Yuqi Qin

Genomic and Secretomic Analyses Reveal Unique Features of the Lignocellulolytic Enzyme System of Penicillium decumbens

Many Penicillium species could produce extracellular enzyme systems with good lignocellulose hydrolysis performance. However, these species and their enzyme systems are still poorly understood and explored due to the lacking of genetic information. Here, we present the genomic and secretomic analyses of Penicillium decumbens that has been used in industrial production of lignocellulolytic enzymes in China for more than fifteen years. Comparative genomics analysis with the phylogenetically most similar species Penicillium chrysogenum revealed that P. decumbens has evolved with more genes involved in plant cell wall degradation, but fewer genes in cellular metabolism and regulation. Compared with the widely used cellulase producer Trichoderma reesei, P. decumbens has a lignocellulolytic enzyme system with more diverse components, particularly for cellulose binding domain-containing proteins and hemicellulases. Further, proteomic analysis of secretomes revealed that P. decumbens produced significantly more lignocellulolytic enzymes in the medium with cellulose-wheat bran as the carbon source than with glucose. The results expand our knowledge on the genetic information of lignocellulolytic enzyme systems in Penicillium species, and will facilitate rational strain improvement for the production of highly efficient enzyme systems used in lignocellulose utilization from Penicillium species.

Genome shuffling improves production of cellulase by Penicillium decumbens JU-A10

Aims:  Improvement of cellulase production of Penicillium decumbens by genome shuffling of an industrial catabolite‐repression‐resistant strain JU‐A10 with its mutants.

Engineering endoglucanase II from Trichoderma reesei to improve the catalytic efficiency at a higher pH optimum

The catalytic efficiency and pH optimum of Trichoderma reesei endo-beta-1,4-glucanase II were improved by protein engineering. We subjected residue 342 to saturation mutagenesis, and further changed the enzyme by random mutagenesis and two rounds of DNA shuffling. Enzyme variants were purified and characterized. Variant N342V exhibited an optimal activity at pH 5.8, corresponding to a basic shift of 1 pH unit compared with the wild-type enzyme, and had improved catalytic efficiency (1.5-fold of k(cat)/K(m)) for the main substrates at pH 6.2. Variants N342R and N39R/L218H/W276R/N342T both had a pH optimum of 6.2 and the latter had improved catalytic efficiency (1.4-fold of k(cat)/K(m)) at pH 6.2. Variants L218H, Q139R/N342T and Q139R/L218H/W276R/N342T all had more than 4.5-fold higher activity in reactions compared with the wild-type at pH 7.0. The relationship between the structures and the activities of the variants were analyzed by modeling the structures of the endoglucanase II variants. More stable helixes and changed electrostatic interactions between the catalytic residues and substrates may explain the higher activities and higher pH optima of the variants.

Isolation and characterization of a β-glucosidase from Penicillium decumbens and improving hydrolysis of corncob residue by using it as cellulase supplementation

A β-glucosidase from Penicillium decumbens was purified and characterized. The enzyme presented as a single band of 120kDa on SDS-PAGE, showed optimal temperature of 65-70°C and optimal pH of 4.5-5.0. The β-glucosidase showed relatively higher affinity to pNPG and the highest affinity to salicin with the Km value as 0.0064 and 0.0188mM, respectively. The gene coding for it was obtained with an ORF of 2586bp coding for 861 amino acids belonging to glycoside hydrolases family 3. The purified enzyme could improve the saccharifying ability of cellulose when it was added to the cellulase systems of Trichoderma reesei QM 9414. The several properties of it, including its pH and temperature optima, the high affinity to substrates and high specific activity, make it has great potential to be utilized as supplementation in conversion of corncob residue and other lignocellulosic biomass into simple sugars.

Development of highly efficient, low-cost lignocellulolytic enzyme systems in the post-genomic era

The current high cost of lignocellulolytic enzymes is a major bottleneck in the economic bioconversion of lignocellulosic biomass to fuels and chemicals. Fungal lignocellulolytic enzyme systems are secreted at high levels, making them the most promising starting points for further development of highly efficient lignocellulolytic enzyme systems. In this paper, recent advances in improvement of fungal lignocellulolytic enzyme systems are reviewed, with an emphasis on the achievements made using genomic approaches. A general strategy for lignocellulolytic enzyme system development is proposed, including the improvement of the hydrolysis efficiencies and productivities of current enzyme systems. The applications of genomic, transcriptomic and proteomic analysis methods in examining the composition of native enzyme systems, discovery of novel enzymes and synergistic proteins from natural sources, and understanding of regulatory mechanisms for lignocellulolytic enzyme biosynthesis are summarized. By combining systems biology and synthetic biology tools, engineered fungal strains are expected to produce high levels of optimized lignocellulolytic enzyme systems.

Synergistic and Dose-Controlled Regulation of Cellulase Gene Expression in Penicillium oxalicum.

