Imaging cellulose synthase motility during primary cell wall synthesis in the grass Brachypodium distachyon.
Derui LiuNina ZehfrooshBrandon L HancockKevin HinesWenjuan FangMaria KilfoilErik Learned-MillerKaren A SanguinetLori S GoldnerTobias I BaskinPublished in: Scientific reports (2017)
The mechanism of cellulose synthesis has been studied by characterizing the motility of cellulose synthase complexes tagged with a fluorescent protein; however, this approach has been used exclusively on the hypocotyl of Arabidopsis thaliana. Here we characterize cellulose synthase motility in the model grass, Brachypodium distachyon. We generated lines in which mEGFP is fused N-terminal to BdCESA3 or BdCESA6 and which grew indistinguishably from the wild type (Bd21-3) and had dense fluorescent puncta at or near the plasma membrane. Measured with a particle tracking algorithm, the average speed of GFP-BdCESA3 particles in the mesocotyl was 164 ± 78 nm min-1 (error gives standard deviation [SD], n = 1451 particles). Mean speed in the root appeared similar. For comparison, average speed in the A. thaliana hypocotyl expressing GFP-AtCESA6 was 184 ± 86 nm min-1 (n = 2755). For B. distachyon, we quantified root diameter and elongation rate in response to inhibitors of cellulose (dichlorobenylnitrile; DCB), microtubules (oryzalin), or actin (latrunculin B). Neither oryzalin nor latrunculin affected the speed of CESA complexes; whereas, DCB reduced average speed by about 50% in B. distachyon and by about 35% in A. thaliana. Evidently, between these species, CESA motility is well conserved.
Keyphrases
- cell wall
- ionic liquid
- biofilm formation
- arabidopsis thaliana
- wild type
- aqueous solution
- silver nanoparticles
- photodynamic therapy
- machine learning
- high resolution
- transcription factor
- staphylococcus aureus
- living cells
- pseudomonas aeruginosa
- candida albicans
- deep learning
- small molecule
- escherichia coli
- amino acid
- protein protein
- neural network
- cystic fibrosis
- optic nerve
- cell migration