Mechanical stress contributes to the expression of the STM homeobox gene in Arabidopsis shoot meristems

Landrein, Benoît; Kiss, Annamária; Sassi, Massimiliano; Chauvet, Aurélie; Das, Pradeep; Cortizo, Millán; Laufs, Patrick; Takeda, Seiji; Aida, Mitsuhiro; Traas, Jan; Vernoux, Teva; Boudaoud, Arezki; Hamant, Olivier

doi:10.7554/elife.07811

Cited by 136 publications

(121 citation statements)

References 86 publications

Supporting

Mentioning

114

Contrasting

Order By: Relevance

“…We recently showed that mechanical perturbations in the form of ablation in the SAM is sufficient to induce CUC3 expression in the SAM, while CUC1 expression profile remains largely unaffected in the same conditions. 26 Here we further confirm this result: No significant induction of signal or change in signal patterning was detected in the pCUC1:: CUC1-GFP line after ablation (Fig. 1C upper panels).…”

supporting

confidence: 76%

“…4,15,32 A key question for the future is the analysis of the interplay between mechanical forces and the molecular regulators of meristem function (Fig. 1A).In a recent article, 26 we showed that a master regulator of meristem maintenance, the homeodomain protein SHOOT MERISTEMLESS (STM) is expressed at a higher level in the boundary domain, and that this local increase in promoter activity can be related to mechanical stress: mechanical perturbations are sufficient to induce STM expression in the meristem. Interestingly, mechanical perturbations do not affect all boundary-expressed genes in the same way.…”

mentioning

confidence: 99%

“…For instance, the promoter activity of the PINOID gene, which is also increased in the boundary domain, is not affected by mechanical perturbations. 26 Here we focus on the most canonical genetic markers of boundary identity, the CUP SHAPED COTYLEDON (CUC) genes. CUC1, CUC2 and CUC3, belong to a group of NAC domain transcription factors and show a high level of functional redundancy.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Interplay between miRNA regulation and mechanical stress forCUCgene expression at the shoot apical meristem

Fal

Landrein

Hamant

2016

Plant Signaling & Behavior

Self Cite

View full text Add to dashboard Cite

The shoot apical meristem is the central organizer of plant aerial organogenesis. The molecular bases of its functions involve several cross-talks between transcription factors, hormones and microRNAs. We recently showed that the expression of the homeobox transcription factor STM is induced by mechanical perturbations, adding another layer of complexity to this regulation. Here we provide additional evidence that mechanical perturbations impact the promoter activity of CUC3, an important regulator of boundary formation at the shoot meristem. Interestingly, we did not detect such an effect for CUC1. This suggests that the robustness of expression patterns and developmental programs is controlled via a combined action of molecular factors as well as mechanical cues in the shoot apical meristem. KEYWORDSCUC genes; mechanical stress; Meristem; micro-RNAs Throughout their lifetime, plants are exposed to a number of external mechanical perturbations, such as wind or touch. This leads to changes in mRNA level of many genes, and long-term developmental responses such as stem thickening and flowering delay 5 In addition to these external factors, plants are also constantly affected by intrinsic tensile stresses, notably because plant cells are under high turgor pressure. There is now accumulating evidence that these internal stresses are affecting many aspects of the cells, thus channeling growth in the long term.14 The shoot apical meristem (SAM) is the central organizer of plant aerial organogenesis. Initiation of new organs and maintenance of SAM is achieved through the concomitant action of multiple regulatory pathways. Genetic screens have identified many key players, including transcription factors, hormones, and microRNAs. 38,48,53,55 In addition to these biochemical factors, mechanical forces are also present within the meristem. In particular, the boundary domain that separates newly emerging organ from the meristem is under highly anisotropic tensile stresses. 4,15,32 A key question for the future is the analysis of the interplay between mechanical forces and the molecular regulators of meristem function (Fig. 1A).In a recent article, 26 we showed that a master regulator of meristem maintenance, the homeodomain protein SHOOT MERISTEMLESS (STM) is expressed at a higher level in the boundary domain, and that this local increase in promoter activity can be related to mechanical stress: mechanical perturbations are sufficient to induce STM expression in the meristem. Interestingly, mechanical perturbations do not affect all boundary-expressed genes in the same way. For instance, the promoter activity of the PINOID gene, which is also increased in the boundary domain, is not affected by mechanical perturbations. 26Here we focus on the most canonical genetic markers of boundary identity, the CUP SHAPED COTYLEDON (CUC) genes. CUC1, CUC2 and CUC3, belong to a group of NAC domain transcription factors and show a high level of functional redundancy. They play an essential role in shoot meristem initiation throug...

show abstract

supporting

confidence: 76%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Interplay between miRNA regulation and mechanical stress forCUCgene expression at the shoot apical meristem

Fal

Landrein

Hamant

2016

Plant Signaling & Behavior

Self Cite

View full text Add to dashboard Cite

show abstract

“…Stacks of 1,024 × 1,024 pixels of three dissected meristems, with Z slices every 0.5 μm, were acquired every 12 h during 48 h on a Zeiss LSM 700 upright confocal microscope, with a 40× water-dipping lens. Stacks from the kinetics were processed with a C++ script, using the Level Set method (45) to detect the surface of the meristem at high resolution. Meshes of these surfaces were then created with MorphoGraphX (17,46).…”

Section: A Mechanical Division Rule Provides Better Predictions For Dmentioning

confidence: 99%

Cell division plane orientation based on tensile stress inArabidopsis thaliana

Louveaux

Julien

Mirabet

et al. 2016

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

Self Cite

159

155

View full text Add to dashboard Cite

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.cell division plane | mechanical forces | meristem | vertex model | Arabidopsis

show abstract

“…Thus, the lock on organ identity probably resides in the final pattern of the meristematic tissues. It might be encoded in the tensile stress networks that characterize different cell arrangements as mechanical forces regulate key meristem factors including STM (Landrein et al, 2015). Alternatively, the size and shape of the lateral organ might alter the distribution of morphogens or the penetration of exogenous cytokinin, as well as other compounds, which control meristem functions.…”

Section: What Locks Organ Identity?mentioning

confidence: 99%

Direct conversion of root primordium into shoot meristem relies on timing of stem cell niche development

et al. 2017

View full text Add to dashboard Cite

To understand how the identity of an organ can be switched, we studied the transformation of lateral root primordia (LRP) into shoot meristems in Arabidopsis root segments. In this system, the cytokinininduced conversion does not involve the formation of callus-like structures. Detailed analysis showed that the conversion sequence starts with a mitotic pause and is concomitant with the differential expression of regulators of root and shoot development. The conversion requires the presence of apical stem cells, and only LRP at stages VI or VII can be switched. It is engaged as soon as cell divisions resume because their position and orientation differ in the converting organ compared with the undisturbed emerging LRP. By alternating auxin and cytokinin treatments, we showed that the root and shoot organogenetic programs are remarkably plastic, as the status of the same plant stem cell niche can be reversed repeatedly within a set developmental window. Thus, the networks at play in the meristem of a root can morph in the span of a couple of cell division cycles into those of a shoot, and back, through transdifferentiation.

show abstract

Mechanical stress contributes to the expression of the STM homeobox gene in Arabidopsis shoot meristems

Cited by 136 publications

References 86 publications

Interplay between miRNA regulation and mechanical stress forCUCgene expression at the shoot apical meristem

Interplay between miRNA regulation and mechanical stress forCUCgene expression at the shoot apical meristem

Cell division plane orientation based on tensile stress inArabidopsis thaliana

Direct conversion of root primordium into shoot meristem relies on timing of stem cell niche development

Contact Info

Product

Resources

About