Your search keyword '"Geldner, Niko"' showing total 30 results

1. A suberized exodermis is required for tomato drought tolerance

Author

Cantó-Pastor, Alex, Kajala, Kaisa, Shaar-Moshe, Lidor, Manzano, Concepción, Timilsena, Prakash, De Bellis, Damien, Gray, Sharon, Holbein, Julia, Yang, He, Mohammad, Sana, Nirmal, Niba, Suresh, Kiran, Ursache, Robertas, Mason, G. Alex, Gouran, Mona, West, Donnelly A., Borowsky, Alexander T., Shackel, Kenneth A., Sinha, Neelima, Bailey-Serres, Julia, Geldner, Niko, Li, Song, Franke, Rochus Benni, Brady, Siobhan M., Cantó-Pastor, Alex, Kajala, Kaisa, Shaar-Moshe, Lidor, Manzano, Concepción, Timilsena, Prakash, De Bellis, Damien, Gray, Sharon, Holbein, Julia, Yang, He, Mohammad, Sana, Nirmal, Niba, Suresh, Kiran, Ursache, Robertas, Mason, G. Alex, Gouran, Mona, West, Donnelly A., Borowsky, Alexander T., Shackel, Kenneth A., Sinha, Neelima, Bailey-Serres, Julia, Geldner, Niko, Li, Song, Franke, Rochus Benni, and Brady, Siobhan M.

Abstract

Plant roots integrate environmental signals with development using exquisite spatiotemporal control. This is apparent in the deposition of suberin, an apoplastic diffusion barrier, which regulates flow of water, solutes and gases, and is environmentally plastic. Suberin is considered a hallmark of endodermal differentiation but is absent in the tomato endodermis. Instead, suberin is present in the exodermis, a cell type that is absent in the model organism Arabidopsis thaliana. Here we demonstrate that the suberin regulatory network has the same parts driving suberin production in the tomato exodermis and the Arabidopsis endodermis. Despite this co-option of network components, the network has undergone rewiring to drive distinct spatial expression and with distinct contributions of specific genes. Functional genetic analyses of the tomato MYB92 transcription factor and ASFT enzyme demonstrate the importance of exodermal suberin for a plant water-deficit response and that the exodermal barrier serves an equivalent function to that of the endodermis and can act in its place.

Published

2024

2. Spatial IMA1 regulation restricts root iron acquisition on MAMP perception

Author

National Institute of General Medical Sciences (US), National Institutes of Health (US), Salk Institute for Biological Studies, Hess Corporation, Ministry of Science and Technology (Taiwan), Human Frontier Science Program, Helmsley Charitable Trust, Chapman Foundation, Ministerio de Universidades (España), European Commission, Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), Generalitat de Catalunya, Armengot, Laia [0000-0002-3790-9838], Coll, Nuria S. [0000-0002-8889-0399], Cao, Min Min, Pierre Platre, Matthieu, Tsai, Huei-Hsuan, Zhang, Ling, Nobori, Tatsuya, Armengot, Laia, Chen, Yintong, He, Wenrong, Brent, Lukas, Coll, Nuria S., Ecker, Joseph R., Geldner, Niko, Busch, Wolfgang, National Institute of General Medical Sciences (US), National Institutes of Health (US), Salk Institute for Biological Studies, Hess Corporation, Ministry of Science and Technology (Taiwan), Human Frontier Science Program, Helmsley Charitable Trust, Chapman Foundation, Ministerio de Universidades (España), European Commission, Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), Generalitat de Catalunya, Armengot, Laia [0000-0002-3790-9838], Coll, Nuria S. [0000-0002-8889-0399], Cao, Min Min, Pierre Platre, Matthieu, Tsai, Huei-Hsuan, Zhang, Ling, Nobori, Tatsuya, Armengot, Laia, Chen, Yintong, He, Wenrong, Brent, Lukas, Coll, Nuria S., Ecker, Joseph R., Geldner, Niko, and Busch, Wolfgang

