ-GONZÁLEZ ML, RODRÍGUEZ-HERRERA R & AGUILAR CN. 2013. Biotechnological production of gallic acid. Handbook on Gallic Acid: Natural Occurrences, Antioxidant Properties and Health Implications. Nova Science Publishers, Inc.
ARÉVALO-VILLENA M, ÚBEDA-IRANZO JF, GUNDLLAPALLI SB, CORDERO-OTERO RR & BRIONES-PÉREZ AI. 2006. Characterization of an exocellular β-glucosidase from Debaryomyces pseudopolymorphus. Enzyme Microb Technol 39: 229-234.
BELMARES R, CONTRERAS-ESQUIVEL JC, RODRÍGUEZ-HERRERA R, CORONEL AR & AGUILAR CN. 2004. Microbial production of tannase: An enzyme with potential use in food industry. Food Sci Technol 8: 57-864.
BENSEN ES, MARTIN SJ, LI M, BERMAN J & DAVIS DA. 2004. Transcriptional profiling in Candida albicans reveals new adaptive responses to extracellular pH and functions for Rim101p. Mol Microbiol 54: 1335-1351.
BRADFORD MM. 1976. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Chem 72(1-2): 248-254.
BUSCHLE-DILLER G, ZERONIAN SH, PAN N & YOON MY. 1994. Enzymatic Hydrolysis of Cotton, Linen, Ramie, and Viscose Rayon Fabrics. Tex Res J 64: 270-279.
CORDERO-OTERO RR, ÚBEDA-IRANZO JF, BRIONES-PÉREZ AI, POTGIETER NM, VILLENA A, PRETORIUS IS & VAN RENSURVHD P. 2003. Characterization of the β-glucosidase activity produced by enological strains of non-Saccharomyces yeasts. J Food Sci 68: 2564-2569.
FERNÁNDEZ-GONZÁLEZ M, DI STEFANO R & BRIONES AI. 2003. Hydrolysis and transformation of terpene glycosides from Muscat must by different yeast species. Food Microbiol 20: 35-41.
GAITAN BDM & PÉREZ PLI. 2007. Aislamiento y evaluación de microorganismos celulolíticos a partir de residuos vegetales frescos y en compost generados en un cultivo de crisantemo (Dendranthema grandiflora). Tesis de Microbiología Industrial. Facultad de Ciencias. Pontificia Universidad Javeriana. Bogota, Colombia.
GIBBS PA, SEVIOUR RJ & SCHMID F. 2000. Growth of Filamentous Fungi in Submerged Culture: Problems and Possible Solutions. Crit Rev Biotechnol 20(1): 17-48.
GONZÁLEZ-HERNÁNDEZ JC, ALCÁNTAR-COVARRUBIAS MA & CORTÉS-ROJO C. 2015. Producción de trehalosa a partir de levaduras no-convencionales. Rev Mex Ing Quím 4(1): 11-23.
GONZÁLEZ-POMBO P, FARIÑA L, CARRAU F & BATISTA-VIERA FBM. 2011. A novel extracellular β-glucosidase from Issatchenkia terricola: isolation, immobilization and application for aroma enhancement of white Muscat wine. Process Biochem 46(1): 385-389.
GRANADOS L & VALDERRAMA J. 2003. Evaluación de la actividad proteolítica y amilolítica de Actinomycetes termofílicos aislados a partir de pilas de composta. Tesis de Microbiología Industrial. Facultad de ciencias. Pontificia Universidad Javeriana. Bogota, Colombia.
GUNATA YZ, BAYONOVE CL, ARNAUD A & GALZY P. 1990. Hydrolysis of grape monoterpenyl glycosides by Candida molischiana and Candida wickerhamii b-glucosidases. J Sci Food Agric 50: 499-506.
HUANG W, NIU H, LI Z, HE Y, GONG W & GONG G. 2008. Optimization of ellagic acid production from ellagitannins by co-culture and correlation between its yield and activities of relevant enzymes. Bioresour Technol 99(4): 769-775.
LAMB TM & MITCHELL AP. 2003. The transcription factor Rim101p governs ion tolerance and cell differentiation by direct repression of the regulatory genes NRG1 and SMP1 in Saccharomyces cerevisiae. Mol Cell Biol 23: 677-686.
