Abstract

Significance StatementCellulose is a major extracellular matrix component of cells that is critical for plant development and has applications to bioenergy, agricultural food/feed, textile, and wood production. Cellulose is thought to be assembled by the closely coordinated motion of plasma membrane-embedded cellulose synthase enzyme complexes. To date, however, it has not been possible to visualize de novo plant cell wall synthesis at the single cell level with the necessary spatiotemporal resolution to derive a data-driven model of how plant cells can resynthesize and assemble cell wall after its removal. Based on our time-resolved data, we propose a new model for cellulose biosynthesis after successfully performing live protoplast time-lapse imaging to visualize for the first time the complex dynamics of de novo cellulose biosynthesis and assembly into an intertwined microfibril network. Plant cell walls are composed of polysaccharides among which cellulose is the most abundant component. Cellulose is processively synthesized as bundles of linear {beta}-1,4-glucan homopolymer chains via the coordinated action of multiple enzymes in cellulose synthase complexes (CSCs) embedded within the plasma cell membrane. Plant cell walls are composed of multiple layers of cellulose fibrils that form highly intertwined extracellular matrix networks. However, it is not yet clear as to how cellulose fibrils synthesized by multiple CSCs are assembled into the intricate cellulose network deposited on plant cell surfaces. Herein, we have established an in vivo time-resolved imaging platform for visualizing cellulose during its biosynthesis and assembly into a complex fibrillar network on the surface of Arabidopsis thaliana mesophyll protoplasts as the primary cell wall regenerates. We performed total internal reflection fluorescence microscopy (TIRFM) with fluorophore-conjugated tandem carbohydrate binding modules (tdCBMs) that were engineered to specifically bind to nascent cellulose fibrils. Together with a well-controlled environment, it was possible to monitor in vivo cellulose fibril synthesis dynamics in a time-resolved manner for nearly one day of continuous cell wall regeneration on protoplast cell surfaces. Our observations provide the basis for a novel model of cellulose fibril network development in protoplasts driven by complex interplay of multi-scale dynamics that include: rapid diffusion and coalescence of short nascently synthesized cellulose fibrils; processive elongation of single fibrils; and cellulose fibrillar network rearrangement during cell wall maturation. This platform is valuable for exploring mechanistic aspects of cell wall synthesis while visualizing cellulose microfibrils assembly.