Abstract

Iron is critical during host–microorganism interactions1,2,3,4. Restriction of available iron by the host during infection is an important defence strategy, described as nutritional immunity5. However, this poses a conundrum for externally facing, absorptive tissues such as the gut epithelium or the plant root epidermis that generate environments that favour iron bioavailability. For example, plant roots acquire iron mostly from the soil and, when iron deficient, increase iron availability through mechanisms that include rhizosphere acidification and secretion of iron chelators6,7,8,9. Yet, the elevated iron bioavailability would also be beneficial for the growth of bacteria that threaten plant health. Here we report that microorganism-associated molecular patterns such as flagellin lead to suppression of root iron acquisition through a localized degradation of the systemic iron-deficiency signalling peptide Iron Man 1 (IMA1) in Arabidopsis thaliana. This response is also elicited when bacteria enter root tissues, but not when they dwell on the outer root surface. IMA1 itself has a role in modulating immunity in root and shoot, affecting the levels of root colonization and the resistance to a bacterial foliar pathogen. Our findings reveal an adaptive molecular mechanism of nutritional immunity that affects iron bioavailability and uptake, as well as immune responses.

Published

2024

3. A suberized exodermis is required for tomato drought tolerance

Author

Sub Experim.and Comput.Plant Development, Sub Plant-Environment Signaling, Plant-Environment Signaling, Experim.and Comput.Plant Development, Cantó-Pastor, Alex, Kajala, Kaisa, Shaar-Moshe, Lidor, Manzano, Concepción, Timilsena, Prakash, De Bellis, Damien, Gray, Sharon, Holbein, Julia, Yang, He, Mohammad, Sana, Nirmal, Niba, Suresh, Kiran, Ursache, Robertas, Mason, G. Alex, Gouran, Mona, West, Donnelly A., Borowsky, Alexander T., Shackel, Kenneth A., Sinha, Neelima, Bailey-Serres, Julia, Geldner, Niko, Li, Song, Franke, Rochus Benni, Brady, Siobhan M., Sub Experim.and Comput.Plant Development, Sub Plant-Environment Signaling, Plant-Environment Signaling, Experim.and Comput.Plant Development, Cantó-Pastor, Alex, Kajala, Kaisa, Shaar-Moshe, Lidor, Manzano, Concepción, Timilsena, Prakash, De Bellis, Damien, Gray, Sharon, Holbein, Julia, Yang, He, Mohammad, Sana, Nirmal, Niba, Suresh, Kiran, Ursache, Robertas, Mason, G. Alex, Gouran, Mona, West, Donnelly A., Borowsky, Alexander T., Shackel, Kenneth A., Sinha, Neelima, Bailey-Serres, Julia, Geldner, Niko, Li, Song, Franke, Rochus Benni, and Brady, Siobhan M.

Published

2024

4. The suberinteresting role of GELP proteins

Author

EMBO, Université de Lausanne, CSIC-IRTA-UAB-UB - Centre de Recerca Agrigenómica (CRAG), Ursache, Robertas, Dénervaud-Tendon, Valérie, Vieira-Texeira, Cristovão de Jesus, Geldner, Niko, Vermeer, Joop, EMBO, Université de Lausanne, CSIC-IRTA-UAB-UB - Centre de Recerca Agrigenómica (CRAG), Ursache, Robertas, Dénervaud-Tendon, Valérie, Vieira-Texeira, Cristovão de Jesus, Geldner, Niko, and Vermeer, Joop

Abstract

Plants roots take up essential nutrients and block out unwanted compounds from the soil by using a selective barrier in the roots known as the endodermis. Endodermis contains ring-shaped and lignin-based Casparian strip network that acts as a difusion barrier (Barbosa et al., 2019). Later in development, endodermal cells suberize to produce ‘patchy’ suberization that eventually leads to a zone of continuous suberin deposition (Serra and Geldner 2022). The two impermeable polymers, lignin and suberin, afect paracellular and transcellular transport, respectively. Suberin is a lipophilic polyester composed of fatty acids, glycerol and some aromatics. It’s deposited as a hydrophobic layer between the primary cell wall and plasma membrane. Despite suberin being a major plant polymer, fundamental aspects of its biosynthesis and plasticity have remained unclear. Plants shape their root system via lateral root formation, an auxin-induced process requiring local degradation and re-sealing of endodermal suberin. We demonstrated that diferentiated endodermis has a specifc, auxin-mediated transcriptional response, dominated by cell wall remodelling genes. We identifed two sets of auxin-regulated GELP proteins (GDSL-lipases). Using an optimized CRISPR-Cas9 gene editing toolset (Ursache et al., 2021), we discovered that one set of GELPs is required for suberin polymerization, while the other can drive suberin degradation (Ursache et al., 2021). These enzymes constitute novel core players of suberisation, driving root suberin plasticity during plant growth and in response to the environmental stress.

