Arja Mäntylä

High frequency one-step gene replacement in Trichoderma reesei. II. Effects of deletions of individual cellulase genes

Four cellulase genes of Trichoderma reesei, cbh1, cbh2, egl1 and egl2, have been replaced by the amdS marker gene. When linear DNA fragments and flanking regions of the corresponding cellulase locus of more than 1 kb were used, the replacement frequencies were high, ranging from 32 to 52%. Deletion of the major cellobiohydrolase 1 gene led to a 2-fold increase in the production of cellobiohydrolase II; however, replacement of the cbh2 gene did not affect the final cellulase levels and deletion of egl1 or egl2, slightly increased production of both cellobiohydrolases. Based on our results, endoglucanase II accounts for most of the endoglucanase activity produced by the hypercellulolytic host strain. Furthermore, loss of the egl2, gene causes a significant drop in the filter paper-hydrolysing activity, indicating that endoglucanase II has an important role in the total hydrolysis of cellulose.

Genetic engineering of Trichoderma to produce strains with novel cellulase profiles

Genetic engineering has been used to modify the proportion of different cellulases produced by a hypercellulolytic Trichoderma reesei mutant strain. A general expression vector, pAMH110, containing the promoter and terminator sequences of the strongly expressed main cellobiohydrolase 1 (cbh1) gene was used to overexpress a cDNA coding for EGI, the major endoglucanase (1,4,beta-D-glucan glucanohydrolase, EC 3.2.1.4). An in vitro modified cbh1 cDNA, incapable of coding for active enzyme, was used to inactivate the major cellobiohydrolase (1,4-beta-D-glucan cellobiohydrolase, EC 3.2.1.91) gene. In this way, new strains producing elevated amounts of the specific endoglucanase 1 (EGI) and/or lacking the major cellobiohydrolase (CBHI) were produced, and these have been further characterized.

High frequency one-step gene replacement in Trichoderma reesei. I. Endoglucanase I overproduction

The chromosomal cellobiohydrolase 1 locus (cbh1) of the biotechnologically important filamentous fungus Trichoderma reesei was replaced in a single-step procedure by an expression cassette containing an endoglucanase I cDNA (egl1) under control of the cbh1 promoter. CBHI protein was missing from 37–63% of the transformants, showing that targeting of the linear expression cassette to the cbh1 locus was efficient. Studies of expression of the intact cbh1-egl1 cassette at the cbh1 locus revealed that egl1 cDNA is expressed from the cbh1 promoter as efficiently as cbh1 itself. Furthermore, a strain carrying two copies of the cbh1-egl1 expression cassette produced twice as much EG I as the amount of CBHI, the major cellulase protein, produced by the host strain. The level of egl1-specific mRNA in the single-copy transformant was about 10-fold higher than that found in the non transformed host strain, indicating that the cbh1 promoter is about 10 times stronger than the egl1 promoter. The 10-fold increase in the secreted EG I protein, measured with an enzyme-linked immunosorbent assay (ELISA), correlated well with the increase in egl1-specific mRNA.

High-Yield Production of a Bacterial Xylanase in the Filamentous Fungus Trichoderma reesei Requires a Carrier Polypeptide with an Intact Domain Structure

ABSTRACT A bacterial xylanase gene, Nonomuraea flexuosa xyn11A, was expressed in the filamentous fungus Trichoderma reesei from the strong cellobiohydrolase 1 promoter as fusions to a variety of carrier polypeptides. By using single-copy isogenic transformants, it was shown that production of this xylanase was clearly increased (up to 820 mg/liter) when it was produced as a fusion protein with a carrier polypeptide having an intact domain structure compared to the production (150 to 300 mg/liter) of fusions to the signal sequence alone or to carriers having incomplete domain structures. The carriers tested were the T. reesei mannanase I (Man5A, or MANI) core-hinge and a fragment thereof and the cellulose binding domain of T. reesei cellobiohydrolase II (Cel6A, or CBHII) with and without the hinge region(s) and a fragment thereof. The flexible hinge region was shown to have a positive effect on both the production of Xyn11A and the efficiency of cleavage of the fusion polypeptide. The recombinant Xyn11A produced had properties similar to those of the native xylanase. It constituted 6 to 10% of the total proteins secreted by the transformants. About three times more of the Man5A core-hinge carrier polypeptide than of the recombinant Xyn11A was observed. Even in the best Xyn11A producers, the levels of the fusion mRNAs were only ∼10% of the level of cel7A (cbh1) mRNA in the untransformed host strain.

