Summary
The dynamic changes in microfibril architecture in the internode cell walls of the giant unicellular algaNitella translucens were studied during cell expansion. Thin section electron microscopy in conjunction with mild matrix polysaccharide extraction techniques revealed three distinct architectural zones in the walls of fully grown cells. These zones were related to distinct phases of growth by monitoring changes in cell wall architecture of internodes during active cell expansion. The initial microfibril deposition before the onset of active cell growth is helicoidal. A helicoid is a structurally complex but ordered arrangement of microfibrils that has been detected increasingly often in higher plant cell walls. During active cell elongation microfibrils are deposited transversely to the direction of cell elongation as shown in earlier studies by birefringence measurements in the polarizing microscope. The gradual decline in cell elongation corresponds with a final helicoidal deposition which continues after cell expansion ceases entirely.
The continual presence of the initial helicoidal zone in the outer wall region during the whole growth process suggests that these microfibrils do not experience strain reorientation and are continually reorganized, or maintained, in a well ordered helicoidal arrangement.
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Levy, S. Two separate zones of helicoidally orientated microfibrils are present in the walls ofNitella internodes during growth. Protoplasma 163, 145–155 (1991). https://doi.org/10.1007/BF01323338
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DOI: https://doi.org/10.1007/BF01323338