The state-of-the-art procedure for gene insertions into Trichoderma reesei is a cotransformation of two plasmids, one bearing the gene of interest and the other a marker gene. This procedure yields up to 80% transformation efficiency, but both the number of integrated copies and the loci of insertion are unpredictable. This can lead to tremendous pleiotropic effects. This study describes the development of a novel transformation system for site-directed gene insertion based on auxotrophic markers. For this purpose, we tested the applicability of the genes asl1 (encoding an enzyme of the l-arginine biosynthesis pathway), the hah1 (encoding an enzyme of the l-lysine biosynthesis pathway), and the pyr4 (encoding an enzyme of the uridine biosynthesis pathway). The developed transformation system yields strains with an additional gene at a defined locus that are prototrophic and ostensibly isogenic compared to their parental strain. A positive transformation rate of 100% was achieved due to the developed split-marker system. Additionally, a double-auxotrophic strain that allows multiple genomic manipulations was constructed, which facilitates metabolic engineering purposes in T. reesei. By employing goxA of Aspergillus niger as a reporter system, the influence on the expression of an inserted gene caused by the orientation of the insertion and the transformation strategy used could be demonstrated. Both are important aspects to be considered during strain engineering.
Trichoderma reesei can produce up to 100 g/liter of extracellular proteins. The major and industrially relevant products are cellobiohydrolase I (CBHI) and the hemicellulase XYNI. The genes encoding both enzymes are transcriptionally activated by the regulatory protein Xyr1. The first 850 nucleotides of the cbh1 promoter contain 14 Xyr1-binding sites (XBS), and 8 XBS are present in the xyn1 promoter. Some of these XBS are arranged in tandem and others as inverted repeats. One such cis element, an inverted repeat, plays a crucial role in the inducibility of the xyn1 promoter. We investigated the impact of the properties of such cis elements by shuffling them by insertion, exchange, deletion, and rearrangement of cis elements in both the cbh1 and xyn1 promoter. A promoter-reporter assay using the Aspergillus niger goxA gene allowed us to measure changes in the promoter strength and inducibility. Most strikingly, we found that an inverted repeat of XBS causes an important increase in cbh1 promoter strength and allows induction by xylan or wheat straw. Furthermore, evidence is provided that the distances of cis elements to the transcription start site have important influence on promoter activity. Our results suggest that the arrangement and distances of cis elements have large impacts on the strength of the cbh1 promoter, whereas the sheer number of XBS has only secondary importance. Ultimately, the biotechnologically important cbh1 promoter can be improved by cis element rearrangement.IMPORTANCE In the present study, we demonstrate that the arrangement of cis elements has a major impact on promoter strength and inducibility. We discovered an influence on promoter activity by the distances of cis elements to the transcription start site. Furthermore, we found that the configuration of cis elements has a greater effect on promoter strength than does the sheer number of transactivator binding sites present in the promoter. Altogether, the arrangement of cis elements is an important factor that should not be overlooked when enhancement of gene expression is desired.
Long non-coding RNAs (lncRNAs) are crucial factors acting on regulatory processes in eukaryotes. Recently, for the first time in a filamentous fungus, the lncRNA HAX1 was characterized in the ascomycete Trichoderma reesei. In industry, this fungus is widely applied for the high-yield production of cellulases. The lncRNA HAX1 was reported to influence the expression of cellulase-encoding genes; interestingly, this effect is dependent on the presence of its most abundant length. Clearly, HAX1 acts in association with a set of well-described transcription factors to regulate gene expression. In this study, we attempted to elucidate the regulatory strategy of HAX1 and its interactions with the major transcriptional activator Xylanase regulator 1 (Xyr1). We demonstrated that HAX1 interferes with the negative feedback regulatory loop of Xyr1 in a sophisticated manner and thus ultimately has a positive effect on gene expression.
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