Callose Biosynthesis Regulates Symplastic Trafficking during Root Development

Vatén, Anne; Dettmer, Jan; Wu, Shuang; Stierhof, York‐Dieter; Miyashima, Shunsuke; Yadav, Shri Ram; Roberts, Christina; Campilho, Ana; Bulone, Vincent; Lichtenberger, Raffael; Lehesranta, Satu; Mähönen, Ari Pekka; Kim, Jae‐Yean; Jokitalo, Eija; Sauer, Norbert; Scheres, Ben; Nakajima, Keiji; Carlsbecker, Annelie; Gallagher, Kimberly L.; Helariutta, Yrjö

doi:10.1016/j.devcel.2011.10.006

Cited by 389 publications

(427 citation statements)

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“…n represents the number of roots counted; numbers are average and SD. BIRDs Control Tissue Boundariesin the procambial region of the vascular tissue (Bonke et al, 2003;Vatén et al, 2011), where SHR is both nuclear and cytoplasmic ( Figures 3A and 3A'). Expression of SCR in the vasculature directed nuclear SHR retention, consistent with a previous report (Koizumi et al, 2012;Figures 3B and 3B').…”

Section: Bib and Jkd Cooperate With Scr To Retain Shr In The Nucleusmentioning

confidence: 99%

“…The HEAT domain protein SHR INTERACTING EMBRYONIC LETHAL was suggested to facilitate SHR movement through an endosome-and microtubule-dependent process (Koizumi et al, 2011;Wu and Gallagher, 2013). In addition, callose accumulation at plasmodesmata, symplastic channels that allow passage of hormones, proteins, and RNAs (Du et al, 2007;Schlereth et al, 2010;Matsuzaki et al, 2010), results in plasmodesmata closure and reduces SHR intercellular trafficking (Vatén et al, 2011). Furthermore, nuclear targeting of SHR by fusing a nuclear localization signal or by expressing SCR in the vasculature blocks SHR movement (Gallagher et al, 2004;Koizumi et al, 2012), suggesting that nuclear retention determines the range of SHR movement.…”

Section: Introductionmentioning

confidence: 99%

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Arabidopsis BIRD Zinc Finger Proteins Jointly Stabilize Tissue Boundaries by Confining the Cell Fate Regulator SHORT-ROOT and Contributing to Fate Specification

et al. 2015

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Plant cells cannot rearrange their positions; therefore, sharp tissue boundaries must be accurately programmed. Movement of the cell fate regulator SHORT-ROOT from the stele to the ground tissue has been associated with transferring positional information across tissue boundaries. The zinc finger BIRD protein JACKDAW has been shown to constrain SHORT-ROOT movement to a single layer, and other BIRD family proteins were postulated to counteract JACKDAW's role in restricting SHORT-ROOT action range. Here, we report that regulation of SHORT-ROOT movement requires additional BIRD proteins whose action is critical for the establishment and maintenance of the boundary between stele and ground tissue. We show that BIRD proteins act in concert and not in opposition. The exploitation of asymmetric redundancies allows the separation of two BIRD functions: constraining SHORT-ROOT spread through nuclear retention and transcriptional regulation of key downstream SHORT-ROOT targets, including SCARECROW and CYCLIND6. Our data indicate that BIRD proteins promote formative divisions and tissue specification in the Arabidopsis thaliana root meristem ground tissue by tethering and regulating transcriptional competence of SHORT-ROOT complexes. As a result, a tissue boundary is not "locked in" after initial patterning like in many animal systems, but possesses considerable developmental plasticity due to continuous reliance on mobile transcription factors.

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Section: Bib and Jkd Cooperate With Scr To Retain Shr In The Nucleusmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Arabidopsis BIRD Zinc Finger Proteins Jointly Stabilize Tissue Boundaries by Confining the Cell Fate Regulator SHORT-ROOT and Contributing to Fate Specification

et al. 2015

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“…In plants, PD are the channels mediating cell-to-cell trafficking of many macromolecules 232 including proteins and microRNA (miRNA) (Vatén et al, 2011). To verify that the 233 punctate foci of FT SL24 mRNA were PD, we examined co-localization of FT SL24 mRNA 234 and PD markers.…”

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confidence: 99%

“…To verify that the 233 punctate foci of FT SL24 mRNA were PD, we examined co-localization of FT SL24 mRNA 234 and PD markers. Aniline blue fluorophore (ABF) is a widely used PD marker that stains 235 callose located at the PD neck (Vatén et al, 2011). In ABF-stained N. benthamiana leaves 236 expressing MS2 FD -GFP and FT SL24 or RFP SL24 mRNA, FT SL24 signals co-localized with 237 co-localization analyses with FM4-64-stained plasma membrane showed FT SL24 mRNA 243 distributed as puncta on the plasma membrane (Supplemental Fig.…”

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confidence: 99%

Selective Targeting of Mobile mRNAs to Plasmodesmata for Cell-to-Cell Movement

Luo

Huang

2018

Plant Physiol.

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3 Abstract 30Many plant mRNAs move from cell to cell or long-distance to execute a 31 non-cell-autonomous functions. These mobile mRNAs traffic through the phloem to 32 regulate many developmental processes, but despite the burgeoning discovery of mobile 33 mRNAs, little is known about the mechanism underlying the intracellular sorting of these 34 mRNAs. Here, we exploited a fluorescence-based mRNA labeling system, using the 35 bacteriophage coat protein MS2, fused to GFP (MS2-GFP) and an MS2 recognition site 36 in the RNA of interest, to visualize the intracellular trafficking of mobile mRNAs in 37 living plant cells of Nicotiana benthamiana. We first improved this system by using the 38 nuclear localization sequence from FD, which substantially reduced the fluorescent 39 background of MS2-GFP in the cytoplasm. The modified system allowed us to observe 40

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“…In cals7 mutants reduced callose deposition at the sieve plate leads to a reduced number of open pores per sieve plate, smaller diameter sieve pores and impaired phloem transport 22,23 . But also over accumulation of callose, as shown by the phloem-specific expression of a gain of function mutant of CalS3, inhibits phloem conductivity 24 , suggesting that callose deposition at the sieve plate has to be tightly regulated. The only gene identified so far which is specifically required to establish phloem identity is altered phloem development (APL), a MYB coiled-coil-type transcription factor 25 .…”

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confidence: 99%