LU W, WANG H, YANG Z & NIE Y. 2005. Isolation and characterización of mesophilic cellulose-degrading bacteria from flower stalks-vegetable waste co-composting system. J Gen Appl Microbiol 51: 353-360.
MÁRQUEZ-LÓPEZ A, AYALA-FLORES F, MACÍAS-PURECO S, CHÁVEZ-PARGA MC, VALENCIA FLORES DC, MAYA-YESCAS R & GONZÁLEZ-HERNÁNDEZ JC. 2020a. Extract of Ellagitannins starting with Strawberries (Fragaria sp.) and Blackberries (Rubus sp.). J Food Sci Technolo 40(2): 430-439.
MÁRQUEZ-LÓPEZ A, RAMÍREZ-CONEJO JD, CHÁVEZ-PARGA MC, VALENCIA FLORES DC, ZAMUDIO JARAMILLO MA, GONZÁLEZ RODRÍGUEZ H & GONZÁLEZ-HERNÁNDEZ JC. 2020b. Comparative analysis of enzymatic activity of tannase in non-conventional yeasts to produce ellagic acid. J Food Sci Technol 40(3): 557-563.
MATEO JJ & MAICAS S. 2016. Application of non-saccharomyces yeasts to wine-making process. Fermentation 2(14): 2030014.
MCMAHON H, ZOECKLEIN BW, FUGELSANG K & JASINSKI Y. 1999. Quantication of glycosidase activities in selected yeasts and lactic acid bacteria. Journal Indian Microbiology Biotechnology 23: 198-203.
MILLER GL. 1959. Use of Dinitrosalicylic Acid Reagent for Determination of Reducing Sugar. Anal Chem 31(3): 426-428.
MOHANRAM S, AMAT D, CHOUDHARY J, ARORA A & NAIN L. 2013. Novel perspectives for evolving enzyme cocktails for lignocellulose hydrolysis in biorefineries. Sustain Chem Process 1: 15.
POINTING CA. 1999. Qualitative methods for the determination of lignocellulotyc enzyme production by tropical fungi. Funga Divers 2: 17-33.
RODRÍGUEZ ME, LOPES CA, VAN BROOCK M, VALLÉS S, RAMÓN D & CABALLERO AC. 2004. Screening and typing of Patagonian wine yeasts for glycosidase activities. J Appl Microbiol 96: 84-95.
ROSI I, VINELLA M & DOMIZIO P. 1994. Characterization of β-glucosidase activity in yeasts of oenological origin. J Appl Bacteriol 77(5): 519-527.
SERRANO R, KIELLANDBRANDT MC & FINK GR. 1986. Yeast Plasma-Membrane Atpase Is Essential for Growth and Has Homology with (Na++K+), K+- and Ca-2+-Atpases. Nature 319(6055): 689-693.
SHI B, HE Q, YAO K, HUANG W & LI Q. 2005. Production of ellagic acid from degradation of valonea tannins by Aspergillus niger and Candida utilis. J Chem Technol Biotechnol 80(10): 1154-1159.
SIM SL & HANG YD. 1996. Research Note: Sauerkraut Brine: A potential substrate for production of yeast β-Glucosidase. J Food Sci Technol 29(4): 365-367.
STRAUSS MLA, JOLLY NP, LAMBRECHTS MG & VAN RENSBURG P. 2001. Screening for the production of extracellular hydrolytic enzymes by non-Saccharomyces wine yeasts. J Appl Microbiol 91: 182-190.
TEATHER RM & WOOD PJ. 1982. Use of congo red-polysaccharide interaction in enumeration and characterization of cellulolytic bacteria from the bovine rumen. Appl Environ Biotechnol 43(4): 777-780.
TURAN Y & ZHENG M. 2005. Purification and characterization of an intracellular β-glucosidase from Methylotropic yeast Pichia pastoris. Biochem (Moscow) 70(12): 1363-1368.
VILLENA MA, IRANZO JFÚ & PÉREZ AIB. 2007: β-Glucosidase activity in wine yeasts: Application in enology. Enzyme Microb Technol 40: 420-425.
WAGNER JM & ALPER HS. 2016. Synthetic biology and molecular genetics in non-conventional yeasts: Current tools and future advances. Fungal Genet Biol 89: 126-136.
ZHANG HP, HIMMEL ME & MIELENZ JR. 2006. Outlook for cellulase improvent: Screening and selection strategies. Biotechnol Adv 24: 452-481.

