J.R. Bradner scite author profile

Bran from bread wheat (Triticum aestivum ‘Babbler’) grain is composed of many outer layers of dead maternal tissues that overlie living aleurone cells. The dead cell layers function as a barrier resistant to degradation, whereas the aleurone layer is involved in mobilizing organic substrates in the endosperm during germination. We microdissected three defined bran fractions, outer layers (epidermis and hypodermis), intermediate fraction (cross cells, tube cells, testa, and nucellar tissue), and inner layer (aleurone cells), and used proteomics to identify their individual protein complements. All proteins of the outer layers were enzymes, whose function is to provide direct protection against pathogens or improve tissue strength. The more complex proteome of the intermediate layers suggests a greater diversity of function, including the inhibition of enzymes secreted by pathogens. The inner layer contains proteins involved in metabolism, as would be expected from live aleurone cells, but this layer also includes defense enzymes and inhibitors as well as 7S globulin (specific to this layer). Using immunofluorescence microscopy, oxalate oxidase was localized predominantly to the outer layers, xylanase inhibitor protein I to the xylan-rich nucellar layer of the intermediate fraction and pathogenesis-related protein 4 mainly to the aleurone. Activities of the water-extractable enzymes oxalate oxidase, peroxidase, and polyphenol oxidase were highest in the outer layers, whereas chitinase activity was found only in assays of whole grains. We conclude that the differential protein complements of each bran layer in wheat provide distinct lines of defense in protecting the embryo and nutrient-rich endosperm.

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Rapid transformation of high cellulase-producing mutant strains of Trichoderma reesei by microprojectile bombardment

Hazell

Te’o

Bradner

et al. 2000

Lett Appl Microbiol

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Intact conidia of three industrially relevant strains of Trichoderma reesei were effectively transformed by particle bombardment. Transformations were carried out individually with plasmids carrying either the fungal amdS or bacterial hph gene as a selectable marker and by cotransformation with both plasmids. Transformant yields with single plasmids were up to 11 stable transformants per mg DNA at the bombardment distance of 6 cm. Mitotic stability of the transformants was 75±100% and the cotransformation ef®ciency averaged 92% when the ®rst selection was performed on hygromycin B plates. The entire procedure could be completed in 1 week with the hph marker.

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Fungi from koala (Phascolarctos cinereus) faeces exhibit a broad range of enzyme activities against recalcitrant substrates

Peterson

Bradner

Roberts

et al. 2009

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Aims: Identification of fungi isolated from koala faeces and screening for their enzyme activities of biotechnological interest. Methods and Results: Thirty‐seven fungal strains were isolated from koala faeces and identified by the amplification and direct sequencing of the internal transcribed spacer (ITS) region of the ribosomal DNA. The fungi were screened for selected enzyme activities using agar plates containing a single substrate for each target class of enzyme. For xylanase, endoglucanase, ligninase (ligninolytic phenoloxidase) and protease over two‐thirds of the isolates produced a clearing halo at 25°C, indicating the secretion of active enzyme by the fungus, and one‐third produced a halo indicating amylase, mannanase and tannase activity. Some isolates were also able to degrade crystalline cellulose and others displayed lipase activity. Many of the fungal isolates also produced active enzymes at 15°C and some at 39°C. Conclusions: Koala faeces, consisting of highly lignified fibre, undigested cellulose and phenolics, are a novel source of fungi with high and diverse enzyme activities capable of breaking down recalcitrant substrates. Significance and Impact of the Study: To our knowledge, this is the first time fungi from koala faeces have been identified using ITS sequencing and screened for their enzyme activities.

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Metabolic activity in filamentous fungi can be analysed by flow cytometry

Bradner

Nevalainen

2003

Journal of Microbiological Methods

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J.R. Bradner

Strategic Distribution of Protective Proteins within Bran Layers of Wheat Protects the Nutrient-Rich Endosperm

Rapid transformation of high cellulase-producing mutant strains of Trichoderma reesei by microprojectile bombardment

Fungi from koala (Phascolarctos cinereus) faeces exhibit a broad range of enzyme activities against recalcitrant substrates

Metabolic activity in filamentous fungi can be analysed by flow cytometry

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