Abstract
Humicola insolens is an excellent producer of pH-neutral active, thermostable cellulases that find many industrial applications. In the present study, we developed an efficient Agrobacterium tumefaciens-mediated transformation system for H. insolens. We transformed plasmids carrying the promoter of the glyceraldehyde-3-phosphate dehydrogenase gene of H. insolens driving the transcription of genes encoding neomycin phosphotransferase, hygromycin B phosphotransferase, and enhanced green fluorescent protein. We optimized transformation efficiency to obtain over 300 transformants/106 conidia. T-DNA insertional mutagenesis was employed to generate an H. insolens mutant library, and we isolated a transformant termed T4 with enhanced cellulase and hemicellulase activities. The FPase, endoglucanase, cellobiohydrolase, β-glucosidase, and xylanase activities of T4, measured at the end of fermentation, were 60%, 440%, 320%, 41%, and 81% higher than those of the wild-type strain, respectively. We isolated the sequences flanking the T-DNA insertions and thus identified new genes potentially involved in cellulase and hemicellulase production. Our results show that it is feasible to use T-DNA insertional mutagenesis to identify novel candidate genes involved in cellulase production. This will be valuable when genetic improvement programs seeking to enhance cellulase production are planned, and will also allow us to gain a better understanding of the genetics of the thermophilic fungus H. insolens.
Highlights
Primer Pgpd-F Pgpd-F-2 Pgpd-F-3 Pgpd-R Tgpd-F Tgpd-R npt-F npt-R neo-F neo-R hph-F hph-R gfp-F gfp-R LAD1-1 LAD1-3 LAD1-5 LAD1-11 AC1 LB-1 LB-2 LB-3 RB-A RB-B RB-C and a multi-active β-glucanase preparation from H. insolens (Ultraflo L, Novozymes) is used by breweries in the mashing process
To aid in the development of a rapid and efficient transformation method for H. insolens Y1, we tested geneticin and hygromycin B currently used as selectable markers in fungal transformations
Agrobacterium tumefaciens-mediated transformation (ATMT) is an essential tool when studying the functional genomics of filamentous fungi and has been reported to be applicable to many such fungi[18,19]
Summary
Primer Pgpd-F Pgpd-F-2 Pgpd-F-3 Pgpd-R Tgpd-F Tgpd-R npt-F npt-R neo-F neo-R hph-F hph-R gfp-F gfp-R LAD1-1 LAD1-3 LAD1-5 LAD1-11 AC1 LB-1 LB-2 LB-3 RB-A RB-B RB-C and a multi-active β-glucanase preparation from H. insolens (Ultraflo L, Novozymes) is used by breweries in the mashing process. Hemicellulases and cellulases from H. insolens degrade lignocellulose-rich materials, such as rice straw or wood chips, much more efficiently than do enzymes from T. reesei[14]. H. insolens has served as an excellent host for overproduction of heterologous enzymes, especially neutral cellulases[15]. H. insolens should be seriously considered as an alternative to T. reesei in terms of biomass degradation. We isolate a mutant (termed T4) with enhanced cellulolytic capacity and identify the sequences flanking the T-DNA insertion sites. These results will help us gain a better understanding of the genetics of the organism and will greatly facilitate future genetic engineering of the fungus to obtain strains producing high levels of cellulase
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