BGL production and growth of T. amestolkiae in media with raw glycerol
The ascomycete T. amestolkiae has been proven as an excellent producer of robust and efficient cellulolytic enzymes in media with different carbon sources [9]. This finding suggested the convenience of testing cheaper carbon sources to obtain these cocktails, since they are rich in β-glucosidases, the key enzymes for cellulose saccharification.
In this work, we study the use of different concentrations of raw glycerol, an abundant waste generated from biodiesel production, to produce added-value enzyme cocktails. To analyze the potential of this carbon source, we followed the evolution of fungal growth and the extracellular levels of β-glucosidase over 10 day-old cultures (240 h). As observed in Fig. 1A, T. amestolkiae cultures in unbuffered media reached maximal biomass values around 24 h independently of the glycerol concentration assayed, although total biomass was higher as the glycerol concentration increased. The highest β-glucosidase levels were detected in the cultures containing 1% or 2% glycerol (Fig. 1B). BGL levels were low in the first 24–48 h, and then they started to raise uninterruptedly at high rate between 72 h and 168 h. Surprisingly, both cultures produced around 8 U/mL at the final incubation time, despite fungal biomass was higher with 2% glycerol. Searching for an explanation to this result, it was observed that the pH was more acidic in the culture with 2% glycerol (pH 5) than in the other cultures (pH 6-6.5). The acidification was detected at 168 h and maintained until the end of the incubation period.
Thus, to investigate the effect of pH on BGL production, we repeated the experiment buffering all media with phosphate pH 6 to maintain the pH constant across the incubation period. In these conditions, BGL activity and fungal growth went in parallel, and the highest values for both were detected in cultures with 2% glycerol (Fig. 2A). It should also be noticed that the total amount of secreted proteins detected in 2% glycerol unbuffered cultures was considerably lower than in the buffered ones (0.10 and 0.17 mg/mL, respectively). These results suggest that pH should be strictly controlled in the cultures, since its value is related to the levels of secreted proteins. No significant differences were found in buffered and unbuffered cultures with 0.5 and 1% glycerol, where the pH was maintained in a pH range 6-6.5.
On the other hand, these results confirm that T. amestolkiae does not require any specific inducer (cellulosic or non-cellulosic) to produce high amounts of β-glucosidases, as previously reported. This is probably due to the presence of BGL-3, an efficient β-glucosidase secreted under carbon starvation conditions [11]. BGL-3 is a β-1,4 glucosidase with a prominent activity on β-1,3 glucans. The high levels of this protein detected during secondary metabolism in the cultures may be due to its activity degrading the β-1,3-glucan released from fungal cell wall during autolysis. As expected, the amount of other cellulolytic activities like avicelase or β-1,4-endoglucanase was negligible (data not shown), since these enzymes are usually released upon induction by cellulosic substrates.
Only a handful of studies have reported the production of fungal β-glucosidases using glycerol as carbon source. For Penicillium echinulatum, glycerol was the preferred carbon source over cellulose, sugar cane bagasse (pretreated by steam explosion) or glucose [12]. Aspergillus niger NRRL 3112 could produce considerable amounts of this activity when grown on wheat bran and glycerol as co-substrates [13]. In other cases, the use of glycerol was not suitable for β-glucosidase production, as reported in Penicillium funiculosum [14]. Trichoderma reesei has been the most used fungus for producing cellulolytic cocktails, although it is well documented that the amount of β-glucosidase released by this fungus is insufficient for efficient hydrolysis of lignocellulosic biomass [15]. In this sense, one of the main advantages of the use of Aspergillus spp., Penicillium spp. or Talaromyces spp. lies on their higher secretion of β-glucosidase activity [15]. Many published reports allow to compare its production among these fungal genera, mainly using crystalline cellulose as carbon source. Different Aspergillus sp. secreted between 0.5 U/mL and 2.5 U/mL of β-glucosidase[16; 17][16]. Penicillium species, like Penicillium brasilianum or Penicillium decumbens, reached a total activity of 3.5 U/mL and 2.39 U/mL, respectively [18; 19]. Higher β-glucosidase levels, from 10 to 150 U/mL, have been reported in strains of P. funiculosum, Penicillium occitanis or Penicillium verriculosum [20; 21; 14] using cellulosic inducers. It should be noted that the amounts of BGL observed in T. amestolkiae cultures in media with raw glycerol as the sole carbon source are among the highest reported to date. The fact that this high production was achieved using a by-product of biodiesel industry makes it even more interesting.
