Jordi Chan scite author profile

In plants, it is unclear how dispersed cortical microtubules are nucleated, polarized and organized in the absence of centrosomes. In Arabidopsis thaliana cells, expression of a fusion between the microtubule-end-binding protein AtEB1a and green fluorescent protein (GFP) results in labelling of spindle poles, where minus ends gather. During interphase, AtEB1a-GFP labels the microtubule plus end as a comet, but also marks the minus end as a site from which microtubules can grow and shrink. These minus-end nucleation sites are mobile, explaining how the cortical array can redistribute during the cell cycle and supporting the idea of a flexible centrosome in plants.

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ArabidopsisCortical Microtubules Are Initiated along, as Well as Branching from, Existing Microtubules

Chan

et al. 2009

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The principles by which cortical microtubules self-organize into a global template hold important implications for cell wall patterning. Microtubules move along bundles of microtubules, and neighboring bundles tend to form mobile domains that flow in a common direction. The bundles themselves move slowly and for longer than the individual microtubules, with domains describing slow rotary patterns. Despite this tendency for colinearity, microtubules have been seen to branch off extant microtubules at ;458. To examine this paradoxical behavior, we investigated whether some microtubules may be born on and grow along extant microtubule(s). The plus-end markers Arabidopsis thaliana end binding protein 1a, AtEB1a-GFP, and Arabidopsis SPIRAL1, SPR1-GFP, allowed microtubules of known polarity to be distinguished from underlying microtubules. This showed that the majority of microtubules do branch but in a direction heavily biased toward the plus end of the mother microtubule: few grow backward, consistent with the common polarity of domains. However, we also found that a significant proportion of emergent comets do follow the axes of extant microtubules, both at sites of apparent microtubule nucleation and at cross-over points. These phenomena help explain the persistence of bundles and counterbalance the tendency to branch.

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Cortical microtubule arrays undergo rotary movements in Arabidopsis hypocotyl epidermal cells

et al. 2007

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Plant-cell expansion is controlled by cellulose microfibrils in the wall with microtubules providing tracks for cellulose synthesizing enzymes. Microtubules can be reoriented experimentally and are hypothesized to reorient cyclically in aerial organs, but the mechanism is unclear. Here, Arabidopsis hypocotyl microtubules were labelled with AtEB1a-GFP (Arabidopsis microtubule end-binding protein 1a) or GFP-TUA6 (Arabidopsis alpha-tubulin 6) to record long cycles of reorientation. This revealed microtubules undergoing previously unseen clockwise or counter-clockwise rotations. Existing models emphasize selective shrinkage and regrowth or the outcome of individual microtubule encounters to explain realignment. Our higher-order view emphasizes microtubule group behaviour over time. Successive microtubules move in the same direction along self-sustaining tracks. Significantly, the tracks themselves migrate, always in the direction of the individual fast-growing ends, but twentyfold slower. Spontaneous sorting of tracks into groups with common polarities generates a mosaic of domains. Domains slowly migrate around the cell in skewed paths, generating rotations whose progressive nature is interrupted when one domain is displaced by collision with another. Rotary movements could explain how the angle of cellulose microfibrils can change from layer to layer in the polylamellate cell wall.

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The 65-kDa carrot microtubule-associated protein forms regularly arranged filamentous cross-bridges between microtubules

Chan

Jensen

et al. 1999

Proc. Natl. Acad. Sci. U.S.A.

171

152

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In plants, cortical microtubules (MTs) occur in characteristically parallel groups maintained up to one microtubule diameter apart by fine filamentous cross-bridges. However, none of the plant microtubule-associated proteins (MAPs) so far purified accounts for the observed separation between MTs in cells. We previously isolated from carrot cytoskeletons a MAP fraction including 120-and 65-kDa MAPs and have now separated the 65-kDa carrot MAP by sucrose density centrifugation. MAP65 does not induce tubulin polymerization but induces the formation of bundles of parallel MTs in a nucleotide-insensitive manner. The bundling effect is inhibited by porcine MAP2, but, unlike MAP2, MAP65 is heat-labile. In the electron microscope, MAP65 appears as filamentous crossbridges, maintaining an intermicrotubule spacing of 25-30 nm. Microdensitometer-computer correlation analysis reveals that the cross-bridges are regularly spaced, showing a regular axial spacing that is compatible with a symmetrical helical superlattice for 13 protofilament MTs. Because MAP65 maintains in vitro the inter-MT spacing observed in plants and is shown to decorate cortical MTs, it is proposed that this MAP is important for the organization of the cortical array in vivo.A distinctive feature of the cortical array in higher plants is the parallelism of the microtubules (MTs). Electron microscopy (EM) studies show that the array is composed of overlapping MTs that can maintain a parallel relationship over several micrometers (1, 2). Averaged over the entire cell, this degree of order allows the directionality of the entire array to be summarized as ''one cell: one microtubule alignment'' (3) that can be transverse to the cell's long axis or oblique or longitudinal. Immunofluorescence studies show that most cells have organized arrays, with only a few percent being random (3, 4). The factor responsible for this spacing is, therefore, an important element in contributing to the large-scale organization and integrity of the array (5). It is also likely to be involved in channeling the movement of the plasma membranous cellulose synthesizing particles (6).At the EM level, MTs are commonly seen to occur in parallel groups interconnected by filamentous cross-bridges with lengths approximating the diameter of the MTs (1, 2, 7, 8). Several attempts have been made to isolate these filamentous microtubule-associated proteins (MAPs). Cyr and Palevitz (9) found that high speed supernatants from carrot suspension cells caused the bundling of MTs in vitro, with a center-center spacing of 34 nm. A maize MAP fraction containing a range of proteins that also causes MT bundling has been described (10). Jiang et al. (11) showed that a crude cytoplasmic extract from evacuolated tobacco protoplasts bundled MTs with cross-links of two different lengths: 20-25 and 12-15 nm. Later, Jiang and Sonobe (12) used this cytosolic extract to isolate a group of 65-kDa microtubule-associated proteins. Although these proteins induced bundling, they did not form the longer, 20-to 25-nm...

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Jordi Chan

EB1 reveals mobile microtubule nucleation sites in Arabidopsis

ArabidopsisCortical Microtubules Are Initiated along, as Well as Branching from, Existing Microtubules

Cortical microtubule arrays undergo rotary movements in Arabidopsis hypocotyl epidermal cells

The 65-kDa carrot microtubule-associated protein forms regularly arranged filamentous cross-bridges between microtubules

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