The targeting of starch binding domains from starch synthase III to the cell wall alters cell wall composition and properties

Grisolía, Mauricio J.; Peralta, Diego A.; Valdez, Hugo A.; Barchiesi, Julieta; Gómez-Casati, Diego F.; Busi, María V.

doi:10.1007/s11103-016-0551-y

Cited by 12 publications

(8 citation statements)

References 76 publications

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“…Low‐lignin rice was developed through the expression of a laccase‐cellulose‐binding domain (CBD) fusion protein, and this protein increases saccharification efficiency (up to 1.5‐fold) and modifications in the cell wall composition . Similarly, changes in the cell wall composition of Arabidopsis thaliana plants can be achieved through overexpression of the starch‐binding domain (SBD123) of A. thaliana starch synthase III, which increases the cell wall degradability while increasing biomass, resulting in higher levels of fermentable sugars and hydrolyzed cellulose …”

Section: Applications Of Cbms In Biotechnologymentioning

confidence: 99%

“…80 Similarly, changes in the cell wall composition of Arabidopsis thaliana plants can be achieved through overexpression of the starch-binding domain (SBD123) of A. thaliana starch synthase III, which increases the cell wall degradability while increasing biomass, resulting in higher levels of fermentable sugars and hydrolyzed cellulose. 81 Four tandem proteins, comprising two CBMs, have been used in the paper industry. 35 The CBM3-CBM3 protein shows promising potential for the paper industry because it can enhance the mechanical properties of paper, such as folding endurance (27.4%) and tensile strength (15.5%).…”

Section: Applications Of Cbms In Biotechnologymentioning

confidence: 99%

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Advances in molecular engineering of carbohydrate-binding modules

et al. 2017

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Carbohydrate-binding modules (CBMs) are non-catalytic domains that are generally appended to carbohydrate-active enzymes. CBMs have a broadly conserved structure that allows recognition of a notable variety of carbohydrates, in both their soluble and insoluble forms, as well as in their alpha and beta conformations and with different types of bonds or substitutions. This versatility suggests a high functional plasticity that is not yet clearly understood, in spite of the important number of studies relating protein structure and function. Several studies have explored the flexibility of these systems by changing or improving their specificity toward substrates of interest. In this review, we examine the molecular strategies used to identify CBMs with novel or improved characteristics. The impact of the spatial arrangement of the functional amino acids of CBMs is discussed in terms of unexpected new functions that are not related to the original biological roles of the enzymes. Proteins 2017; 85:1602-1617. © 2017 Wiley Periodicals, Inc.

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Section: Applications Of Cbms In Biotechnologymentioning

confidence: 99%

Section: Applications Of Cbms In Biotechnologymentioning

confidence: 99%

Advances in molecular engineering of carbohydrate-binding modules

et al. 2017

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“…The average cell area was increased by 40% and dry biomass weight by 76%. Unlike the ClEXPA-expressing plants, Grisolia et al (2017) observed a 27% reduction in cell wall thickness and similar amounts of cellulose in transgenic Arabidopsis stems. This suggests SBD123 loosened the components of the cell wall, stretching the cell wall to cover a greater cell volume.…”

Section: Polysaccharide Modification Cellulosementioning

confidence: 68%

“…It is also interesting to explore the effects that CBMs alone can have on cell wall architecture. In Arabidopsis, the coding sequence of the CBM of Starch Synthase III (SSIII) was overexpressed and targeted to the cell wall (Grisolia et al, 2017). Though starch and cellulose are very different in structure, previous work indicated that the concatenated triplicate of CBMs (collectively referred to as SBD123) from SSIII had preferential affinity for the linear portions of the starch molecule.…”

Section: Polysaccharide Modification Cellulosementioning

confidence: 99%

Engineering of Bioenergy Crops: Dominant Genetic Approaches to Improve Polysaccharide Properties and Composition in Biomass

Brandon

Scheller

2020

Front. Plant Sci.