Glycerol consumption was monitored and related with the increase of BGL activity (Fig. 2B). In cultures with 0.5% glycerol the depletion of carbon source occurred in 24 h, while in those with 1% and 2% it took around 48 h. Low β-glucosidase levels were detected before glycerol exhaustion, but the activity started to raise slowly once consumed, and faster when carbon starvation conditions were fully stablished, expanding over time. The data in Fig. 2B indicate that the maximal exploitation of glycerol for BGL production was obtained with 2% glycerol, so we chose this culture as the best model to produce BGL-rich cocktails.
The secretion of β-glucosidases in aged fungal cultures has been scarcely studied, although it would be interesting to know to what extent their production under carbon starvation is common among filamentous fungi. Some authors have reported the production of glycosyl hydrolases after carbon depletion in cultures of A. niger [22; 23], but their finding was not discussed as a potential way to produce these enzymes. In any case, the versatility of T. amestolkiae to produce high levels of BGLs from different carbon sources, including some important industrial residues, should be exploited.
Fungal secretome analysis
An extracellular proteomic analysis of 7-day-old cultures was carried out to elucidate the protein profiles of T. amestolkiae cultures with 1% raw glycerol. The samples were subjected to tryptic digestion and LC–MS/MS of the whole peptide mixtures produced. The number of proteins identified was 148, similar to that reported in cultures with glucose or cellulosic substrates [9].
According to KOG, the functional role of most of the proteins identified in cultures with 1% raw glycerol was related to carbohydrate metabolism and transport (55.0%), followed by enzymes involved in amino acid metabolism and transport (Table 1). These data also agree with those previously published for T. amestolkiae secretomes with glucose as carbon source [9].
Table 1
Functional classification of the proteins identified in the secretome of 7-day old T. amestolkiae cultures with raw glycerol as carbon source, compared to those obtained in the same medium with glucose (de Eugenio et al., 2017).
| % PSM |
| Glycerol | Glucose |
A- RNA processing and modification | 0.63 | 0.22 |
C- Energy production and conversion | 2.72 | 4.90 |
E- Amino Acid metabolism and transport | 13.11 | 10.38 |
F- Nucleotide metabolism and transport | 0.74 | 1.42 |
G- Carbohydrate metabolism and transport | 55.01 | 65.16 |
I -Lipid metabolism | 0.09 | 0.17 |
M- Cell wall/membrane/envelop biogenesis | 0.77 | 3.61 |
O- Post-translational modification. protein turnover. chaperone functions | 1.96 | 1.71 |
Q- Secondary Structure | 2.55 | 0.91 |
R- General Functional Prediction only | 4.81 | 1.89 |
S- Function Unknown | 5.79 | 3.71 |
T- Signal Transduction | 4.13 | 4.86 |
As the main objective of this work was to produce BGLs from contaminated glycerol waste, we started our analysis classifying the CAZymes (carbohydrate active enzymes), finding 80 out of 148 detected proteins (54%). Among them, the most abundant were glycosyl hydrolases (GHs) from GH3, GH15, GH31 and GH55 families (Table 2). It is worth noting that GH15 enzymes were predominant in cultures with glucose as carbon source [9], while in media with glycerol GH3 proteins were the most abundant. Family GH3 is normally associated with enzymes degrading polysaccharides from lignocellulosic biomass, including many β-glucosidases, which supports the suitability of using this carbon source for β-glucosidase production. As expected, BGL-3 was found in the studied secretome (Table 3). As already mentioned, this enzyme is secreted under carbon starvation [11] but other GHs potentially related with carbon depletion were also detected. This is the case of glucoamylases (GH15), α-glucosidases (GH31), and exo-β-1,3-glucanases (GH55), related to the fungal autophagy process, since 1,3-β-glucans and 1,4-α-glucan are components of the cell wall of many Talaromyces species [24]. Besides, it is noticeable that some of the most abundant proteins are related with fungal autolysis processes. For example, cathepsin, which is detected in every condition, is a well-known protease that could be used by T. amestolkiae for degrading proteins and using its components as nutrients. The amino acids produced by cathepsin can be utilized by glutaminase, which has been related with glutamine metabolism under starvation conditions, when no other carbon source is present in the medium.
