Interaction between Wall Deposition and Cell Elongation in Dark-Grown Hypocotyl Cells in Arabidopsis

Refrégier, Guislaine; Pelletier, Sandra; Jaillard, Danielle; Höfte, Monica

doi:10.1104/pp.104.038711

Cited by 163 publications

(173 citation statements)

References 37 publications

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“…The growing stem cells apparently coordinate growth with these cellular processes more closely than do Arabidopsis hypocotyls (Refrégier et al, 2004), whose cell walls thinned during elongation, or pea (Pisum sativum) epicotyls (Cosgrove and Cleland, 1983), whose cell osmotic pressure declined slightly along the elongation zone. The last two examples notwithstanding, plant cell growth is generally well coordinated with the production of cellular materials needed for mechanical stability, and the Arabidopsis inflorescence is a fine example of such coordination.…”

Section: Discussionmentioning

confidence: 99%

Gradients in Wall Mechanics and Polysaccharides along Growing Inflorescence Stems

et al. 2017

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At early stages of Arabidopsis (Arabidopsis thaliana) flowering, the inflorescence stem undergoes rapid growth, with elongation occurring predominantly in the apical ;4 cm of the stem. We measured the spatial gradients for elongation rate, osmotic pressure, cell wall thickness, and wall mechanical compliances and coupled these macroscopic measurements with molecular-level characterization of the polysaccharide composition, mobility, hydration, and intermolecular interactions of the inflorescence cell wall using solid-state nuclear magnetic resonance spectroscopy and small-angle neutron scattering. Force-extension curves revealed a gradient, from high to low, in the plastic and elastic compliances of cell walls along the elongation zone, but plots of growth rate versus wall compliances were strikingly nonlinear. Neutron-scattering curves showed only subtle changes in wall structure, including a slight increase in cellulose microfibril alignment along the growing stem. In contrast, solid-state nuclear magnetic resonance spectra showed substantial decreases in pectin amount, esterification, branching, hydration, and mobility in an apical-to-basal pattern, while the cellulose content increased modestly. These results suggest that pectin structural changes are connected with increases in pectin-cellulose interaction and reductions in wall compliances along the apical-to-basal gradient in growth rate. These pectin structural changes may lessen the ability of the cell wall to undergo stress relaxation and irreversible expansion (e.g. induced by expansins), thus contributing to the growth kinematics of the growing stem.

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Section: Discussionmentioning

confidence: 99%

Gradients in Wall Mechanics and Polysaccharides along Growing Inflorescence Stems

et al. 2017

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“…sis was observed in pom1-21 mutant seedlings compared to the wild type (Mouille et al, 2003), (2) incomplete cell walls were observed in elp1 inflorescence stems (Zhong et al, 2002), and (3) AtCTL1 expression is highly coordinated with cellulose synthesis in primary walls, based on the expression patterns of cellulose synthases CESA1, CESA3, and CESA6 (Persson et al, 2005). Interestingly, mutations in CESA3 and CESA6 but also in KORRIGAN1 (KOR1)/RADIALLY SWOLLEN2, encoding a membrane-bound endo-1,4-b-D-glucanase, lead to similar reductions of PR growth and, to some extent, radial swelling as described in the arm mutant (Hauser et al, 1995;Fagard et al, 2000;Desprez et al, 2002;CanoDelgado et al, 2003;Refregier et al, 2004;Hématy et al, 2007). Therefore, we tested the effect of nitrate availability in the growth medium on the CESA3 (eli1-1), CESA6 (prc1-1), and KOR1 (kor1-1) mutant phenotypes (Fig.…”

Section: The Phenotype Of Cellulose Biosynthesis Mutants Is Conditionmentioning

confidence: 99%

Chitinase-Like Protein CTL1 Plays a Role in Altering Root System Architecture in Response to Multiple Environmental Conditions

et al. 2009

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Plant root architecture is highly responsive to changes in nutrient availability. However, the molecular mechanisms governing the adaptability of root systems to changing environmental conditions is poorly understood. A screen for abnormal root architecture responses to high nitrate in the growth medium was carried out for a population of ethyl methanesulfonatemutagenized Arabidopsis (Arabidopsis thaliana). The growth and root architecture of the arm (for anion altered root morphology) mutant described here was similar to wild-type plants when grown on low to moderate nitrate concentrations, but on high nitrate, arm exhibited reduced primary root elongation, radial swelling, increased numbers of lateral roots, and increased root hair density when compared to the wild-type control. High concentrations of chloride and sucrose induced the same phenotype. In contrast, hypocotyl elongation in the dark was decreased independently of nitrate availability. Positional cloning identified a point mutation in the AtCTL1 gene that encodes a chitinase-related protein, although molecular and biochemical analysis showed that this protein does not possess chitinase enzymatic activity. CTL1 appears to play two roles in plant growth and development based on the constitutive effect of the arm mutation on primary root growth and its conditional impact on root architecture. We hypothesize that CTL1 plays a role in determining cell wall rigidity and that the activity is differentially regulated by pathways that are triggered by environmental conditions. Moreover, we show that mutants of some subunits of the cellulose synthase complex phenocopy the conditional effect on root architecture under nonpermissive conditions, suggesting they are also differentially regulated in response to a changing environment.

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“…Microtubules have been shown to guide the movements of cellulose synthesizing enzymes along the plasma membrane of Arabidopsis hypocotyl cells (Paredez et al, 2006) and so the fact that microtubule bundles undergo rotary movements themselves is likely to be fundamentally important for the organization of cellulose microfibrils in the cell wall (Giddings and Staehelin, 1991). Rotation might explain the helicoidal wall structure of hypocotyl (Refré gier et al, 2004) and stem (Hejnowicz, 2005) epidermal cells, in which cellulose microfibrils are arranged in layers that progressively change angle like the steps of a spiral staircase. Microtubule rotation may not, however, be a feature of other cells, such as elongating root cells, in which microtubules are organized in transverse alignments (Sugimoto et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

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

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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Interaction between Wall Deposition and Cell Elongation in Dark-Grown Hypocotyl Cells in Arabidopsis

Cited by 163 publications

References 37 publications

Gradients in Wall Mechanics and Polysaccharides along Growing Inflorescence Stems

Gradients in Wall Mechanics and Polysaccharides along Growing Inflorescence Stems

Chitinase-Like Protein CTL1 Plays a Role in Altering Root System Architecture in Response to Multiple Environmental Conditions

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

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