Published

2022

5. Coordination of microbe-host homeostasis by crosstalk with plant innate immunity

Author

Ma, Ka-Wai, Niu, Yulong, Jia, Yong, Ordon, Jana, Copeland, Charles, Emonet, Aurelia, Geldner, Niko, Guan, Rui, Stolze, Sara Christina, Nakagami, Hirofumi, Garrido-Oter, Ruben, Schulze-Lefert, Paul, Ma, Ka-Wai, Niu, Yulong, Jia, Yong, Ordon, Jana, Copeland, Charles, Emonet, Aurelia, Geldner, Niko, Guan, Rui, Stolze, Sara Christina, Nakagami, Hirofumi, Garrido-Oter, Ruben, and Schulze-Lefert, Paul

Abstract

Plants grown in natural soil are colonized by phylogenetically structured communities of microbes known as the microbiota. Individual microbes can activate microbe-associated molecular pattern (MAMP)-triggered immunity (MTI), which limits pathogen proliferation but curtails plant growth, a phenomenon known as the growth-defence trade-off. Here, we report that, in monoassociations, 41% (62 out of 151) of taxonomically diverse root bacterial commensals suppress Arabidopsis thaliana root growth inhibition (RGI) triggered by immune-stimulating MAMPs or damage-associated molecular patterns. Amplicon sequencing of bacterial 16S rRNA genes reveals that immune activation alters the profile of synthetic communities (SynComs) comprising RGI-non-suppressive strains, whereas the presence of RGI-suppressive strains attenuates this effect. Root colonization by SynComs with different complexities and RGI-suppressive activities alters the expression of 174 core host genes, with functions related to root development and nutrient transport. Furthermore, RGI-suppressive SynComs specifically downregulate a subset of immune-related genes. Precolonization of plants with RGI-suppressive SynComs, or mutation of one commensal-downregulated transcription factor, MYB15, renders the plants more susceptible to opportunistic Pseudomonas pathogens. Our results suggest that RGI-non-suppressive and RGI-suppressive root commensals modulate host susceptibility to pathogens by either eliciting or dampening MTI responses, respectively. This interplay buffers the plant immune system against pathogen perturbation and defence-associated growth inhibition, ultimately leading to commensal-host homeostasis. Plants evolved powerful mechanisms to fight against pathogenic microorganisms. So how can they accept and even favour the presence of growth-promoting fungi or bacteria? Here, the authors show that helpful commensal bacteria can suppress part of the plant innate immune system.

Published

2021

6. Coordination of microbe-host homeostasis by crosstalk with plant innate immunity

Author

Ma, Ka-Wai, Niu, Yulong, Jia, Yong, Ordon, Jana, Copeland, Charles, Emonet, Aurelia, Geldner, Niko, Guan, Rui, Stolze, Sara Christina, Nakagami, Hirofumi, Garrido-Oter, Ruben, Schulze-Lefert, Paul, Ma, Ka-Wai, Niu, Yulong, Jia, Yong, Ordon, Jana, Copeland, Charles, Emonet, Aurelia, Geldner, Niko, Guan, Rui, Stolze, Sara Christina, Nakagami, Hirofumi, Garrido-Oter, Ruben, and Schulze-Lefert, Paul

Abstract

Plants grown in natural soil are colonized by phylogenetically structured communities of microbes known as the microbiota. Individual microbes can activate microbe-associated molecular pattern (MAMP)-triggered immunity (MTI), which limits pathogen proliferation but curtails plant growth, a phenomenon known as the growth-defence trade-off. Here, we report that, in monoassociations, 41% (62 out of 151) of taxonomically diverse root bacterial commensals suppress Arabidopsis thaliana root growth inhibition (RGI) triggered by immune-stimulating MAMPs or damage-associated molecular patterns. Amplicon sequencing of bacterial 16S rRNA genes reveals that immune activation alters the profile of synthetic communities (SynComs) comprising RGI-non-suppressive strains, whereas the presence of RGI-suppressive strains attenuates this effect. Root colonization by SynComs with different complexities and RGI-suppressive activities alters the expression of 174 core host genes, with functions related to root development and nutrient transport. Furthermore, RGI-suppressive SynComs specifically downregulate a subset of immune-related genes. Precolonization of plants with RGI-suppressive SynComs, or mutation of one commensal-downregulated transcription factor, MYB15, renders the plants more susceptible to opportunistic Pseudomonas pathogens. Our results suggest that RGI-non-suppressive and RGI-suppressive root commensals modulate host susceptibility to pathogens by either eliciting or dampening MTI responses, respectively. This interplay buffers the plant immune system against pathogen perturbation and defence-associated growth inhibition, ultimately leading to commensal-host homeostasis. Plants evolved powerful mechanisms to fight against pathogenic microorganisms. So how can they accept and even favour the presence of growth-promoting fungi or bacteria? Here, the authors show that helpful commensal bacteria can suppress part of the plant innate immune system.

