Autoreproductive cells and plant meristem construction: The case of the tomato cap meristem

Barlow, PW; Lück, Hermann B.; Lück, Jacqueline

doi:10.1007/bf01280303

Cited by 10 publications

(12 citation statements)

References 13 publications

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“…The result is that the extra cells are eventually squeezed out from the initial ring. It is interesting to note that the apparent excess of anticlinal divisions in the initial cells would be expected if the cells conformed to a deterministic division programme, such as has been postulated for a similar autoreproductive system by Barlow et al . (2001).…”

Section: Discussionmentioning

confidence: 79%

“…In the earlier study of Barlow et al . (2001) it was proposed that the direction of cell production was determined according to the states attached to the walls of the dividing cell and that, following such a production, these states altered according to a definite sequence that could be codified as a set of directed production rules.…”

Section: Discussionmentioning

confidence: 83%

“…(In a periclinal division, the new division wall is orientated parallel to the cambial perimeter.) The initials are autoreproductive stem cells (Barlow 1997; Barlow et al . 2001) and are designated as a cells.…”

Section: Introductionmentioning

confidence: 99%

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Estimation of directional division frequencies in vascular cambium and in marginal meristematic cells of plants

2002

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Using simple arithmetical formulae, it is shown that, when the meristematic initial cells of a growing plant organ are arranged in a ring, the cellular dimensions predict the relative frequencies of anticlinal and periclinal divisions which these cells undergo. The pattern of cell file branching which appears during the course of development, and which is predicted by this mathematical model, is validated using data pertaining to the numbers and dimensions of initial cells within the secondary vascular cambium of hybrid aspen trees. Data pertaining to a second, simpler set of initial cells which comprises the outer cellular ring of the thallus of the alga Coleochaete orbicularis, and from which all the radial cell files of the circular disc-like thallus are descended, have also been used for model validation. Combining the mathematical approach to division frequencies with data of actual cell sizes permits inferences about the course of the increase of the number of cell files (generated by the anticlinal divisions) and the number of cells within each file (generated by the periclinal divisions) during the earlier stages of secondary tissue or thallus development, and also about how they will develop at future stages. The question whether or not cell division patterns conform to the geometry of the system in which the cells are embedded is also discussed.

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Section: Discussionmentioning

confidence: 79%

Section: Discussionmentioning

confidence: 83%

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Estimation of directional division frequencies in vascular cambium and in marginal meristematic cells of plants

2002

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“…In this aspect both shoot and root apices possessing one or more apical cells were investigated (Barlow et al 2000, 2001). Such analysis does not need simulation performed at the organ level.…”

Section: Discussionmentioning

confidence: 99%

The simulation model of growth and cell divisions for the root apex with an apical cell in application to Azolla pinnata

Piekarska-Stachowiak

Nakielski

2013

Planta

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In contrast to seed plants, the roots of most ferns have a single apical cell which is the ultimate source of all cells in the root. The apical cell has a tetrahedral shape and divides asymmetrically. The root cap derives from the distal division face, while merophytes derived from three proximal division faces contribute to the root proper. The merophytes are produced sequentially forming three sectors along a helix around the root axis. During development, they divide and differentiate in a predictable pattern. Such growth causes cell pattern of the root apex to be remarkably regular and self-perpetuating. The nature of this regularity remains unknown. This paper shows the 2D simulation model for growth of the root apex with the apical cell in application to Azolla pinnata. The field of growth rates of the organ, prescribed by the model, is of a tensor type (symplastic growth) and cells divide taking principal growth directions into account. The simulations show how the cell pattern in a longitudinal section of the apex develops in time. The virtual root apex grows realistically and its cell pattern is similar to that observed in anatomical sections. The simulations indicate that the cell pattern regularity results from cell divisions which are oriented with respect to principal growth directions. Such divisions are essential for maintenance of peri-anticlinal arrangement of cell walls and coordinated growth of merophytes during the development. The highly specific division program that takes place in merophytes prior to differentiation seems to be regulated at the cellular level.Electronic supplementary materialThe online version of this article (doi:10.1007/s00425-013-1950-9) contains supplementary material, which is available to authorized users.

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“…This condition appropriate to the research of [4] and the structural evidence obtained in studies of different root types indicates that the roots are effective in water and nutrient absorption. [34] describe a pattern of cell division in the cap meristem in detail. The regions considered were columella and flank meristem and the principles of the model may be regarded as general for the caps of roots, such as mangrove, with a closed meristem structure.…”

Section: Discussionmentioning

confidence: 99%

Characteristics of Root Caps in Four Root Types of <i>Avicennia marina</i> (Forsk.) Vierh.

Purnobasuki¹

2013

AJPS

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The anatomy of the root caps in four root types of Avicennia marina were studied using conventional histological techniques by Ligth Microscopy (LM) in order to relate their development and structure of their function as environmental adaptation in mangrove's root and to identify cellular polarities with respect to gravity. In columella cells, nuclei are located proximally. The result reveals that root caps consisted of two regions, i.e., central columella or statenchyma and peripheral regions. The columella cells (statocyte) are in the form of oval to rectangular. We also found that all root with marked gravitropism have statoliths that settle along different walls of that statocyte. Caps vary in form and size within root system of A. marina. The most striking feature of the root is the distinct and extensive root cap with quite long files of cells. From its shape, structure, and location, it seems clear that the root caps protects the cells under it from abrasion and assists the root in penetrating the soil.

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Autoreproductive cells and plant meristem construction: The case of the tomato cap meristem

Cited by 10 publications

References 13 publications

Estimation of directional division frequencies in vascular cambium and in marginal meristematic cells of plants

Estimation of directional division frequencies in vascular cambium and in marginal meristematic cells of plants

The simulation model of growth and cell divisions for the root apex with an apical cell in application to Azolla pinnata

Characteristics of Root Caps in Four Root Types of <i>Avicennia marina</i> (Forsk.) Vierh.

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Autoreproductive cells and plant meristem construction: The case of the tomato cap meristem

Cited by 10 publications

References 13 publications

Estimation of directional division frequencies in vascular cambium and in marginal meristematic cells of plants

Estimation of directional division frequencies in vascular cambium and in marginal meristematic cells of plants

The simulation model of growth and cell divisions for the root apex with an apical cell in application to Azolla pinnata

Characteristics of Root Caps in Four Root Types of &lt;i&gt;Avicennia marina&lt;/i&gt; (Forsk.) Vierh.

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Characteristics of Root Caps in Four Root Types of <i>Avicennia marina</i> (Forsk.) Vierh.