MicroRNA miR396 Regulates the Switch between Stem Cells and Transit-Amplifying Cells in Arabidopsis Roots

Rodríguez, Ramiro E.; Ercoli, María Florencia; Debernardi, Juan M.; Breakfield, Natalie W.; Mecchia, Martín A.; Sabatini, Martín; Cools, Toon; Veylder, Lieven De; Benfey, Philip N.; Palatnik, Javier F.

doi:10.1105/tpc.15.00452

Cited by 133 publications

(140 citation statements)

References 64 publications

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“…How are these feed-forward loops kept in check? A possible mechanism may be provided by GRF corepressors that were recently shown to control PLT levels in the root (Rodriguez et al, 2015). Here, we find that GRF2 is regulated by PLTs and bound by PLT2, suggesting a negative feedback loop for the stabilization of PLT levels.…”

Section: Discussionmentioning

confidence: 58%

“…During growth, cells undergo transitions from division toward expansion and differentiation in distinct developmental zones and interactions between plant growth factors of the auxin and cytokinin classes play an important role in this process (Heidstra and Sabatini, 2014). In addition, root meristem growth factor (RGF) peptides and their receptors (RGFRs) as well as nuclear GROWTH-REGULATING FACTOR (GRF) corepressor proteins regulate meristematic activity by influencing the activity of PLETHORA (PLT) proteins (Matsuzaki et al, 2010;Rodriguez et al, 2015;Ou et al, 2016;Shinohara et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

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The PLETHORA Gene Regulatory Network Guides Growth and Cell Differentiation in Arabidopsis Roots

et al. 2016

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Organ formation in animals and plants relies on precise control of cell state transitions to turn stem cell daughters into fully differentiated cells. In plants, cells cannot rearrange due to shared cell walls. Thus, differentiation progression and the accompanying cell expansion must be tightly coordinated across tissues. PLETHORA (PLT) transcription factor gradients are unique in their ability to guide the progression of cell differentiation at different positions in the growing Arabidopsis thaliana root, which contrasts with well-described transcription factor gradients in animals specifying distinct cell fates within an essentially static context. To understand the output of the PLT gradient, we studied the gene set transcriptionally controlled by PLTs. Our work reveals how the PLT gradient can regulate cell state by region-specific induction of cell proliferation genes and repression of differentiation. Moreover, PLT targets include major patterning genes and autoregulatory feedback components, enforcing their role as master regulators of organ development.

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Section: Discussionmentioning

confidence: 58%

Section: Introductionmentioning

confidence: 99%

The PLETHORA Gene Regulatory Network Guides Growth and Cell Differentiation in Arabidopsis Roots

et al. 2016

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“…These highly expressed miRNAs were of particular interest because, in Arabidopsis, miR159, miR167, and miR319 and their targets form a regulatory circuit during floral organ patterning (Rubio-Somoza and Weigel, 2013). Moreover, the miR319-TCP module directly regulates miR396 expression, which in turn represses a number of growthregulating factors (GRFs), while GRFs may repress meristem cell-promoting genes in actively proliferating cells (Schommer et al, 2014;Rodriguez et al, 2015). In wheat, the high expression levels of miR159b and miR319b were sharply down-regulated from DR to TS, while miR396e remained low in the first three stages and was significantly increased (.50-fold) in TS ( Fig.…”

Section: Mirnas In Early Wheat Inflorescence Developmentmentioning

confidence: 97%

Transcriptome Profiling of Wheat Inflorescence Development from Spikelet Initiation to Floral Patterning Identified Stage-Specific Regulatory Genes

et al. 2017

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Early reproductive development in cereals is crucial for final grain number per spike and hence the yield potential of the crop. To date, however, no systematic analyses of gene expression profiles during this important process have been conducted for common wheat (Triticum aestivum). Here, we studied the transcriptome profiles at four stages of early wheat reproductive development, from spikelet initiation to floral organ differentiation. K-means clustering and stage-specific transcript identification detected dynamically expressed homeologs of important transcription regulators in spikelet and floral meristems that may be involved in spikelet initiation, floret meristem specification, and floral organ patterning, as inferred from their homologs in model plants. Small RNA transcriptome sequencing discovered key microRNAs that were differentially expressed during wheat inflorescence development alongside their target genes, suggesting that miRNA-mediated regulatory mechanisms for floral development may be conserved in cereals and Arabidopsis. Our analysis was further substantiated by the functional characterization of the ARGONAUTE1d (AGO1d) gene, which was initially expressed in stamen primordia and later in the tapetum during anther maturation. In agreement with its stage-specific expression pattern, the loss of function of the predominantly expressed B homeolog of AGO1d in a tetraploid durum wheat mutant resulted in smaller anthers with more infertile pollens than the wild type and a reduced grain number per spike. Together, our work provides a first glimpse of the gene regulatory networks in wheat inflorescence development that may be pivotal for floral and grain development, highlighting potential targets for genetic manipulation to improve future wheat yields.

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“…For example, a small family of R OOT G ROWTH F ACTORS ( RGF s), which are expressed in the QC and columella, have been shown to diffuse into the proximal meristem and positively regulate growth (Matsuzaki et al, 2010; Zhou et al, 2010). In addition, it was shown recently that microRNA396 , which is transcribed in the QC and columella, non-cell autonomously represses redundant G ROWTH R EGULATING F ACTOR s ( GRF s), which are localized exclusively in the proximal meristem and were shown to have a role in locally promoting division rates (Rodriguez et al, 2015; Wang et al, 2011). Both factors have been implicated in the regulation of the PL E T HORA ( PLT ) gene family (Matsuzaki et al, 2010; Wang et al, 2011), which regulates division rates and maturation state throughout the meristem (Aida et al, 2004; Galinha et al, 2007).…”

Section: Communication Between the Two Axes Of The Meristemmentioning

confidence: 99%

A Case for Distributed Control of Local Stem Cell Behavior in Plants

2016

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Summary The root meristem has a centrally located group of quiescent cells, to which current models assign a stem cell organizer function. However, evidence is emerging for decentralized control of stem cell activity, where self-renewing behavior emerges from the lack of cell displacement at the border of opposing differentiation gradients. We term this a “stagnation” model due to its reliance on passive mechanics. The position of stem cells is established by two opposing axes that reciprocally control each other’s differentiation. Such broad tissue organization programs would allow plants, like some animal systems, to rapidly reconstitute stem cells from non-stem cell tissues.

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MicroRNA miR396 Regulates the Switch between Stem Cells and Transit-Amplifying Cells in Arabidopsis Roots

Cited by 133 publications

References 64 publications

The PLETHORA Gene Regulatory Network Guides Growth and Cell Differentiation in Arabidopsis Roots

The PLETHORA Gene Regulatory Network Guides Growth and Cell Differentiation in Arabidopsis Roots

Transcriptome Profiling of Wheat Inflorescence Development from Spikelet Initiation to Floral Patterning Identified Stage-Specific Regulatory Genes

A Case for Distributed Control of Local Stem Cell Behavior in Plants

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