The lignin-degrading abilities of Gelatoporia subvermispora gat1 and pex1 mutants generated via CRISPR/Cas9.

White-rot fungi efficiently degrade wood lignin; however, the mechanisms involved remain largely unknown. Recently, a forward genetics approach to identify several genes in Pleurotus ostreatus (Agaricales) in which mutations cause defects in wood lignin degradation was used. For example, pex1 encodes a peroxisome biogenesis factor and gat1 encodes a putative Agaricomycetes-specific DNA-binding transcription factor. In this study, we examined the effects of single-gene mutations in pex1 or gat1 on wood lignin degradation in another white-rot fungus, Gelatoporia (Ceriporiopsis) subvermispora (Polyporales), to investigate conserved and derived degradation mechanisms in white-rot fungi. G. subvermispora pex1 and gat1 single-gene mutant strains were generated from a monokaryotic wild-type strain, FP-90031-Sp/1, using plasmid-based CRISPR/Cas9. As in P. ostreatus, Gsgat1 mutants were nearly unable to degrade lignin sourced from beech wood sawdust medium (BWS), while Gspex1 mutants exhibited a delay in lignin degradation. We also found that the transcripts of lignin-modifying enzyme-encoding genes, mnp4, mnp5, mnp6, mnp7, and mnp11, which predominantly accumulate in FP-90031-Sp/1 cultured with BWS, were greatly downregulated in Gsgat1 mutants. Taken together, the results suggest that Gat1 may be a conserved regulator of the ligninolytic system of white-rot fungi and that the contribution of peroxisomes to the ligninolytic system may differ among species.

CRISPR/Cas9 using a transient transformation system in Ceriporiopsis subvermispora.

Ceriporiopsis subvermispora is a white-rot fungus with great potential for industrial and biotechnological applications, such as the pretreatment of lignocellulose in biorefineries, as it decomposes the lignin in the plant cell wall without causing severe cellulose degradation. A genetic transformation system was recently developed; however, gene-targeting experiments to disrupt or modify the gene(s) of interest remain challenging, and this is a bottleneck for further molecular genetic studies and breeding of C. subvermispora. Herein, we report efficient clustered regularly interspaced short palindromic repeat (CRISPR)/CRISPR-associated protein 9 (Cas9)-assisted gene mutagenesis in this fungus. Two plasmids expressing Cas9 together with a different pyrG-targeting single-guide RNA were separately introduced into the monokaryotic C. subvermispora strain FP-90031-Sp/1, which frequently generated strains that exhibited resistance to 5-fluoroorotic acid and uridine/uracil auxotrophy. Southern blot analyses and genomic polymerase chain reaction followed by DNA sequencing of some mutants revealed that they were pyrG mutants. We also observed that hygromycin resistance of the pyrG mutants was frequently lost after repeated subcultivations, indicating that a maker-free genome editing occurred successfully. It is also suggested that a gene mutation(s) can be introduced via a transient expression of Cas9 and a single-guide RNA; this feature, together with high-frequency gene targeting using the CRISPR/Cas9 system, would be helpful for studies on lignocellulose-degrading systems in C. subvermispora. KEY POINTS: • Efficient plasmid-based CRISPR/Cas9 was established in C. subvermispora. • The mutations can be introduced via a transient expression of Cas9 and sgRNA. • A maker-free CRISPR/Cas9 is established in this fungus.

Characterization of the effects of terminators and introns on recombinant gene expression in the basidiomycete Ceriporiopsis subvermispora.

Terminators and introns are vital regulators of gene expression in many eukaryotes; however, the functional importance of these elements for controlling gene expression in Agaricomycetes remains unclear. In this study, the effects of Ceriporiopsis subvermispora terminators and introns on the expression of a recombinant hygromycin B phosphotransferase gene (hph) were characterized. Using a transient transformation system, we proved that a highly active terminator (e.g., the gpd terminator) is required for the efficient expression of the hph gene. Mutational analyses of the C. subvermispora gpd terminator revealed that hph expression was dictated by an A-rich region, which included a putative positioning element, and polyadenylation sites. In contrast, our results indicated that introns are not required for the expression of hph directed by the Csß1-tub and Csgpd promoters in C. subvermispora. This study provides insights into the functions and cis-element requirements of transcriptional terminators in Agaricomycetes, which may be relevant for designing recombinant genes for this important fungal class.

Fungus-specific sirtuin HstD coordinates secondary metabolism and development through control of LaeA.

The sirtuins are members of the NAD(+)-dependent histone deacetylase family that contribute to various cellular functions that affect aging, disease, and cancer development in metazoans. However, the physiological roles of the fungus-specific sirtuin family are still poorly understood. Here, we determined a novel function of the fungus-specific sirtuin HstD/Aspergillus oryzae Hst4 (AoHst4), which is a homolog of Hst4 in A. oryzae yeast. The deletion of all histone deacetylases in A. oryzae demonstrated that the fungus-specific sirtuin HstD/AoHst4 is required for the coordination of fungal development and secondary metabolite production. We also show that the expression of the laeA gene, which is the most studied fungus-specific coordinator for the regulation of secondary metabolism and fungal development, was induced in a ΔhstD strain. Genetic interaction analysis of hstD/Aohst4 and laeA clearly indicated that HstD/AoHst4 works upstream of LaeA to coordinate secondary metabolism and fungal development. The hstD/Aohst4 and laeA genes are fungus specific but conserved in the vast family of filamentous fungi. Thus, we conclude that the fungus-specific sirtuin HstD/AoHst4 coordinates fungal development and secondary metabolism via the regulation of LaeA in filamentous fungi.