Marcelo Ventura Rubio

A novel thermostable xylanase GH10 from Malbranchea pulchella expressed in Aspergillus nidulans with potential applications in biotechnology

BackgroundThe search for novel thermostable xylanases for industrial use has intensified in recent years, and thermophilic fungi are a promising source of useful enzymes. The present work reports the heterologous expression and biochemical characterization of a novel thermostable xylanase (GH10) from the thermophilic fungus Malbranchea pulchella, the influence of glycosylation on its stability, and a potential application in sugarcane bagasse hydrolysis.ResultsXylanase MpXyn10A was overexpressed in Aspergillus nidulans and was active against birchwood xylan, presenting an optimum activity at pH 5.8 and 80°C. MpXyn10A was 16% glycosylated and thermostable, preserving 85% activity after 24 hours at 65°C, and deglycosylation did not affect thermostability. Circular dichroism confirmed the high alpha-helical content consistent with the canonical GH10 family (β/α)8 barrel fold observed in molecular modeling. Primary structure analysis revealed the existence of eight cysteine residues which could be involved in four disulfide bonds, and this could explain the high thermostability of this enzyme even in the deglycosylated form. MpXyn10A showed promising results in biomass degradation, increasing the amount of reducing sugars in bagasse in natura and in three pretreated sugarcane bagasses.ConclusionsMpXyn10A was successfully secreted in Aspergillus nidulans, and a potential use for sugarcane bagasse biomass degradation was demonstrated.

Understanding the function of conserved variations in the catalytic loops of fungal glycoside hydrolase family 12

Enzymes that cleave the xyloglucan backbone at unbranched glucose residues have been identified in GH families 5, 7, 12, 16, 44, and 74. Fungi produce enzymes that populate 20 of 22 families that are considered critical for plant biomass deconstruction. We searched for GH12‐encoding genes in 27 Eurotiomycetes genomes. After analyzing 50 GH12‐related sequences, the conserved variations of the amino acid sequences were examined. Compared to the endoglucanases, the endo‐xyloglucanase‐associated YSG deletion at the negative subsites of the catalytic cleft with a SST insertion at the reducing end of the substrate‐binding crevice is highly conserved. In addition, a highly conserved alanine residue was identified in all xyloglucan‐specific enzymes, and this residue is substituted by arginine in more promiscuous glucanases. To understand the basis for the xyloglucan specificity displayed by certain GH12 enzymes, two fungal GH12 endoglucanases were chosen for mutagenesis and functional studies: an endo‐xyloglucanase from Aspergillus clavatus (AclaXegA) and an endoglucanase from A. terreus (AtEglD). Comprehensive molecular docking studies and biochemical analyses were performed, revealing that mutations at the entrance of the catalytic cleft in AtEglD result in a wider binding cleft and the alteration of the substrate‐cleavage pattern, implying that a trio of residues coordinates the interactions and binding to linear glycans. The loop insertion at the crevice‐reducing end of AclaXegA is critical for catalytic efficiency to hydrolyze xyloglucan. The understanding of the structural elements governing endo‐xyloglucanase activity on linear and branched glucans will facilitate future enzyme modifications with potential applications in industrial biotechnology. Biotechnol. Bioeng. 2014;111: 1494–1505.

Xyloglucan breakdown by endo-xyloglucanase family 74 from Aspergillus fumigatus

Xyloglucan is the most abundant hemicellulose in primary walls of spermatophytes except for grasses. Xyloglucan-degrading enzymes are important in lignocellulosic biomass hydrolysis because they remove xyloglucan, which is abundant in monocot-derived biomass. Fungal genomes encode numerous xyloglucanase genes, belonging to at least six glycoside hydrolase (GH) families. GH74 endo-xyloglucanases cleave xyloglucan backbones with unsubstituted glucose at the −1 subsite or prefer xylosyl-substituted residues in the −1 subsite. In this work, 137 GH74-related genes were detected by examining 293 Eurotiomycete genomes and Ascomycete fungi contained one or no GH74 xyloglucanase gene per genome. Another interesting feature is that the triad of tryptophan residues along the catalytic cleft was found to be widely conserved among Ascomycetes. The GH74 from Aspergillus fumigatus (AfXEG74) was chosen as an example to conduct comprehensive biochemical studies to determine the catalytic mechanism. AfXEG74 has no CBM and cleaves the xyloglucan backbone between the unsubstituted glucose and xylose-substituted glucose at specific positions, along the XX motif when linked to regions deprived of galactosyl branches. It resembles an endo-processive activity, which after initial random hydrolysis releases xyloglucan-oligosaccharides as major reaction products. This work provides insights on phylogenetic diversity and catalytic mechanism of GH74 xyloglucanases from Ascomycete fungi.