Published

2021

7. Surveillance of cell wall diffusion barrier integrity modulates water and solute transport in plants.

Author

Wang, Peng, Wang, Peng, Calvo-Polanco, Monica, Reyt, Guilhem, Barberon, Marie, Champeyroux, Chloe, Santoni, Véronique, Maurel, Christophe, Franke, Rochus B, Ljung, Karin, Novak, Ondrej, Geldner, Niko, Boursiac, Yann, Salt, David E, Wang, Peng, Wang, Peng, Calvo-Polanco, Monica, Reyt, Guilhem, Barberon, Marie, Champeyroux, Chloe, Santoni, Véronique, Maurel, Christophe, Franke, Rochus B, Ljung, Karin, Novak, Ondrej, Geldner, Niko, Boursiac, Yann, and Salt, David E

Abstract

The endodermis is a key cell layer in plant roots that contributes to the controlled uptake of water and mineral nutrients into plants. In order to provide such functionality the endodermal cell wall has specific chemical modifications consisting of lignin bands (Casparian strips) that encircle each cell, and deposition of a waxy-like substance (suberin) between the wall and the plasma membrane. These two extracellular deposits provide control of diffusion enabling the endodermis to direct the movement of water and solutes into and out of the vascular system in roots. Loss of integrity of the Casparian strip-based apoplastic barrier is sensed by the leakage of a small peptide from the stele into the cortex. Here, we report that such sensing of barrier integrity leads to the rebalancing of water and mineral nutrient uptake, compensating for breakage of Casparian strips. This rebalancing involves both a reduction in root hydraulic conductivity driven by deactivation of aquaporins, and downstream limitation of ion leakage through deposition of suberin. These responses in the root are also coupled to a reduction in water demand in the shoot mediated by ABA-dependent stomatal closure.

Published

2019

8. Surveillance of cell wall diffusion barrier integrity modulates water and solute transport in plants.

Author

Wang, Peng, Wang, Peng, Calvo-Polanco, Monica, Reyt, Guilhem, Barberon, Marie, Champeyroux, Chloe, Santoni, Véronique, Maurel, Christophe, Franke, Rochus B, Ljung, Karin, Novak, Ondrej, Geldner, Niko, Boursiac, Yann, Salt, David E, Wang, Peng, Wang, Peng, Calvo-Polanco, Monica, Reyt, Guilhem, Barberon, Marie, Champeyroux, Chloe, Santoni, Véronique, Maurel, Christophe, Franke, Rochus B, Ljung, Karin, Novak, Ondrej, Geldner, Niko, Boursiac, Yann, and Salt, David E

Abstract

The endodermis is a key cell layer in plant roots that contributes to the controlled uptake of water and mineral nutrients into plants. In order to provide such functionality the endodermal cell wall has specific chemical modifications consisting of lignin bands (Casparian strips) that encircle each cell, and deposition of a waxy-like substance (suberin) between the wall and the plasma membrane. These two extracellular deposits provide control of diffusion enabling the endodermis to direct the movement of water and solutes into and out of the vascular system in roots. Loss of integrity of the Casparian strip-based apoplastic barrier is sensed by the leakage of a small peptide from the stele into the cortex. Here, we report that such sensing of barrier integrity leads to the rebalancing of water and mineral nutrient uptake, compensating for breakage of Casparian strips. This rebalancing involves both a reduction in root hydraulic conductivity driven by deactivation of aquaporins, and downstream limitation of ion leakage through deposition of suberin. These responses in the root are also coupled to a reduction in water demand in the shoot mediated by ABA-dependent stomatal closure.

