Your search keyword '"Louise Glass"' showing total 2 results

1. Plant Cell Wall Deconstruction by Ascomycete Fungi.

Author

Louise Glass, N., Schmoll, Monika, Cate, Jamie H.D., and Coradetti, Samuel

Subjects

PLANT cell walls, ASCOMYCETES, PLANT biomass, CARBON cycle, GENOMICS, POLYSACCHARIDES, MONOOXYGENASES

Abstract

Plant biomass degradation by fungi requires a diverse set of secreted enzymes and significantly contributes to the global carbon cycle. Recent advances in genomic and systems-level studies have begun to reveal how filamentous ascomycete species exploit carbon sources in different habitats. These studies have laid the groundwork for unraveling new enzymatic strategies for deconstructing the plant cell wall, including the discovery of polysaccharide monooxygenases that enhance the activity of cellulases. The identification of genes encoding proteins lacking functional annotation, but that are coregulated with cellulolytic genes, suggests functions associated with plant biomass degradation remain to be elucidated. Recent research shows that signaling cascades mediating cellulolytic responses often act in a light-dependent manner and show crosstalk with other metabolic pathways. In this review, we cover plant biomass degradation, from sensing, to transmission and modulation of signals, to activation of transcription factors and gene induction, to enzyme complement and function. [ABSTRACT FROM AUTHOR]

Published

2013

2. Engineered Saccharomyces cerevisiae capable of simultaneous cellobiose and xylose fermentation.

Author

Suk-Jin Ha, Galazka, Jonathan M., Soo Rin Kim, Jin-Ho Choi, Xiaomin Yang, Jin-Ho Seo, Louise Glass, N., Cate, Jamie H. D., and Yong-Su Jin

Subjects

BIOMASS energy, FERMENTATION, ETHANOL as fuel, YEAST, BIOCHEMICAL engineering

Abstract

The use of plant biomass for biofuel production will require efficient utilization of the sugars in lignocellulose. primarily glucose and xylose. However, strains of Saccharomyces cerevisiae presently used in bioethanol production ferment glucose but not xylose. Yeasts engineered to ferment xylose do so slowly, and cannot utilize xylose until glucose is completely consumed. To overcome these bottlenecks, we engineered yeasts to coferment mixtures of xylose and cellobiose. In these yeast strains, hydrolysis of cellobiose takes place inside yeast cells through the action of an intracellular β-glucosidase following import by a high-affinity cellodextrin transporter. Intracellular hydrolysis of cellobiose mini- mizes glucose repression of xylose fermentation allowing coconsumption of cellobiose and xylose. The resulting yeast strains, cofermented cellobiose and xylose simultaneously and exhibited improved ethanol yield when compared to fermentation with either cellobiose or xylose as sole carbon sources. We also observed improved yields and productivities from cofermentation experiments performed with simulated cellulosic hydrolyzates, suggesting this is a promising cofermentation strategy for cellulosic biofuel production. The successful integration of cellobiose and xylose fermentation pathways in yeast is a critical step towards enabling economic biofuel production. [ABSTRACT FROM AUTHOR]

Published

2011