Molecular basis of substrate recognition and specificity revealed in family 12 glycoside hydrolases.

Fungal GH12 enzymes are classified as xyloglucanases when they specifically target xyloglucans, or promiscuous endoglucanases when they exhibit catalytic activity against xyloglucan and β‐glucan chains. Several structural and functional studies involving GH12 enzymes tried to explain the main patterns of xyloglucan activity, but what really determines xyloglucanase specificity remains elusive. Here, three fungal GH12 enzymes from Aspergillus clavatus (AclaXegA), A. zonatus (AspzoGH12), and A. terreus (AtEglD) were studied to unveil the molecular basis for substrate specificity. Using functional assays, site‐directed mutagenesis, and molecular dynamics simulations, we demonstrated that three main regions are responsible for substrate selectivity: (i) the YSG group in loop 1; (ii) the SST group in loop 2; and (iii) loop A3‐B3 and neighboring residues. Functional assays and sequence alignment showed that while AclaXegA is specific to xyloglucan, AtEglD cleaves β‐glucan, and xyloglucan. However, AspzoGH12 was also shown to be promiscuous contrarily to a sequence alignment‐based prediction. We find that residues Y111 and R93 in AtEglD harbor the substrate in an adequate orientation for hydrolysis in the catalytic cleft entrance and that residues Y19 in AclaXegA and Y30 in AspzoGH12 partially compensate the absence of the YSG segment, typically found in promiscuous enzymes. The results point out the multiple structural factors underlying the substrate specificity of GH12 enzymes. Biotechnol. Bioeng. 2016;113: 2577–2586.

Protein profile in Aspergillus nidulans recombinant strains overproducing heterologous enzymes

Filamentous fungi are robust cell factories and have been used for the production of large quantities of industrially relevant enzymes. However, the production levels of heterologous proteins still need to be improved. Therefore, this article aimed to investigate the global proteome profiling of Aspergillus nidulans recombinant strains in order to understand the bottlenecks of heterologous enzymes production. About 250, 441 and 424 intracellular proteins were identified in the control strain Anid_pEXPYR and in the recombinant strains Anid_AbfA and Anid_Cbhl respectively. In this context, the most enriched processes in recombinant strains were energy pathway, amino acid metabolism, ribosome biogenesis, translation, endoplasmic reticulum and oxidative stress, and repression under secretion stress (RESS). The global protein profile of the recombinant strains Anid_AbfA and Anid_Cbhl was similar, although the latter strain secreted more recombinant enzyme than the former. These findings provide insights into the bottlenecks involved in the secretion of recombinant proteins in A. nidulans, as well as in regard to the rational manipulation of target genes for engineering fungal strains as microbial cell factories.

Agro-Industrial Residues and Microbial Enzymes

Abstract Bioconversion of renewable lignocellulosic biomass to biofuels and high value-added products is nowadays a field of much attention and promise. Furthermore, lignin can be used for the smooth generation of polymers using laccase or a laccase-mediator system. Food industries provide other important uses of residues, such as underutilized fish, and by-products from the fishing industries for the production of bioactive peptides using microbial proteases. On the other hand, fat wastes, such as waste from cooking oil, are very interesting substrates for the production of industrially relevant compounds, mainly biodiesel, using lipases from different microorganisms. Again, phenolic compounds are very important because of their biological activities, presenting impressive antioxidant activity. More interestingly, they can be obtained using enzymes from different microorganisms, which are capable of producing antioxidative phenolics from different wastes. Although microbial enzymes are highly effective tools for modifying agro-industrial residues in generating high value-added products, the use of native enzymes are frequently infeasible in large scales. Therefore, different techniques of molecular biology are necessary to surpass these limitations. These techniques include the use of expression models that are more feasible for the industrial production of enzymes, and genetic and protein engineering focusing on the overexpression of the enzymes to have the desired enzymes with improved characteristics, such as better enzymatic activity, stability, and selectivity.