Published

2019

9. Single-cell damage elicits regional, nematode-restricting ethylene responses in roots.

Author

Marhavý, Peter, Marhavý, Peter, Kurenda, Andrzej, Siddique, Shahid, Dénervaud Tendon, Valerie, Zhou, Feng, Holbein, Julia, Hasan, M Shamim, Grundler, Florian Mw, Farmer, Edward E, Geldner, Niko, Marhavý, Peter, Marhavý, Peter, Kurenda, Andrzej, Siddique, Shahid, Dénervaud Tendon, Valerie, Zhou, Feng, Holbein, Julia, Hasan, M Shamim, Grundler, Florian Mw, Farmer, Edward E, and Geldner, Niko

Abstract

Plants are exposed to cellular damage by mechanical stresses, herbivore feeding, or invading microbes. Primary wound responses are communicated to neighboring and distal tissues by mobile signals. In leaves, crushing of large cell populations activates a long-distance signal, causing jasmonate production in distal organs. This is mediated by a cation channel-mediated depolarization wave and is associated with cytosolic Ca2+ transient currents. Here, we report that much more restricted, single-cell wounding in roots by laser ablation elicits non-systemic, regional surface potential changes, calcium waves, and reactive oxygen species (ROS) production. Surprisingly, laser ablation does not induce a robust jasmonate response, but regionally activates ethylene production and ethylene-response markers. This ethylene activation depends on calcium channel activities distinct from those in leaves, as well as a specific set of NADPH oxidases. Intriguingly, nematode attack elicits very similar responses, including membrane depolarization and regional upregulation of ethylene markers. Moreover, ethylene signaling antagonizes nematode feeding, delaying initial syncytial-phase establishment. Regional signals caused by single-cell wounding thus appear to constitute a relevant root immune response against small invaders.

Published

2019

10. The endodermis—development and differentiation of the plant's inner skin

Author

Alassimone, Julien, Roppolo, Daniele, Geldner, Niko, Vermeer, Joop, Alassimone, Julien, Roppolo, Daniele, Geldner, Niko, and Vermeer, Joop

Abstract

Controlling external compound entrance is essential for plant survival. To set up an efficient and selective sorting of nutrients, free diffusion via the apoplast in vascular plants is blocked at the level of the endodermis. Although we have learned a lot about endodermal specification in the last years, information regarding its differentiation is still very limited. A differentiated endodermal cell can be defined by the presence of the "Casparian strip” (CS), a cell wall modification described first by Robert Caspary in 1865. While the anatomical description of CS in many vascular plants has been very detailed, we still lack molecular information about the establishment of the Casparian strips and their actual function in roots. The recent isolation of a novel protein family, the CASPs, that localizes precisely to a domain of the plasma membrane underneath the CS represents an excellent point of entry to explore CS function and formation. In addition, it has been shown that the endodermis contains transporters that are localized to either the central (stele-facing) or peripheral (soil-facing) plasma membranes. These features suggest that the endodermis functions as a polar plant epithelium

Published

2018

11. In roots of Arabidopsis thaliana, the damage-associated molecular pattern AtPep1 is a stronger elicitor of immune signalling than flg22 or the chitin heptamer

Author

Poncini, Lorenzo, Wyrsch, Ines, Tendon, Valérie Dénervaud, Vorley, Thomas, Boller, Thomas, Geldner, Niko, Métraux, Jean-Pierre, Lehmann, Silke, Poncini, Lorenzo, Wyrsch, Ines, Tendon, Valérie Dénervaud, Vorley, Thomas, Boller, Thomas, Geldner, Niko, Métraux, Jean-Pierre, and Lehmann, Silke

Abstract

Plants interpret their immediate environment through perception of small molecules. Microbe-associated molecular patterns (MAMPs) such as flagellin and chitin are likely to be more abundant in the rhizosphere than plant-derived damage-associated molecular patterns (DAMPs). We investigated how the Arabidopsis thaliana root interprets MAMPs and DAMPs as danger signals. We monitored root development during exposure to increasing concentrations of the MAMPs flg22 and the chitin heptamer as well as of the DAMP AtPep1. The tissue-specific expression of defence- related genes in roots was analysed using a toolkit of promoter::YFPN lines reporting jasmonic acid (JA)-, salicylic acid (SA)-, ethylene (ET)- and reactive oxygen species (ROS)- dependent signalling. Finally, marker responses were analysed during invasion by the root pathogen Fusarium oxysporum. The DAMP AtPep1 triggered a stronger activation of the defence markers compared to flg22 and the chitin heptamer. In contrast to the tested MAMPs, AtPep1 induced SA- and JA-signalling markers in the root and caused a severe inhibition of root growth. Fungal attack resulted in a strong activation of defence genes in tissues close to the invading fungal hyphae. The results collectively suggest that AtPep1 presents a stronger danger signal to the Arabidopsis root than the MAMPs flg22 and chitin heptamer.