Publication Dates

Publication in this collection
01 Dec 2023
Date of issue
2023

History

Received
12 Dec 2022
Accepted
8 May 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] AGUILAR-ZÁRATE P, CHÁVEZ-GONZÁLEZ ML, RODRÍGUEZ-HERRERA R & AGUILAR CN. 2013. Biotechnological production of gallic acid. Handbook on Gallic Acid: Natural Occurrences, Antioxidant Properties and Health Implications. Nova Science Publishers, Inc.

[2] ARÉVALO-VILLENA M, ÚBEDA-IRANZO JF, GUNDLLAPALLI SB, CORDERO-OTERO RR & BRIONES-PÉREZ AI. 2006. Characterization of an exocellular β-glucosidase from Debaryomyces pseudopolymorphus. Enzyme Microb Technol 39: 229-234.

[3] BELMARES R, CONTRERAS-ESQUIVEL JC, RODRÍGUEZ-HERRERA R, CORONEL AR & AGUILAR CN. 2004. Microbial production of tannase: An enzyme with potential use in food industry. Food Sci Technol 8: 57-864.

[4] BENSEN ES, MARTIN SJ, LI M, BERMAN J & DAVIS DA. 2004. Transcriptional profiling in Candida albicans reveals new adaptive responses to extracellular pH and functions for Rim101p. Mol Microbiol 54: 1335-1351.

[5] BRADFORD MM. 1976. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Chem 72(1-2): 248-254.

[6] BUSCHLE-DILLER G, ZERONIAN SH, PAN N & YOON MY. 1994. Enzymatic Hydrolysis of Cotton, Linen, Ramie, and Viscose Rayon Fabrics. Tex Res J 64: 270-279.

[7] CORDERO-OTERO RR, ÚBEDA-IRANZO JF, BRIONES-PÉREZ AI, POTGIETER NM, VILLENA A, PRETORIUS IS & VAN RENSURVHD P. 2003. Characterization of the β-glucosidase activity produced by enological strains of non-Saccharomyces yeasts. J Food Sci 68: 2564-2569.

[8] FERNÁNDEZ-GONZÁLEZ M, DI STEFANO R & BRIONES AI. 2003. Hydrolysis and transformation of terpene glycosides from Muscat must by different yeast species. Food Microbiol 20: 35-41.

[9] GAITAN BDM & PÉREZ PLI. 2007. Aislamiento y evaluación de microorganismos celulolíticos a partir de residuos vegetales frescos y en compost generados en un cultivo de crisantemo (Dendranthema grandiflora). Tesis de Microbiología Industrial. Facultad de Ciencias. Pontificia Universidad Javeriana. Bogota, Colombia.

[10] GIBBS PA, SEVIOUR RJ & SCHMID F. 2000. Growth of Filamentous Fungi in Submerged Culture: Problems and Possible Solutions. Crit Rev Biotechnol 20(1): 17-48.

