IQ67 DOMAIN proteins facilitate preprophase band formation and division-plane orientation

AbstractThe microtubule cytoskeleton serves as a dynamic structural framework for mitosis in eukaryotic cells. TANGLED1 (TAN1) is a microtubule-binding protein that localizes to the division site and mitotic microtubules and plays a critical role in division plane orientation in plants. Here, in vitro experiments demonstrate that TAN1 directly binds microtubules, mediating microtubule zippering or end-on microtubule interactions, depending on their contact angle. Maize tan1 mutant cells improperly position the preprophase band (PPB), which predicts the future division site. However, cell-shape-based modeling indicates that PPB positioning defects are likely a consequence of abnormal cell shapes and not due to TAN1 absence. Spindle defects in the tan1 mutant suggest that TAN1-mediated microtubule zippering may contribute to metaphase spindle organization. In telophase, co-localization of growing microtubules ends from the phragmoplast with TAN1 at the division site suggests that TAN1 interacts with microtubule tips end-on. Together, our results suggest that TAN1 contributes to spindle and phragmoplast microtubule organization to ensure proper division plane orientation.

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TANGLED1 mediates microtubule interactions that may promote division plane positioning in maize

The Journal of Cell Biology ◽

10.1083/jcb.201907184 ◽

2020 ◽

Vol 219 (8) ◽

Cited By ~ 1

Author(s):

Pablo Martinez ◽

Ram Dixit ◽

Rachappa S. Balkunde ◽

Antonia Zhang ◽

Seán E. O’Leary ◽

...

Keyword(s):

Critical Role ◽

Preprophase Band ◽

Microtubule Organization ◽

Division Plane ◽

Plane Orientation ◽

Division Site ◽

Structural Framework ◽

Cell Shapes ◽

Division Plane Orientation

The microtubule cytoskeleton serves as a dynamic structural framework for mitosis in eukaryotic cells. TANGLED1 (TAN1) is a microtubule-binding protein that localizes to the division site and mitotic microtubules and plays a critical role in division plane orientation in plants. Here, in vitro experiments demonstrate that TAN1 directly binds microtubules, mediating microtubule zippering or end-on microtubule interactions, depending on their contact angle. Maize tan1 mutant cells improperly position the preprophase band (PPB), which predicts the future division site. However, cell shape–based modeling indicates that PPB positioning defects are likely a consequence of abnormal cell shapes and not due to TAN1 absence. In telophase, colocalization of growing microtubules ends from the phragmoplast with TAN1 at the division site suggests that TAN1 interacts with microtubule tips end-on. Together, our results suggest that TAN1 contributes to microtubule organization to ensure proper division plane orientation.

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Predicting division planes of three-dimensional cells by soap-film minimization

10.1101/199885 ◽

2017 ◽

Cited By ~ 1

Author(s):

Pablo Martinez ◽

Lindy A. Allsman ◽

Kenneth A. Brakke ◽

Christopher Hoyt ◽

Jordan Hayes ◽

...

Keyword(s):

Developmental Regulation ◽

Three Dimensional ◽

Soap Film ◽

Preprophase Band ◽

Animal Cells ◽

Division Plane ◽

Plane Orientation ◽

Division Site ◽

Division Plane Orientation

AbstractOne key aspect of cell division in multicellular organisms is the orientation of the division plane. Proper division plane establishment contributes to normal organization of the plant body. To determine the importance of cell geometry in division plane orientation, we designed a threedimensional probabilistic mathematical modeling approach to directly test the century-old hypothesis that cell divisions mimic “soap-film minima” or that daughter cells have equal volume and the resulting division plane is a local surface area minimum. Predicted division planes were compared to a plant microtubule array that marks the division site, the preprophase band (PPB). PPB location typically matched one of the predicted divisions. Predicted divisions offset from the PPB occurred when a neighboring cell wall or PPB was observed directly adjacent to the predicted division site, to avoid creating a potentially structurally unfavorable four-way junction. By comparing divisions of differently shaped plant and animal cells to divisions simulated in silico, we demonstrate the generality of this model to accurately predict in vivo division. This powerful model can be used to separate the contribution of geometry from mechanical stresses or developmental regulation in predicting division plane orientation.