Published

2017

12. An N-acetylglucosamine transporter required for arbuscular mycorrhizal symbioses in rice and maize

Author

Nadal, Marina, Sawers, Ruairidh, Naseem, Shamoon, Bassin, Barbara, Kulicke, Corinna, Sharman, Abigail, An, Gynheung, An, Kyungsook, Ahern, Kevin R, Romag, Amanda, Brutnell, Thomas P; https://orcid.org/0000-0002-3581-8211, Gutjahr, Caroline; https://orcid.org/0000-0001-6163-745X, Geldner, Niko, Roux, Christophe, Martinoia, Enrico, Konopka, James B; https://orcid.org/0000-0001-5989-4086, Paszkowski, Uta; https://orcid.org/0000-0002-7279-7632, Nadal, Marina, Sawers, Ruairidh, Naseem, Shamoon, Bassin, Barbara, Kulicke, Corinna, Sharman, Abigail, An, Gynheung, An, Kyungsook, Ahern, Kevin R, Romag, Amanda, Brutnell, Thomas P; https://orcid.org/0000-0002-3581-8211, Gutjahr, Caroline; https://orcid.org/0000-0001-6163-745X, Geldner, Niko, Roux, Christophe, Martinoia, Enrico, Konopka, James B; https://orcid.org/0000-0001-5989-4086, and Paszkowski, Uta; https://orcid.org/0000-0002-7279-7632

Abstract

Most terrestrial plants, including crops, engage in beneficial interactions with arbuscular mycorrhizal fungi. Vital to the association is mutual recognition involving the release of diffusible signals into the rhizosphere. Previously, we identified the maize no perception 1 (nope1) mutant to be defective in early signalling. Here, we report cloning of ZmNope1 on the basis of synteny with rice. NOPE1 encodes a functional homologue of the Candida albicans N-acetylglucosamine (GlcNAc) transporter NGT1, and represents the first plasma membrane GlcNAc transporter identified from plants. In C. albicans, exposure to GlcNAc activates cell signalling and virulence. Similarly, in Rhizophagus irregularis treatment with rice wild-type but not nope1 root exudates induced transcriptome changes associated with signalling function, suggesting a requirement of NOPE1 function for presymbiotic fungal reprogramming.

Published

2017

13. Lateral root initiation in Arabidopsis thaliana: a force awakens

Author

Vermeer, Joop E M; https://orcid.org/0000-0001-8876-5873, Geldner, Niko, Vermeer, Joop E M; https://orcid.org/0000-0001-8876-5873, and Geldner, Niko

Abstract

Osmotically driven turgor pressure of plant cells can be higher than that of a car tire. It puts tremendous forces onto cell walls and drives cell growth and changes in cell shape. This has given rise to unique mechanisms to control organ formation compared to metazoans. The fascinating interplay between forces and local cellular reorganization is still poorly understood. Growth of lateral roots is a prominent example of a developmental process in which mechanical forces between neighboring cells are generated and must be dealt with. Lateral roots initiate from a single cell layer that resides deep within the primary root. On their way out, lateral roots grow through the overlying endodermal, cortical, and epidermal cell layers. It was recently demonstrated that endodermal cells actively accommodate lateral root formation. Interfering genetically with these accommodating responses in the endodermis completely blocks cell proliferation in the pericycle. The lateral root system provides a unique opportunity to elucidate the molecular and cellular mechanisms whereby mechanical forces and intercellular communication regulate spatial accommodation during plant development.

Published

2015

14. Functional and evolutionary analysis of the CASPARIAN STRIP MEMBRANE DOMAIN PROTEIN family

Author

Roppolo, Daniele, Boeckmann, Brigitte, Pfister, Alexandre, Boutet, Emmanuel, Rubio Luna, María Carmen, Dénervaud-Tendon, Valérie, Vermeer, Joop E.M., Gheyselinck, Jacqueline, Xenarios, Ioannis, Geldner, Niko, Roppolo, Daniele, Boeckmann, Brigitte, Pfister, Alexandre, Boutet, Emmanuel, Rubio Luna, María Carmen, Dénervaud-Tendon, Valérie, Vermeer, Joop E.M., Gheyselinck, Jacqueline, Xenarios, Ioannis, and Geldner, Niko

