Immunogold Labeling of Rosette Terminal Cellulose-Synthesizing Complexes in the Vascular Plant <i>Vigna angularis</i>

Kimura, Satoshi; Laosinchai, Walairat; Itoh, Takaò; Cui, Xiaojiang; Linder, C. Randal; Brown, R. Malcolm

doi:10.1105/tpc.11.11.2075

Cited by 388 publications

(150 citation statements)

References 32 publications

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“…In 1999, immunolabeling in conjunction with FF-TEM showed that the rosette CSC contained CesA protein (6). The rosette region of the CSC is about 25 nm in diameter and contains six intramembrane particles.…”

Section: Cesa Protein Is a Major Component Of The Plant Cscmentioning

confidence: 99%

Biogenesis of Cellulose Nanofibrils by a Biological Nanomachine

Haigler

Roberts

2009

The Nanoscience and Technology of Renewable Biomaterials

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Cellulose is synthesized by diverse organisms including prokaryotes, protists, animals, and plants. However, cellulose achieves its natural dominance within plants, where ß-1,4-linked glucan chains form long, semi-crystalline fibrils with nanoscale lateral dimensions. Although these fibrils have been conventionally called 'microfibrils', the term 'nanofibril' may be a more appropriate name in the age of nanoscience and nanotechnology (1). This term would reflect the fibril width (ranging between ∼1.5 and 25 nm in different cells) and the importance of surface properties in the chemistry and biological roles of cellulose. A main feature of nanomaterials (with 1-100 nm dimensions) is unique properties that: (a) often arise from a high surface-to-volume ratio; and (b) bridge between the molecular mechanics that applies to the molecular scale and the Newtonian physics that applies to larger objects (2, 3). The surface interactions of cellulose with other molecules are major determinants of its role as a scaffold for deposition of other wall components and the coherence and physical properties of the composite cell wall.In the plant cell wall, the cellulose nanofibrils are commonly 2-6 nm in diameter, with the larger nanofibrils usually occurring in secondary walls. All plant cells contain about ∼15% cellulose in the thin, extensible primary walls that surround growing cells. In this role, the cellulose nanofibrils are able to constrain the direction of plant cell expansion (as driven by isodiametric turgor pressure). This function derives from the high breaking strain energy (5 − 50 × 10 6 J/m 3 ) and tensile strength (∼GN/m 2 ) of cellulose fibrils, in the same range as high tensile steel. In proportion to its density, which is lower than steel,The Nanoscience and Technology of Renewable Biomaterials Edited

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Section: Cesa Protein Is a Major Component Of The Plant Cscmentioning

confidence: 99%

Biogenesis of Cellulose Nanofibrils by a Biological Nanomachine

Haigler

Roberts

2009

The Nanoscience and Technology of Renewable Biomaterials

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“…The rosettes have been shown to be cellulose synthase by immunological methods (12). The only known components of cellulose synthase in higher plants are the CESA proteins.…”

Section: Cellulosementioning

confidence: 99%

Cell Wall Polysaccharide Synthesis

Mohnen

Bar‐Peled

Somerville

2008

Biomass Recalcitrance

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“…2). Predictions [24,77] and now experimental evidence [79] place this central region facing the cytoplasm so that only the small regions between transmembrane domains 1 and 2, 3 and 4, 5 and 6, and 7 and 8 contact the wall. A highly conserved cysteine-rich sequence precedes the first two transmembrane domains.…”

Section: Mutants Implicate Glycosyltransferases and An Endo-14-b B-gmentioning

confidence: 99%

“…Proteins immunologically related to the central catalytic domain of a cotton CesA occur in characteristic clusters of six particles on the cytoplasmic face of the Vigna angularis plasma membrane [79] where they could use cytoplasmic UDP-Glc. Whether any other proteins occur in the same structures remains to be determined.…”

Section: Organisation Of Enzymes and Products At The Plasma Membranementioning

confidence: 99%

“…The catalytic domains of the CesA proteins and of the type III endo-1,4-b-glucanase are exposed at the inner [79] and outer faces of the plasma membrane [80], respectively. If synthesis proceeds from cytoplasmic substrate (UDP-Glc) to external product (cellulose), the endo-1,4-b-glucanase-dependent step will therefore follow the glycosyltransferase-dependent step.…”

Section: Organisation Of Enzymes and Products At The Plasma Membranementioning

confidence: 99%

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Cellulose synthesis: mutational analysis and genomic perspectives using Arabidopsis thaliana

Williamson

Burn

Hocart

2001

CMLS, Cell. Mol. Life Sci.

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Cellulose microfibrils containing crystalline beta-1,4-glucan provide the major structural framework in higher-plant cell walls. Genetic analyses of Arabidopsis thaliana now link specific genes to plant cellulose production just as was achieved some years earlier with bacteria. Cellulose-deficient mutants have defects in several members of one family within a complex glycosyltransferase superfamily and in one member of a small family of membrane-bound endo-1,4-beta-glucanases. The mutants also accumulate a readily extractable beta-1,4-glucan that has short chains which, in at least one case, are lipid linked. Cellulose could be made by direct extension of the glucan chain by the glycosyltransferase or, as the mutant suggests, by an indirect route which makes lipid-linked oligosaccharides. Models discussed incorporate the known enzymes and lipo-glucan and raise the possibility that different CesA glycosyltransferases may catalyse different steps.

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Immunogold Labeling of Rosette Terminal Cellulose-Synthesizing Complexes in the Vascular Plant Vigna angularis

Cited by 388 publications

References 32 publications

Biogenesis of Cellulose Nanofibrils by a Biological Nanomachine

Biogenesis of Cellulose Nanofibrils by a Biological Nanomachine

Cell Wall Polysaccharide Synthesis

Cellulose synthesis: mutational analysis and genomic perspectives using Arabidopsis thaliana

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