Quantitative analysis of changes in spatial distribution and plus-end geometry of microtubules involved in plant-cell cytokinesis

doi:10.1242/jcs.02512

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JCS ePress online publication date 16 Aug 2005
doi: 10.1242/jcs.02512

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Research Article

Quantitative analysis of changes in spatial distribution and plus-end geometry of microtubules involved in plant-cell cytokinesis

Jotham R. Austin II^*, José M. Seguí-Simarro, and L. Andrew Staehelin
^* Author for correspondence (e-mail: jotham.austinii{at}colorado.edu)

The cell plate of higher plants is formed within a ribosome-excludingcell plate assembly matrix. Phragmoplast microtubules facilitatecell-plate formation by forming a scaffold that directs Golgi-derivedvesicles to the forming cell plate. Here, we analyse the effectsof the cell-plate assembly matrix on phragmoplast microtubuleplus-end geometry by electron tomography of cryogenically fixedArabidopsis meristem cells. Five distinct microtubules plus-endgeometries are seen - blunt, extended, horned, flared and hybridextended/horned. We have quantified and mapped these types ofplus-end morphology during the different stages of cell-plateformation and analysed the effects of cell-plate assembly matrixassociation on microtubule plus-end morphologies. Our resultsshow that somatic-type phragmoplast microtubules do not interdigitateat the cell plate mid-line. The cell-plate assembly matrix isshown to stabilize microtubule plus ends, as evidenced by thefact that of these microtubules that do not terminate in sucha matrix, 40-80% are horn-shaped (shrinking), whereas of thosethat end in such a matrix, 50-70% are blunt (metastable). Also,a third of the blunt-ended microtubules within the cell-plateassembly matrix end at a distance of $~$ 30 nm from the cell plate.

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