Abstract

CASPARIAN STRIP MEMBRANE DOMAIN PROTEINS (CASPs) are four-membrane-span proteins that mediate the deposition of Casparian strips in the endodermis by recruiting the lignin polymerization machinery. CASPs show high stability in their membrane domain, which presents all the hallmarks of a membrane scaffold. Here, we characterized the large family of CASPlike (CASPL) proteins. CASPLs were found in all major divisions of land plants as well as in green algae; homologs outside of the plant kingdom were identified as members of the MARVEL protein family. When ectopically expressed in the endodermis, most CASPLs were able to integrate the CASP membrane domain, which suggests that CASPLs share with CASPs the propensity to form transmembrane scaffolds. Extracellular loops are not necessary for generating the scaffold, since CASP1 was still able to localize correctly when either one of the extracellular loops was deleted. The CASP first extracellular loop was found conserved in euphyllophytes but absent in plants lacking Casparian strips, an observation that may contribute to the study of Casparian strip and root evolution. In Arabidopsis (Arabidopsis thaliana), CASPL showed specific expression in a variety of cell types, such as trichomes, abscission zone cells, peripheral root cap cells, and xylem pole pericycle cells.

Published

2014

15. AtABCG29 is a monolignol transporter involved in lignin biosynthesis

Author

Alejandro, Santiago, Lee, Yuree, Tohge, Takayuki, Sudre, Damien, Osorio, Sonia, Park, Jiyoung, Bovet, Lucien, Lee, Youngsook, Geldner, Niko, Fernie, Alisdair R, Martinoia, Enrico, Alejandro, Santiago, Lee, Yuree, Tohge, Takayuki, Sudre, Damien, Osorio, Sonia, Park, Jiyoung, Bovet, Lucien, Lee, Youngsook, Geldner, Niko, Fernie, Alisdair R, and Martinoia, Enrico

Abstract

Lignin is the defining constituent of wood and the second most abundant natural polymer on earth. Lignin is produced by the oxidative coupling of three monolignols: p-coumaryl alcohol, coniferyl alcohol, and sinapyl alcohol. Monolignols are synthesized via the phenylpropanoid pathway and eventually polymerized in the cell wall by peroxidases and laccases. However, the mechanism whereby monolignols are transported from the cytosol to the cell wall has remained elusive. Here we report the discovery that AtABCG29, an ATP-binding cassette transporter, acts as a p-coumaryl alcohol transporter. Expression of AtABCG29 promoter-driven reporter genes and a Citrine-AtABCG29 fusion construct revealed that AtABCG29 is targeted to the plasma membrane of the root endodermis and vascular tissue. Moreover, yeasts expressing AtABCG29 exhibited an increased tolerance to p-coumaryl alcohol by excreting this monolignol. Vesicles isolated from yeasts expressing AtABCG29 exhibited a p-coumaryl alcohol transport activity. Loss-of-function Arabidopsis mutants contained less lignin subunits and were more sensitive to p-coumaryl alcohol. Changes in secondary metabolite profiles in abcg29 underline the importance of regulating p-coumaryl alcohol levels in the cytosol. This is the first identification of a monolignol transporter, closing a crucial gap in our understanding of lignin biosynthesis, which could open new directions for lignin engineering.

Published

2012

16. Apical-basal polarity : why plant cells don't stand on their heads (Letters)

Author

Friml, Jirí, Benfey, Philip, Benková, Eva, Bennett, Malcolm, Berleth, Thomas, Geldner, Niko, Grebe, Markus, Heisler, Marcus, Hejátko, Jan, Jürgens, Gerd, Laux, Thomas, Lindsey, Keith, Lukowitz, Wolfgang, Luschnig, Christian, Offringa, Remko, Scheres, Ben, Swarup, Ranjan, Torres-Ruiz, Ramón, Weijers, Dolf, Zazímalová, Eva, Friml, Jirí, Benfey, Philip, Benková, Eva, Bennett, Malcolm, Berleth, Thomas, Geldner, Niko, Grebe, Markus, Heisler, Marcus, Hejátko, Jan, Jürgens, Gerd, Laux, Thomas, Lindsey, Keith, Lukowitz, Wolfgang, Luschnig, Christian, Offringa, Remko, Scheres, Ben, Swarup, Ranjan, Torres-Ruiz, Ramón, Weijers, Dolf, and Zazímalová, Eva

Published

2006

17. Partial loss-of-function alleles reveal a role for GNOM in auxin transport-related, post-embryonic development of Arabidopsis