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Large-scale, sustainable production of lignocellulosic bioenergy from biomass will depend on a variety of dedicated bioenergy crops. Despite their great genetic diversity, prospective bioenergy crops share many similarities in the polysaccharide composition of their cell walls, and the changes needed to optimize them for conversion are largely universal. Therefore, biomass modification strategies that do not depend on genetic background or require mutant varieties are extremely valuable. Due to their preferential fermentation and conversion by microorganisms downstream, the ideal bioenergy crop should contain a high proportion of C6-sugars in polysaccharides like cellulose, callose, galactan, and mixed-linkage glucans. In addition, the biomass should be reduced in inhibitors of fermentation like pentoses and acetate. Finally, the overall complexity of the plant cell wall should be modified to reduce its recalcitrance to enzymatic deconstruction in ways that do no compromise plant health or come at a yield penalty. This review will focus on progress in the use of a variety of genetically dominant strategies to reach these ideals. Due to the breadth and volume of research in the field of lignin bioengineering, this review will instead focus on approaches to improve polysaccharide component plant biomass. Carbohydrate content can be dramatically increased by transgenic overexpression of enzymes involved in cell wall polysaccharide biosynthesis. Additionally, the recalcitrance of the cell wall can be reduced via the overexpression of native or non-native carbohydrate active enzymes like glycosyl hydrolases or carbohydrate esterases. Some research in this area has focused on engineering plants that accumulate cell wall-degrading enzymes that are sequestered to organelles or only active at very high temperatures. The rationale being that, in order to avoid potential negative effects of cell wall modification during plant growth, the enzymes could be activated post-harvest, and post-maturation of the cell wall. A potentially significant limitation of this approach is that at harvest, the cell wall is heavily lignified, making the substrates for these enzymes inaccessible and their activity ineffective. Therefore, this review will only include research employing enzymes that are at least partially active under the ambient conditions of plant growth and cell wall development.

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“…For AAC, there were no significant differences between the different treatments of R7954. While there was significant increase ( P < 0.05) after treatment with three enzymes altogether in cw , which might be because of high amylose content and the amylose may interact with NSPs such as pectin and cellulose do (Grisolia et al ., ), and was released by removal by hydrolysis of NSPs, the significant decreases in TDF ( P < 0.01) and small changes in starch content suggested that treatment with cellulase, hemicellulose and pectinase was effective with only minor changes in starch content.…”

Section: Resultsmentioning

confidence: 97%

Dependence of physiochemical, functional and textural properties of high‐resistant starch rice on endogenous nonstarch polysaccharides

Sun

Wang

Zhang

et al. 2017

Int J of Food Sci Tech

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To investigate the possibility of improving the quality of rice rich in resistant starch through operation of nonstarch polysaccharides, the high dietary fibre (7.24%) mutant cw and its wild-type R7954 were selected to study the physiochemical characteristics of starch before and after removal of nonstarch polysaccharides. Results showed that hydrolysed or partially hydrolysed nonstarch polysaccharides in cw decreased the resistant starch content significantly, from 15.23% to 10.8%. Nonstarch polysaccharides had significant influences on the gelatinisation temperature, RVA parameters of R7954, but no significant influences on that of cw. For cw, removal of cellulose increased swelling power and adhesiveness, decreased the hardness significantly, from 0.3 to 0.23 N, while the resistant starch content was still as high as 13.72% and showed no significant difference from the wild type. This suggests that the influences of nonstarch polysaccharides on starch properties depend both on the type of rice and the nonstarch polysaccharides. Operation on nonstarch polysaccharides for obtaining rice with lower glycemic index is feasible, but operation on nonstarch polysaccharides may also be an alternative way of improving the palatability for rice high in resistant starch.

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The targeting of starch binding domains from starch synthase III to the cell wall alters cell wall composition and properties

Cited by 12 publications

References 76 publications

Advances in molecular engineering of carbohydrate-binding modules

Advances in molecular engineering of carbohydrate-binding modules

Engineering of Bioenergy Crops: Dominant Genetic Approaches to Improve Polysaccharide Properties and Composition in Biomass

Dependence of physiochemical, functional and textural properties of high‐resistant starch rice on endogenous nonstarch polysaccharides

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