[11] GONZÁLEZ-HERNÁNDEZ JC, ALCÁNTAR-COVARRUBIAS MA & CORTÉS-ROJO C. 2015. Producción de trehalosa a partir de levaduras no-convencionales. Rev Mex Ing Quím 4(1): 11-23.

[12] GONZÁLEZ-POMBO P, FARIÑA L, CARRAU F & BATISTA-VIERA FBM. 2011. A novel extracellular β-glucosidase from Issatchenkia terricola: isolation, immobilization and application for aroma enhancement of white Muscat wine. Process Biochem 46(1): 385-389.

[13] GRANADOS L & VALDERRAMA J. 2003. Evaluación de la actividad proteolítica y amilolítica de Actinomycetes termofílicos aislados a partir de pilas de composta. Tesis de Microbiología Industrial. Facultad de ciencias. Pontificia Universidad Javeriana. Bogota, Colombia.

[14] GUNATA YZ, BAYONOVE CL, ARNAUD A & GALZY P. 1990. Hydrolysis of grape monoterpenyl glycosides by Candida molischiana and Candida wickerhamii b-glucosidases. J Sci Food Agric 50: 499-506.

[15] HUANG W, NIU H, LI Z, HE Y, GONG W & GONG G. 2008. Optimization of ellagic acid production from ellagitannins by co-culture and correlation between its yield and activities of relevant enzymes. Bioresour Technol 99(4): 769-775.

[16] LAMB TM & MITCHELL AP. 2003. The transcription factor Rim101p governs ion tolerance and cell differentiation by direct repression of the regulatory genes NRG1 and SMP1 in Saccharomyces cerevisiae. Mol Cell Biol 23: 677-686.

[17] LU W, WANG H, YANG Z & NIE Y. 2005. Isolation and characterización of mesophilic cellulose-degrading bacteria from flower stalks-vegetable waste co-composting system. J Gen Appl Microbiol 51: 353-360.

[18] MÁRQUEZ-LÓPEZ A, AYALA-FLORES F, MACÍAS-PURECO S, CHÁVEZ-PARGA MC, VALENCIA FLORES DC, MAYA-YESCAS R & GONZÁLEZ-HERNÁNDEZ JC. 2020a. Extract of Ellagitannins starting with Strawberries (Fragaria sp.) and Blackberries (Rubus sp.). J Food Sci Technolo 40(2): 430-439.

[19] MÁRQUEZ-LÓPEZ A, RAMÍREZ-CONEJO JD, CHÁVEZ-PARGA MC, VALENCIA FLORES DC, ZAMUDIO JARAMILLO MA, GONZÁLEZ RODRÍGUEZ H & GONZÁLEZ-HERNÁNDEZ JC. 2020b. Comparative analysis of enzymatic activity of tannase in non-conventional yeasts to produce ellagic acid. J Food Sci Technol 40(3): 557-563.

[20] MATEO JJ & MAICAS S. 2016. Application of non-saccharomyces yeasts to wine-making process. Fermentation 2(14): 2030014.

[21] MCMAHON H, ZOECKLEIN BW, FUGELSANG K & JASINSKI Y. 1999. Quantication of glycosidase activities in selected yeasts and lactic acid bacteria. Journal Indian Microbiology Biotechnology 23: 198-203.

[22] MILLER GL. 1959. Use of Dinitrosalicylic Acid Reagent for Determination of Reducing Sugar. Anal Chem 31(3): 426-428.

[23] MOHANRAM S, AMAT D, CHOUDHARY J, ARORA A & NAIN L. 2013. Novel perspectives for evolving enzyme cocktails for lignocellulose hydrolysis in biorefineries. Sustain Chem Process 1: 15.

[24] POINTING CA. 1999. Qualitative methods for the determination of lignocellulotyc enzyme production by tropical fungi. Funga Divers 2: 17-33.