Filamentous fungus Penicillium oxalicum produces diverse lignocellulolytic enzymes, which are regulated by the combinations of many transcription factors. Here, a single-gene disruptant library for 470 transcription factors was constructed and systematically screened for cellulase production. Twenty transcription factors (including ClrB, CreA, XlnR, Ace1, AmyR, and 15 unknown proteins) were identified to play putative roles in the activation or repression of cellulase synthesis. Most of these regulators have not been characterized in any fungi before. We identified the ClrB, CreA, XlnR, and AmyR transcription factors as critical dose-dependent regulators of cellulase expression, the core regulons of which were identified by analyzing several transcriptomes and/or secretomes. Synergistic and additive modes of combinatorial control of each cellulase gene by these regulatory factors were achieved, and cellulase expression was fine-tuned in a proper and controlled manner. With one of these targets, the expression of the major intracellular β-glucosidase Bgl2 was found to be dependent on ClrB. The Bgl2-deficient background resulted in a substantial gene activation by ClrB and proved to be closely correlated with the relief of repression mediated by CreA and AmyR during cellulase induction. Our results also signify that probing the synergistic and dose-controlled regulation mechanisms of cellulolytic regulators and using it for reconstruction of expression regulation network (RERN) may be a promising strategy for cellulolytic fungi to develop enzyme hyper-producers. Based on our data, ClrB was identified as focal point for the synergistic activation regulation of cellulase expression by integrating cellulolytic regulators and their target genes, which refined our understanding of transcriptional-regulatory network as a “seesaw model” in which the coordinated regulation of cellulolytic genes is established by counteracting activators and repressors.

Promotion of extracellular lignocellulolytic enzymes production by restraining the intracellular β-glucosidase in Penicillium decumbens

In this study, the functions of β-glucosidases in regulation of the lignocellulolytic enzymes production in Penicillium decumbens 114-2 were investigated. The major extracellular β-glucosidase gene bgl1 and the major intracellular β-glucosidase gene bgl2 were deleted in P. decumbens 114-2 respectively. In Δbgl2, the production of extracellular lignocellulolytic enzymes (including endoglucanases, cellobiohydrolases and xylanases) on insoluble cellulose was significantly promoted, while in Δbgl1 there was no any difference compared with that of 114-2. The enhancement of the production of lignocellulolytic enzymes in Δbgl2 was likely attributed to the accumulation of intracellular cellobiose. Induction experiment in Δbgl1Δbgl2 showed that cellobiose was an inducer of lignocellulolytic enzymes expression in P. decumbens 114-2, and the induction was unrelated to the formation, if any, of gentiobiose or sophorose from cellobiose.

Transcription analysis of lignocellulolytic enzymes of Penicillium decumbens 114-2 and its catabolite-repression-resistant mutant.

Penicillium decumbens 114-2 is a fast-growing filamentous fungus which secretes a variety of lignocellulolytic enzymes. Its catabolite-repression-resistant mutant JU-A10 with high secretion capacity of cellulolytic enzymes has been used industrially for biomass hydrolysis. Transcription levels of 6 important lignocellulolytic enzymes genes (cel5A, cel6A, cel7A, cel7B, xyn10A, and xyn11A) from both strains were determined on different carbon sources (glucose, sorbose, lactose, cellobiose, cellulose, and cellulose-wheat bran), by means of a real-time quantitative polymerase chain reaction. For both strains, the 6 genes are coordinately regulated at transcriptional level. Glucose and cellobiose repressed whereas cellulose and cellulose-wheat bran induced expression of 6 genes in both strains. Expression levels of all genes tested in the mutant strain JU-A10 were substantially higher than those in wild-type strain 114-2 on all carbon sources. On glucose repression condition, the mutant JU-A10 appeared obviously derepressed. Lactose was first proved to have an inductive effect on lignocellulolytic enzyme genes expression at lower concentration in Penicillium spp.

Cellodextrin transporters play important roles in cellulase induction in the cellulolytic fungus Penicillium oxalicum

Cellodextrin transporters (cellodextrin permeases) have been identified in fungi in recent years. However, the functions of these transporters in cellulose utilization and cellulase expression have not been well studied. In this study, three cellodextrin transporters, namely, CdtC, CdtD, and CdtG, in the cellulolytic fungus Penicillium oxalicum (formally was classified as P. decumbens) were identified, and their functions were analyzed. The deletion of a single cellodextrin transporter gene slightly decreased cellobiose consumption, but no observable effect on cellulase expression was observed, which was attributed to the overlapping activity of isozymes. Further simultaneous deletion of cdtC and cdtD resulted in significantly decreased cellobiose consumption and poor growth on cellulose. The extracellular activity and transcription level of cellulases in the mutant without cdtC and cdtD were significantly lower than those in the wild-type strain when grown on cellulose. This result provides direct evidence of the crucial function of cellodextrin transporters in the induction of cellulase expression by insoluble cellulose.

G protein-cAMP signaling pathway mediated by PGA3 plays different roles in regulating the expressions of amylases and cellulases in Penicillium decumbens

Heterotrimeric G proteins (G proteins) have been extensively investigated for their regulatory functions in morphogenesis and development in filamentous fungi. In addition, G proteins were also shown to be involved in the regulation of cellulase expression in some fungi. Here, we report the different regulatory effects of PGA3, a group III G protein α subunit, on the expressions of amylases and cellulases in Penicillium decumbens. Deletion of pga3 resulted in impaired amylase production and significantly decreased transcription of the major amylase gene amy15A. Supplementation of exogenous cAMP or its analog dibutyryl-cAMP restored amylase production in Δpga3 strain, suggesting an essential role of PGA3 in amylase synthesis via controlling cAMP level. On the other hand, the transcription of major cellulase gene cel7A-2 increased, nevertheless cellulase activity in the medium was not affected, in Δpga3. The above regulatory effects of PGA3 are carbon source-independent, and are achieved, at least, by cAMP-mediated regulation of the expression level of transcription factor AmyR. The functions of PGA3 revealed by gene deletion were partially supported by the analysis of the mutant carrying dominantly-activated PGA3. The results provided new insights into the understanding of the physiological functions of G protein-cAMP pathway in filamentous fungi.