Comparative RNA-seq based transcriptomic analysis of Aspergillus nidulans recombinant strains overproducing heterologous glycoside hydrolases

Filamentous fungi are important cellular factories for the production and secretion of homologous and heterologous enzymes such as carbohydrate-active enzymes. However, the regulation of protein secretion in these microorganisms requires more profound studies since the enzyme levels produced are usually below the levels required by industry for profitable processes. Genomic and transcriptomic approaches have been used to understand the overexpression and production of heterologous enzymes and their capacity to induce different cellular biological processes. To investigate this regulation, Aspergillus nidulans recombinant strains were analyzed by transcriptomics. We designed three A. nidulans recombinant strains producing the following heterologous proteins: alpha-arabinofuranosidase (AbfA), beta-glucosidase (BglC) and thermophilic mannanase (Tp-Man5). The heterologous genes abfA and bglC were highly expressed, while tp-man5 mRNA levels were low and similar to those of a reference gene. There was an indirect relationship between mRNA and protein secretion levels, suggesting that transcription is not a bottleneck for target gene expression in this system. Despite the distinct features of the recombinant proteins, 30 differentially expressed genes were common to all the recombinant strains, suggesting that these genes represent a general response to the expression of heterologous genes. We also showed that the early activation of the canonical unfolded protein response (UPR) pathway by hacA alternative splicing was normalized after 8h, except in the strain expressing BglC, suggesting either no accumulation of the BglC misfolded form or the presence of an alternative endoplasmic reticulum (ER) stress and UPR pathway. Finally, to focus our analysis on the secretion pathway, a set of 374 genes was further evaluated. Seventeen genes were common to all the recombinant strains, suggesting again that these genes represent a general response of A. nidulans cells to the overexpression of recombinant genes, even thermophilic genes. Additionally, we reported the possible genetic interactions of these 17 genes based on coexpression network calculations. Interestingly, protein improvements are nongeneric, and improvements in the production of one target protein are not necessarily transferable to another one. Thus, this study may provide genetic and cellular background and targets for genetic manipulation to improve protein secretion by A. nidulans.

Structural and functional characterization of a highly secreted α-l-arabinofuranosidase (GH62) from Aspergillus nidulans grown on sugarcane bagasse

Carbohydrate-Active Enzymes are key enzymes for biomass-to-bioproducts conversion. α-l-Arabinofuranosidases that belong to the Glycoside Hydrolase family 62 (GH62) have important applications in biofuel production from plant biomass by hydrolyzing arabinoxylans, found in both the primary and secondary cell walls of plants. In this work, we identified a GH62 α-l-arabinofuranosidase (AnAbf62Awt) that was highly secreted when Aspergillus nidulans was cultivated on sugarcane bagasse. The gene AN7908 was cloned and transformed in A. nidulans for homologous production of AnAbf62Awt, and we confirmed that the enzyme is N-glycosylated at asparagine 83 by mass spectrometry analysis. The enzyme was also expressed in Escherichia coli and the studies of circular dichroism showed that the melting temperature and structural profile of AnAbf62Awt and the non-glycosylated enzyme from E. coli (AnAbf62Adeglyc) were highly similar. In addition, the designed glycomutant AnAbf62AN83Q presented similar patterns of secretion and activity to the AnAbf62Awt, indicating that the N-glycan does not influence the properties of this enzyme. The crystallographic structure of AnAbf62Adeglyc was obtained and the 1.7Å resolution model showed a five-bladed β-propeller fold, which is conserved in family GH62. Mutants AnAbf62AY312F and AnAbf62AY312S showed that Y312 was an important substrate-binding residue. Molecular dynamics simulations indicated that the loop containing Y312 could access different conformations separated by moderately low energy barriers. One of these conformations, comprising a local minimum, is responsible for placing Y312 in the vicinity of the arabinose glycosidic bond, and thus, may be important for catalytic efficiency.