Danae Paultre scite author profile

In plants, a complex mixture of solutes and macromolecules is transported by the phloem. Here, we examined how solutes and macromolecules are separated when they exit the phloem during the unloading process. We used a combination of approaches (non-invasive imaging, 3D-electron microscopy, and mathematical modelling) to show that phloem unloading of solutes in Arabidopsis roots occurs through plasmodesmata by a combination of mass flow and diffusion (convective phloem unloading). During unloading, solutes and proteins are diverted into the phloem-pole pericycle, a tissue connected to the protophloem by a unique class of ‘funnel plasmodesmata’. While solutes are unloaded without restriction, large proteins are released through funnel plasmodesmata in discrete pulses, a phenomenon we refer to as ‘batch unloading’. Unlike solutes, these proteins remain restricted to the phloem-pole pericycle. Our data demonstrate a major role for the phloem-pole pericycle in regulating phloem unloading in roots.DOI: http://dx.doi.org/10.7554/eLife.24125.001

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Lost in Transit: Long-Distance Trafficking and Phloem Unloading of Protein Signals in Arabidopsis Homografts

Paultre

Gustin

Molnár

et al. 2016

Plant Cell

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In addition to moving sugars and nutrients, the phloem transports many macromolecules. While grafting and aphid stylectomy experiments have identified many macromolecules that move in the phloem, the functional significance of phloem transport of these remains unclear. To gain insight into protein trafficking, we micrografted Arabidopsis thaliana scions expressing GFP-tagged chloroplast transit peptides under the 35S promoter onto nontransgenic rootstocks. We found that plastids in the root tip became fluorescent 10 d after grafting. We obtained identical results with the companion cell-specific promoter SUC2 and with signals that target proteins to peroxisomes, actin, and the nucleus. We were unable to detect the respective mRNAs in the rootstock, indicating extensive movement of proteins in the phloem. Outward movement from the root protophloem was restricted to the pericycle-endodermis boundary, identifying plasmodesmata at this interface as control points in the exchange of macromolecules between stele and cortex. Intriguingly, signals directing proteins to the endoplasmic reticulum and Golgi apparatus from membrane-bound ribosomes were not translocated to the root. It appears that many organelletargeting sequences are insufficient to prevent the loss of their proteins into the translocation stream. Thus, nonspecific loss of proteins from companion cells to sieve elements may explain the plethora of macromolecules identified in phloem sap.

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Correlative Imaging of Fluorescent Proteins in Resin-Embedded Plant Material¹

et al. 2013

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Fluorescent proteins (FPs) were developed for live-cell imaging and have revolutionized cell biology. However, not all plant tissues are accessible to live imaging using confocal microscopy, necessitating alternative approaches for protein localization. An example is the phloem, a tissue embedded deep within plant organs and sensitive to damage. To facilitate accurate localization of FPs within recalcitrant tissues, we developed a simple method for retaining FPs after resin embedding. This method is based on low-temperature fixation and dehydration, followed by embedding in London Resin White, and avoids the need for cryosections. We show that a palette of FPs can be localized in plant tissues while retaining good structural cell preservation, and that the polymerized block face can be counterstained with cell wall probes. Using this method we have been able to image green fluorescent protein-labeled plasmodesmata to a depth of more than 40 mm beneath the resin surface. Using correlative light and electron microscopy of the phloem, we were able to locate the same FP-labeled sieve elements in semithin and ultrathin sections. Sections were amenable to antibody labeling, and allowed a combination of confocal and superresolution imaging (three-dimensional-structured illumination microscopy) on the same cells. These correlative imaging methods should find several uses in plant cell biology.

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Intercellular communication via plasmodesmata

2015

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Intercellular communication is fundamental to multicellularity. In plants, plasmodesmata (PD) are membrane-lined channels that connect the cytoplasm of adjacent cells, allowing direct molecular exchange (Fig. 1). In growth, development and responses to the external environment, PD act as traffic controllers, allowing or restricting the flux of different types of molecules and the downstream processes which they trigger. The European Molecular Biology Organization (EMBO) workshop on 'Intercellular communication in plant development and disease' evolved from the PD conference series to bring together researchers who work on the trafficking of different classes of molecules in a variety of contexts. In doing so, the organizers collated some of the most exciting advances in PD research to date. Because PD are small, membranerich structures embedded in the cell wall, their study presents multiple technological challenges such that, in addition to breakthroughs in knowledge, many presenters outlined novel tools and approaches that are likely to take PD research into new realms and also provide a powerful handle to more general cell biological problems in plants.

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Author response: Phloem unloading in Arabidopsis roots is convective and regulated by the phloem-pole pericycle

Ross‐Elliott

Jensen

Haaning

et al. 2017

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Danae Paultre

Phloem unloading in Arabidopsis roots is convective and regulated by the phloem-pole pericycle

Lost in Transit: Long-Distance Trafficking and Phloem Unloading of Protein Signals in Arabidopsis Homografts

Correlative Imaging of Fluorescent Proteins in Resin-Embedded Plant Material¹

Intercellular communication via plasmodesmata

Author response: Phloem unloading in Arabidopsis roots is convective and regulated by the phloem-pole pericycle

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Danae Paultre

Phloem unloading in Arabidopsis roots is convective and regulated by the phloem-pole pericycle

Lost in Transit: Long-Distance Trafficking and Phloem Unloading of Protein Signals in Arabidopsis Homografts

Correlative Imaging of Fluorescent Proteins in Resin-Embedded Plant Material1

Intercellular communication via plasmodesmata

Author response: Phloem unloading in Arabidopsis roots is convective and regulated by the phloem-pole pericycle

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Correlative Imaging of Fluorescent Proteins in Resin-Embedded Plant Material¹