Table 2
Glycosyl hydrolase families identified in secretomes from 7-day-old T. amestolkiae cultures growing in raw glycerol, compared to those obtained in the same medium with glucose as carbon source [9].
| % PSM |
GH family | Glycerol | Glucose |
GH2 | 3.2 | 1.7 |
GH3 | 16.6 | 16.3 |
GH13 | 3.0 | 4.3 |
GH15 | 10.1 | 28.4 |
GH18 | 2.8 | 0.6 |
GH20 | 3.7 | 4.8 |
GH27 | 2.1 | 1.7 |
GH31 | 8.6 | 11.8 |
GH35 | 2.7 | 1.8 |
GH55 | 8.1 | 3.9 |
GH71 | 4.0 | 0.1 |
GH72 | 3.2 | 1.3 |
GH92 | 5.3 | 1.1 |
GH127 | 3.6 | 3.2 |
Table 3
Most abundant extracellular proteins identified in the T. amestolkiae secretome obtained from 7-day-old cultures growing in raw glycerol. BGL-3 is indicated in bold.
| Accession ID | % PSM (average) | Predicted protein function | Cazyme family | Mw (kDa) |
| g377 (BGL-3) | 7.09 | beta-glucosidase | GH3 | 88.7 |
g3995 | 6.47 | Glutaminase | - | 76.4 |
g8295 | 3.59 | alpha-glucosidase | GH31 | 98.6 |
g2158 | 3.28 | Glucoamylase | GH15 | 65.2 |
g9324 | 3.18 | Exo-beta-1,3-glucanase | GH55 | 84.3 |
g2140 | 2.50 | Glucoamylase | GH15 | 67.7 |
g5915 | 2.23 | non-reducing end β-L-arabinofuranosidase | GH127 | 68.8 |
g4076 | 2.00 | hexosaminidase | GH20 | 67.9 |
g216 | 1.77 | neutral/alkaline nonlysosomal ceramidase | - | 160.0 |
g9148 | 1.58 | catalase | - | 79.1 |
Regarding β-glucosidases, the most important result was the confirmation of the presence of BGL-3 as the most abundant extracellular protein. This is in good agreement with our previous results describing its production upon carbon exhaustion [9]. Besides, one GH1, previously characterized [25], and 4 GH3 β-glucosidases were also identified (Table 4). This profusion of β-glucosidases could contribute to explain why this activity was so high in this medium, as compared with other conditions.
Table 4
Main hypothetical BGLs detected identified in the T. amestolkiae secretome obtained from 7-day-old cultures with raw glycerol as carbon source.
| Accession ID | % PSM (average) | Cazyme family | Mw (kDa) | |
| g377 (BGL-3) | 7.09 | GH3 | 88.7 | |
g9150 | 1.54 | GH3 | 86.5 | |
g8384 | 0.85 | GH1 | 68.1 | |
g6857 | 0.79 | GH3 | 109 | |
g3139 | 0.30 | GH3 | 93.6 | |
| g6753 | 0.09 | GH3 | 81.8 | |
In summary, the proteomic analysis of T. amestolkiae growing in raw glycerol confirmed the presence of BGL-3 and revealed that other interesting enzymes, including different β-glucosidases, can also be obtained for different biotechnological applications by exploiting the carbon starvation metabolism of T. amestolkiae.
Wheat straw saccharification
To check the efficiency of the novel enzyme cocktail obtained in this work for saccharification of lignocellulosic biomass, we used it as supplement of β-glucosidase activity for Celluclast 1.5L (a basal cellulolytic preparation, deficient in this activity),.