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Proper division plane orientation and mitotic progression together allow normal growth of maize

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1619252114 ◽

2017 ◽

Vol 114 (10) ◽

pp. 2759-2764 ◽

Cited By ~ 19

Author(s):

Pablo Martinez ◽

Anding Luo ◽

Anne Sylvester ◽

Carolyn G. Rasmussen

Keyword(s):

Cell Cycle ◽

Cell Biology ◽

Cell Cycle Progression ◽

Normal Growth ◽

Mitotic Progression ◽

Wild Type ◽

Cycle Progression ◽

Division Plane ◽

Plane Orientation ◽

Division Plane Orientation

How growth, microtubule dynamics, and cell-cycle progression are coordinated is one of the unsolved mysteries of cell biology. A maize mutant,tangled1, with known defects in growth and proper division plane orientation, and a recently characterized cell-cycle delay identified by time-lapse imaging, was used to clarify the relationship between growth, cell cycle, and proper division plane orientation. Thetangled1mutant was fully rescued by introduction of cortical division site localized TANGLED1-YFP. A CYCLIN1B destruction box was fused to TANGLED1-YFP to generate a line that mostly rescued the division plane defect but still showed cell-cycle delays when expressed in thetangled1mutant. Although an intermediate growth phenotype between wild-type and thetangled1mutant was expected, these partially rescued plants grew as well as wild-type siblings, indicating that mitotic progression delays alone do not alter overall growth. These data indicate that division plane orientation, together with proper cell-cycle progression, is critical for plant growth.

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An overview of plant division-plane orientation

New Phytologist ◽

10.1111/nph.15183 ◽

2018 ◽

Vol 219 (2) ◽

pp. 505-512 ◽

Cited By ~ 23

Author(s):

Carolyn G. Rasmussen ◽

Marschal Bellinger

Keyword(s):

Division Plane ◽

Plane Orientation ◽

Division Plane Orientation

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Cell division plane orientation based on tensile stress in Arabidopsis thaliana

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1600677113 ◽

2016 ◽

Vol 113 (30) ◽

pp. E4294-E4303 ◽

Cited By ~ 87

Author(s):

Marion Louveaux ◽

Jean-Daniel Julien ◽

Vincent Mirabet ◽

Arezki Boudaoud ◽

Olivier Hamant

Keyword(s):

Cell Division ◽

Tensile Stress ◽

Shoot Apex ◽

Boundary Region ◽

Differential Growth ◽

Division Plane ◽

Plane Orientation ◽

Maximal Tension ◽

Division Plane Orientation ◽

Cell Division Plane

Cell geometry has long been proposed to play a key role in the orientation of symmetric cell division planes. In particular, the recently proposed Besson–Dumais rule generalizes Errera’s rule and predicts that cells divide along one of the local minima of plane area. However, this rule has been tested only on tissues with rather local spherical shape and homogeneous growth. Here, we tested the application of the Besson–Dumais rule to the divisions occurring in the Arabidopsis shoot apex, which contains domains with anisotropic curvature and differential growth. We found that the Besson–Dumais rule works well in the central part of the apex, but fails to account for cell division planes in the saddle-shaped boundary region. Because curvature anisotropy and differential growth prescribe directional tensile stress in that region, we tested the putative contribution of anisotropic stress fields to cell division plane orientation at the shoot apex. To do so, we compared two division rules: geometrical (new plane along the shortest path) and mechanical (new plane along maximal tension). The mechanical division rule reproduced the enrichment of long planes observed in the boundary region. Experimental perturbation of mechanical stress pattern further supported a contribution of anisotropic tensile stress in division plane orientation. Importantly, simulations of tissues growing in an isotropic stress field, and dividing along maximal tension, provided division plane distributions comparable to those obtained with the geometrical rule. We thus propose that division plane orientation by tensile stress offers a general rule for symmetric cell division in plants.

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