Plant cell wall proteins called expansins are thought to disrupt hydrogen bonding between cell wall polysaccharides without hydrolyzing them. We describe here a novel gene with sequence similarity to plant expansins, isolated from the cellulolytic fungus Trichoderma reesei. The protein named swollenin has an N-terminal fungal type cellulose binding domain connected by a linker region to the expansin-like domain. The protein also contains regions similar to mammalian fibronectin type III repeats, found for the first time in a fungal protein. The swollenin gene is regulated in a largely similar manner as the T. reesei cellulase genes. The biological role of SWOI was studied by disrupting the swo1 gene from T. reesei. The disruption had no apparent effect on the growth rate on glucose or on different cellulosic carbon sources. Non-stringent Southern hybridization of Trichoderma genomic DNA with swo1 showed the presence of other swollenin-like genes, which could substitute for the loss of SWOI in the disruptant. The swollenin gene was expressed in yeast and Aspergillus niger var. awamori. Activity assays on cotton fibers and filter paper were performed with concentrated SWOI-containing yeast supernatant that disrupted the structure of the cotton fibers without detectable formation of reducing sugars. It also weakened filter paper as assayed by an extensometer. The SWOI protein was purified from A. niger var. awamori culture supernatant and used in an activity assay with Valonia cell walls. It disrupted the structure of the cell walls without producing detectable amounts of reducing sugars.
We have engineered the filamentous fungus Trichoderma reesei to assemble and secrete immunologically authentic engineered Fab antibody fragments into the culture medium. A major improvement in yield was achieved by fusing the heavy Fd chain to the T. reesei cellulase, CBHI. The yields of secreted, immunologically active Fab and CBHI-Fab fusion were 1 mg/l and 150 mg/l, respectively. The Fab fragment can be released from the fusion protein CBHI-Fab by an extracellular T. reesei protease. There was no detectable difference in affinity for the antigen between the engineered Fab and the idiotypic antibody.
Aspergillus niger var. awamori contains multiple copies of a transposable element, Vader. This element was detected as a 437-bp insertion in four independently isolated spontaneous mutants of the niaD (nitrate reductase) gene. The Vader element is present in approximately 15 copies in both A. niger var. awamori and A. niger. A single copy of Vader was detected from only one of the two laboratory strains of A. nidulans which were also examined. Insertion of the Vader element into the niaD gene of A. niger var. awamori caused a 2-bp duplication (TA) of the target sequence. The Vader element is flanked by a 44-bp inverted repeat. The genetic stabilities of the inserted Vader elements at niaD were examined by studying reversion frequencies resulting in colonies able to grow on nitrate as a sole nitrogen source. Mutants niaD392 and niaD436 reverted at a frequency of 9x10(-3) and 4x10(-2), respectively. Two of the mutants, niaD587 and niaD410, reverted at a lower frequency of 6x10(-4).
The production of Fab antibody fragments in Trichoderma reesei can be increased over 50-fold by fusing the core-linker region of the T. reesei cellulase CBHI (cellobiohydrolase I) to the heavy Fd chain (Nyyssönen et al. 1993). This beneficial role of CBHI in antibody production has now been studied further by comparisons of T. reesei trains producing the light chain only. Fab or CBHI-Fab all of which exhibited identical light chain integration. The N-terminal fusion of CBHI to the heavy Fd chain not only aided secretion, as expected, but also increased the level of mRNA encoding the CBHI-heavy Fd chain, either by stabilizing the messenger or by enhancing transcription. The CBHI part appeared to facilitate secretion at least by aiding the passage through the endoplasmic reticulum, since processing of the signal peptide of the antibody chains seemed to be most efficient in the strain producing CBHI-Fab in contrast to the strains producing light chain or Fab fragment. Interestingly, CBHI core-linker protein, originating from the CBHI-heavy Fd chain, was found in large amounts in the culture medium. The cleavage resulting in this tailless CBHI occurred inside the cell. This suggests that, by omitting the heterologous tail, the secretion of the resulting CBHI core-linker protein is enhanced to a level comparable with secretion of the extracellular T. reesei proteins.
Aspergillus niger var. awamori has transposable elements that we refer to as Vader and Tan1 (transposon A. niger). Vader was identified by screening unstable nitrate reductase (niaD) mutants for insertions. Four of the isolated niaD mutants were shown to contain a small insertion element. This 437 bp insertion element, Vader, is flanked by 44 bp inverted repeats (IR) and is present in approximately 15 copies in the genomes of two A. niger strains examined. A synthetic 44 bp oligomer of the inverted repeat of Vader has now been used to clone, via the polymerase chain reaction, a 2.3 kb Tan1 element. The Tan1 element has also been isolated from a partial genomic library. Tan1 is present as a single copy in A. niger var. awamori. The Tan1 element has a unique organization: IR-ORF-IR-IR-Vader-IR. The single open reading frame (ORF) (1668 bp) encodes a putative transposase homologous to Fusarium oxysporum Fot1 and Magnaporthe grisea Pot2. Immediately 3' to the second inverted repeat, which bounds the transposase, is a copy of the AT-rich Vader element. We hypothesize that at some stage the independent Vader element, although inactive by itself, arose from Tan1, resulting in current strains with only one copy of Tan1 providing transposase activity and numerous mobile copies of Vader dispersed in the genome.
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