Since lignocellulosic substrates have different characteristics, the most effective pretreatment and enzyme cocktail should be used, considering the properties of each raw material. Wheat straw is one of the most important agricultural residues worldwide. According to Iskalieva et al. [26], it is mainly composed of cellulose (38.8%), hemicelluloses (39.5%) and lignin (17.1%). In the present work, three different pretreatments were used to make wheat straw cellulose more accessible: steam explosion (SE), steam explosion in the presence of dilute sulfuric acid (AcSE) and alkaline pretreatment (AP). Steam-explosion is one of the most commonly used method for lignocellulose pretreatment, deconstructing and modifying part of the lignin, and solubilizing hemicellulose [27; 28]. However, although cellulose is more accessible in the steam exploded biomass, compounds derived from the partial hydrolysis of sugars and lignin remain embedded, producing adverse effects on downstream processes, including enzyme inhibition [29]. The use of dilute sulfuric acid could theoretically avoid this problem, since it helps to remove a bigger part of the lignin, but some of the polymer is always present in the material. On the other hand, the alkaline pretreatment with NaOH has been reported to increase cellulose digestibility by inducing a big reduction of the lignin content [30]. These pretreatments affect differently the composition of the material used for saccharification (Table 5). In the case of alkaline pretreatment, most lignin was solubilized and removed, leaving a solid fraction enriched in polysaccharides. The two steam explosion treatments give wheat straw slurries with different cellulose and hemicellulose content. The AcSE treatment (dilute sulfuric acid) affects more strongly hemicellulose and lignin, forming compounds that produce adverse effects on downstream processes [31]. The results of saccharification of pretreated wheat straw can be seen in Fig. 3. The combination of Celluclast 1.5L with the T. amestolkiae cocktail improved the saccharification yield of steam exploded wheat straw (with or without sulfuric acid), compared with Celluclast 1.5L alone, reaching cellulose conversion of 65% for SE and 86% of for AcSE. The commercial Celluclast 1.5L contains an array of cellulolytic and hemicellulolytic activities in addition to BGL, which could theoretically improve saccharification. However, cellulose degradation with this cocktail was 41% for SE and 53% for AcSE.
Table 5
Main components of wheat straw pretreated by steam explosion in water (SE), steam explosion with dilute sulfuric acid (AcSE), or alkaline pretreatment (AP).
COMPONENT | SE | AcSE | AP |
Cellulose | 49.0% | 43.6% | 71.8% |
Hemicellulose | 15.4% | 17.1% | 24.1% |
Lignin | 35.6% | 39.3% | 4.1% |
On the other hand, the saccharification of alkali-pretreated wheat straw was similar with both cocktails (86% for only Celluclast and 89% when supplemented with β-glucosidase from T. amestolkiae). One possible reason for this is the virtual lack of lignin in the alkali-pretreated wheat straw. It has been reported that lignin could trigger an irreversible cellulase inactivation, even when using pretreated lignocellulosic biomass, by two possible mechanisms: i) forming a physical barrier that prevents enzyme access, and ii) by non-productively binding cellulolytic enzymes [27; 32]. The non-productive binding of enzymes to lignin is recognized as a problem to overcome to improve the saccharification efficiency of pretreated lignocellulosic biomass to fermentable sugars. A feasible explanation for our results is that the enzymes from the BGL-rich cocktails from T. amestolkiae were better than those contained in Celluclast 1.5L, avoiding the non-productive binding to lignin. This observation perfectly correlates with some studies that suggest that β-glucosidases and xylanases could avoid non-productive binding to lignin better than other cellulolytic enzymes [33]. Besides, it is remarkable that BGL-3, the most abundant cellulase in T. amestolkiae cocktails, possess a fibronectin III domain (FnIII) [11]. Lima et al. [34], postulated that the FnIII domain strongly interacts with lignin fragments, preventing unproductive binding of cellulases to the lignin. Taking this into consideration, BGL-3 rich cocktails may be advantageous for saccharification of pretreated residues where lignin is present, representing an effective and cheap alternative to current commercial enzymatic preparations.