A single heterologously expressed plant cellulose synthase isoform is sufficient for cellulose microfibril formation in vitro

Plant cell walls are a composite material of polysaccharides, proteins, and other noncarbohydrate polymers. In the majority of plant tissues, the most abundant polysaccharide is cellulose, a linear polymer of glucose molecules. As the load-bearing component of the cell wall, individual cellulose cha...

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Published in:	Proceedings of the National Academy of Sciences - PNAS Vol. 113; no. 40; pp. 11360 - 11365
Main Authors:	Purushotham, Pallinti, Cho, Sung Hyun, Díaz-Moreno, Sara M., Kumar, Manish, Nixon, B. Tracy, Bulone, Vincent, Zimmer, Jochen
Format:	Journal Article
Language:	English
Published:	United States National Academy of Sciences 04-10-2016 Proceedings of the National Academy of Sciences
Subjects:	Amino Acid Sequence BASIC BIOLOGICAL SCIENCES bio-inspired Biocatalysis biofuels (including algae and biomass) Biological Sciences Biopolymer Biosynthesis carbon sequestration Cellulase - metabolism Cellulose Cellulose - biosynthesis Cellulose - ultrastructure Cytosol - metabolism Flowers & plants Glucose Glucosyltransferases - chemistry Glucosyltransferases - isolation & purification Glucosyltransferases - metabolism Glycosides - metabolism Glycosyltransferase Hydrolysis Isoenzymes - chemistry Isoenzymes - metabolism Kinetics Lipids - chemistry Mass Spectrometry materials and chemistry by design membrane Membrane transport Microfibrils - metabolism Microfibrils - ultrastructure Molecules Mutagenesis Plant cell wall Plant Proteins - chemistry Plant Proteins - isolation & purification Plant Proteins - metabolism Populus - enzymology Protein Domains Proteins Recombinant Proteins - chemistry Recombinant Proteins - isolation & purification Sequence Alignment synthesis (self-assembly) Time Factors biopolymer membrane transport cellulose glycosyltransferase plant cell wall
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Summary:	Plant cell walls are a composite material of polysaccharides, proteins, and other noncarbohydrate polymers. In the majority of plant tissues, the most abundant polysaccharide is cellulose, a linear polymer of glucose molecules. As the load-bearing component of the cell wall, individual cellulose chains are frequently bundled into micro and macrofibrils and are wrapped around the cell. Cellulose is synthesized by membrane-integrated and processive glycosyltransferases that polymerize UDP-activated glucose and secrete the nascent polymer through a channel formed by their own transmembrane regions. Plants express several different cellulose synthase isoforms during primary and secondary cell wall formation; however, so far, none has been functionally reconstituted in vitro for detailed biochemical analyses. Here we report the heterologous expression, purification, and functional reconstitution of Populus tremula x tremuloides CesA8 (PttCesA8), implicated in secondary cell wall formation. The recombinant enzyme polymerizes UDP-activated glucose to cellulose, as determined by enzyme degradation, permethylation glycosyl linkage analysis, electron microscopy, and mutagenesis studies. Catalytic activity is dependent on the presence of a lipid bilayer environment and divalent manganese cations. Further, electron microscopy analyses reveal that PttCesA8 produces cellulose fibers several micrometers long that occasionally are capped by globular particles, likely representing PttCesA8 complexes. Deletion of the enzyme’s N-terminal RING-finger domain almost completely abolishes fiber formation but not cellulose biosynthetic activity. Our results demonstrate that reconstituted PttCesA8 is not only sufficient for cellulose biosynthesis in vitro but also suffices to bundle individual glucan chains into cellulose microfibrils.
Bibliography:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23 USDOE Office of Science (SC), Basic Energy Sciences (BES) SC0001090 Author contributions: P.P. and J.Z. designed all biochemical experiments; S.H.C., M.K., and B.T.N. designed all EM experiments; S.M.D.-M. and V.B. designed the linkage analysis experiments; P.P., S.H.C., and S.M.D.-M. performed all experiments; P.P., S.H.C., S.M.D.-M., M.K., B.T.N., V.B., and J.Z. contributed to analyzing and writing the manuscript. Edited by Chris R. Somerville, University of California, Berkeley, CA, and approved August 9, 2016 (received for review April 18, 2016)
ISSN:	0027-8424 1091-6490 1091-6490
DOI:	10.1073/pnas.1606210113