Electrophoretic karyotyping of wild-type and mutant Trichoderma longibrachiatum (reesei) strains

SummaryAn electrophoretic karyotype of Trichoderma longibrachiatum (reesei) was obtained using contourclamped homogeneous electric field (CHEF) gel electrophoresis. Seven chromosomal DNA bands were separated in the wild-type T. longibrachiatum strain QM6a. The sizes of the chromosomal DNA bands ranged from 2.8 to 6.9 Mb, giving an estimated total genome size of about 33 Mb. The electrophoretic karyotype of the strain QM6a was compared to three hyper-cellulolytic mutant strains, QM9414, RutC30 and VTT-D-79125. The chromosome pattern of the mutant QM9414 was quite similar to that of the wild-type QM6a except that the smallest chromosome differed somewhat in size. The VTT-D-79125 and RutC30 strains, which have undergone several mutagenesis steps, showed striking differences in their karyotype compared to the initial parent. The chromosomal DNA bands were identified using the previously characterized T. longibrachiatum genes (egl1, egl2, cbh1, cbh2, pgk1, rDNA) and random clones isolated from a genomic library. In all strains the cellulase genes cbh1, cbh2 and egl2 were located in the same linkage group (chromosome II in the wild-type), while the main endoglucanase, egl1, hybridized to another chromosomal DNA band (chromosome VI in the wild-type).

Increased production of xylanase by expression of a truncated version of the xyn11A gene from Nonomuraea flexuosa in Trichoderma reesei

ABSTRACT We have previously shown that the Nonomuraea flexuosa Xyn11A polypeptides devoid of the carbohydrate binding module (CBM) have better thermostability than the full-length xylanase and are effective in bleaching of pulp. To produce an enzyme preparation useful for industrial applications requiring high temperature, the region encoding the CBM was deleted from the N. flexuosa xyn11A gene and the truncated gene was expressed in Trichoderma reesei. The xylanase sequence was fused to the T. reesei mannanase I (Man5A) signal sequence or 3′ to a T. reesei carrier polypeptide, either the Man5A core/hinge or the cellulose binding domain (CBD) of cellobiohydrolase II (Cel6A, CBHII). The gene and fusion genes were expressed using the cellobiohydrolase 1 (cel7A, cbh1) promoter. Single-copy isogenic transformants in which the expression cassette replaced the cel7A gene were cultivated and analyzed. The transformants expressing the truncated N. flexuosa xyn11A produced clearly increased amounts of both the xylanase/fusion mRNA and xylanase activity compared to the corresponding strains expressing the full-length N. flexuosa xyn11A. The transformant expressing the cel6A CBD-truncated N. flexuosa xyn11A produced about 1.9 g liter−1 of the xylanase in laboratory-scale fermentations. The xylanase constituted about 25% of the secreted proteins. The production of the truncated xylanase did not induce the unfolded protein response (UPR) pathway. However, the UPR was induced when the full-length N. flexuosa xyn11A with an exact fusion to the cel7A terminator was expressed. We suggest that the T. reesei folding/secretion machinery is not able to cope properly with the bacterial CBM when the mRNA of the full-length N. flexuosa xyn11A is efficiently translated.

The Three-Dimensional X-Ray Crystal Structure of the Aspartic Proteinase Native to Trichoderma Reesei Complexed with a Renin Inhibitor CP-80794

Aspartic proteinases comprise a family of proteolytic enzymes found in a diverse range of species, from vertebrates, to lower eukaryotes and retroviruses. They are active at neutral or low pH. They are all characterised by the presence of two aspartic acid residues at the active site and are inhibited by pepstatin A. The aspartic proteinases can be broadly divided into two main groups: the retroviral and pepsin-like enzymes. We shall, however only consider the pepsin-like aspartic proteinases.