[25] RODRÍGUEZ ME, LOPES CA, VAN BROOCK M, VALLÉS S, RAMÓN D & CABALLERO AC. 2004. Screening and typing of Patagonian wine yeasts for glycosidase activities. J Appl Microbiol 96: 84-95.

[26] ROSI I, VINELLA M & DOMIZIO P. 1994. Characterization of β-glucosidase activity in yeasts of oenological origin. J Appl Bacteriol 77(5): 519-527.

[27] SERRANO R, KIELLANDBRANDT MC & FINK GR. 1986. Yeast Plasma-Membrane Atpase Is Essential for Growth and Has Homology with (Na++K+), K+- and Ca-2+-Atpases. Nature 319(6055): 689-693.

[28] SHI B, HE Q, YAO K, HUANG W & LI Q. 2005. Production of ellagic acid from degradation of valonea tannins by Aspergillus niger and Candida utilis. J Chem Technol Biotechnol 80(10): 1154-1159.

[29] SIM SL & HANG YD. 1996. Research Note: Sauerkraut Brine: A potential substrate for production of yeast β-Glucosidase. J Food Sci Technol 29(4): 365-367.

[30] STRAUSS MLA, JOLLY NP, LAMBRECHTS MG & VAN RENSBURG P. 2001. Screening for the production of extracellular hydrolytic enzymes by non-Saccharomyces wine yeasts. J Appl Microbiol 91: 182-190.

[31] TEATHER RM & WOOD PJ. 1982. Use of congo red-polysaccharide interaction in enumeration and characterization of cellulolytic bacteria from the bovine rumen. Appl Environ Biotechnol 43(4): 777-780.

[32] TURAN Y & ZHENG M. 2005. Purification and characterization of an intracellular β-glucosidase from Methylotropic yeast Pichia pastoris. Biochem (Moscow) 70(12): 1363-1368.

[33] VILLENA MA, IRANZO JFÚ & PÉREZ AIB. 2007: β-Glucosidase activity in wine yeasts: Application in enology. Enzyme Microb Technol 40: 420-425.

[34] WAGNER JM & ALPER HS. 2016. Synthetic biology and molecular genetics in non-conventional yeasts: Current tools and future advances. Fungal Genet Biol 89: 126-136.

[35] ZHANG HP, HIMMEL ME & MIELENZ JR. 2006. Outlook for cellulase improvent: Screening and selection strategies. Biotechnol Adv 24: 452-481.

Yeasts	Glucose		Sucrose		Cellulose		R² Logistic Model
Yeasts	µ (h ^-1 )	t _D (h)	µ (h ^-1 )	t _D (h)	µ (h ^-1 )	t _D (h)	G	S	C
D. hansenii PYC 2968	0.76±0.03^C	0.91±0.04	0.56±0.02^B	1.23±0.04	0.37±0.06^A	1.91±0.33	0.85	0.98	0.97
C. utilis	0.55±0.11^A	1.28±0.25	0.64±0.02^B	1.08±0.04	0.42±0.04^C	1.67±0.16	0.85	0.98	0.96
C. parapsilosis	0.56±0.00^A	1.24±0.01	0.50±0.13^B	1.44±0.39	0.40±0.05^C	1.77±0.24	0.92	0.92	0.96
P. kluyvery	0.57±0.00^BC	1.22±0.01	0.44±0.01^AC	1.59±0.04	0.32±0.02^AB	2.16±0.11	0.96	0.98	0.72
I. terricola	1.38±0.10^BC	0.50±0.04	0.52±0.22^A	1.45±0.60	0.37±0.12^A	1.98±0.63	0.77	0.91	0.74
P. pastoris	0.45±0.02^A	1.24±0.08	0.43±0.01^B	1.62±0.06	0.24±0.09^C	3.08±1.14	0.83	0.98	0.91
D. hansenii ISA 1510	0.58±0.27^A	1.35±0.63	0.41±0.00^B	1.69±0.01	0.21±0.02^C	3.28±0.29	0.78	0.99	0.92

Microorganism	β-glucosidase activity			References
C. molischiana	0.0048^a			Gunata et al. (1990)GUNATA YZ, BAYONOVE CL, ARNAUD A & GALZY P. 1990. Hydrolysis of grape monoterpenyl glycosides by Candida molischiana and Candida wickerhamii b-glucosidases. J Sci Food Agric 50: 499-506..
C. wickerhamii	0.0002^a
D. hansenii	0.121^b			Yanai & Sato (1999).
Aurebasidium pallulans	2279^c
C. guillermondii	230^c			McMahom et al. (1999)MCMAHON H, ZOECKLEIN BW, FUGELSANG K & JASINSKI Y. 1999. Quantication of glycosidase activities in selected yeasts and lactic acid bacteria. Journal Indian Microbiology Biotechnology 23: 198-203..
C. parapsilosis	1313^c
H. anomala	587^c
K. apiculata	621^c
P. guillermondi	105^c
C. molischiana	0.0031^a			Fernández-González et al. (2003)FERNÁNDEZ-GONZÁLEZ M, DI STEFANO R & BRIONES AI. 2003. Hydrolysis and transformation of terpene glycosides from Muscat must by different yeast species. Food Microbiol 20: 35-41..
D. hansenii	0.0000483^a
H. uvarum	0.0000217^a
M. pulcherrima	0.000205^a
K. thermotolerans	0.0000217^a
P. kluyveri	0.0000233^a
P. pastoris	0.11^b			Turan & Zheng (2005)TURAN Y & ZHENG M. 2005. Purification and characterization of an intracellular β-glucosidase from Methylotropic yeast Pichia pastoris. Biochem (Moscow) 70(12): 1363-1368..
I. terrícola	0.024^b			González-Pombo et al. (2011)GONZÁLEZ-POMBO P, FARIÑA L, CARRAU F & BATISTA-VIERA FBM. 2011. A novel extracellular β-glucosidase from Issatchenkia terricola: isolation, immobilization and application for aroma enhancement of white Muscat wine. Process Biochem 46(1): 385-389..
C. utilis	0.12^b			Sim & Hang (1996)SIM SL & HANG YD. 1996. Research Note: Sauerkraut Brine: A potential substrate for production of yeast β-Glucosidase. J Food Sci Technol 29(4): 365-367..
Microorganism	β-glucosidase activity			References
	Glucose^b	Sucrose^b	Cellulose ^b
D. hansenii PYC 2968	0.0523±0.0072	0.0516±0.0102	0.0038±0.0009	This study
C. utilis	0.0734±0.0000	0.0657±0.0214	0.1129±0.1349	This study
C. parapsilosis	0.0768±0.0103	0.0162±0.0036	0.0334±0.0230	This study
P. kluyvery	0.0512±0.0000	0.0468±0.0150	0.0189±0.0000	This study
I. terricola	0.0544±0.0000	0.0558±0.0659	0.0258±0.0000	This study
P. pastoris	0.1682±0.0000	0.0635±0.0027	0.0077±0.0042	This study
D. hansenii ISA 1510	0.0548±0.0047	0.0365±0.0162	0.0071±0.0029	This study

Brasil

Brasil

Comparative analysis of β-glucosidase activity in non-conventional yeasts

Abstract

INTRODUCTION

MATERIALS AND METHODS

Non-conventional Yeastes and media

Cellulolytic activity and halo essays by Congo Red

Growth kinetics

Analytical techniques

β -glucosidase activity

Statistical analysis

RESULTS

Cellulolytic activity

Growth kinetics

pH

Reducing sugars

β-glucosidase activity

DISCUSSION

CONCLUSION

ACKNOWLEDGMENTS

SUPPLEMENTARY MATERIAL

REFERENCES

Publication Dates

History