Author

Geldner, Niko, Richter, Sandra, Vieten, Anne, Marquardt, Sebastian, Torres-Ruiz, Ramon A, Mayer, Ulrike, Jürgens, Gerd, Geldner, Niko, Richter, Sandra, Vieten, Anne, Marquardt, Sebastian, Torres-Ruiz, Ramon A, Mayer, Ulrike, and Jürgens, Gerd

Abstract

The Arabidopsis GNOM gene encodes an ARF GDP/GTP exchange factor involved in embryonic axis formation and polar localisation of the auxin efflux regulator PIN1. To examine whether GNOM also plays a role in post-embryonic development and to clarify its involvement in auxin transport, we have characterised newly isolated weak gnom alleles as well as trans-heterozygotes of complementing strong alleles. These genotypes form a phenotypic series of GNOM activity in post-embryonic development, with auxin-related defects, especially in the maintenance of primary root meristem activity and in the initiation and organisation of lateral root primordia. Our results suggest a model for GNOM action mediating auxin transport in both embryogenesis and post-embryonic organ development.

Published

2004

18. Partial loss-of-function alleles reveal a role for GNOM in auxin transport-related, post-embryonic development of Arabidopsis

Author

Geldner, Niko, Richter, Sandra, Vieten, Anne, Marquardt, Sebastian, Torres-Ruiz, Ramon A, Mayer, Ulrike, Jürgens, Gerd, Geldner, Niko, Richter, Sandra, Vieten, Anne, Marquardt, Sebastian, Torres-Ruiz, Ramon A, Mayer, Ulrike, and Jürgens, Gerd

Abstract

The Arabidopsis GNOM gene encodes an ARF GDP/GTP exchange factor involved in embryonic axis formation and polar localisation of the auxin efflux regulator PIN1. To examine whether GNOM also plays a role in post-embryonic development and to clarify its involvement in auxin transport, we have characterised newly isolated weak gnom alleles as well as trans-heterozygotes of complementing strong alleles. These genotypes form a phenotypic series of GNOM activity in post-embryonic development, with auxin-related defects, especially in the maintenance of primary root meristem activity and in the initiation and organisation of lateral root primordia. Our results suggest a model for GNOM action mediating auxin transport in both embryogenesis and post-embryonic organ development.

Published

2004

19. Role of LOTR1 in nutrient transport through organization of spatial distribution of root endodermal barriers

Author

Li, Baohai, Kamiya, Takehiro, Kalmbach, Lothar, Yamagami, Mutsumi, Yamaguchi, Katsushi, Shigenobu, Shuji, Sawa, Shinichiro, Danku, John M.C., Salt, David E., Geldner, Niko, Fujiwara, Toru, Li, Baohai, Kamiya, Takehiro, Kalmbach, Lothar, Yamagami, Mutsumi, Yamaguchi, Katsushi, Shigenobu, Shuji, Sawa, Shinichiro, Danku, John M.C., Salt, David E., Geldner, Niko, and Fujiwara, Toru

Abstract

The formation of Casparian strips and suberin lamellae at the endodermis limits the free diffusion of nutrients and harmful substances via the apoplastic space between the soil solution and the stele in roots [1–3]. Casparian strips are ring-like lignin polymers deposited in the middle of anticlinal cellwalls between endodermal cells and fill the gap between them [4–6]. Suberin lamellae are glycerolipid polymers covering the endodermal cells and likely function as a barrier to limit transmembrane movement of apoplastic solutes into the endodermal cells [7, 8].However, the current knowledge on the formation of these two distinct endodermal barriers and their regulatory role in nutrient transport is still limited. Here, we identify an uncharacterized gene,LOTR1, essential for Casparian strip formation in Arabidopsis thaliana. The lotr1 mutants display altered localization of CASP1, an essential protein for Casparian strip formation [9], disrupted Casparian strips, ectopic suberization of endodermal cells, and low accumulation of shoot calcium (Ca). Degradation by expression of a suberin-degrading enzyme in the mutants revealed that the ectopic suberization at the endodermal cells limits Ca transport through the transmembrane pathway, thereby causing reduced Ca delivery to the shoot. Moreover, analysis of the mutants showed that suberin lamellae function as an apoplastic diffusion barrier to the stele at sites of lateral root emergence where Casparian strips are disrupted. Our findings suggest that the transmembrane pathway through unsuberized endodermal cells, rather than the sites of lateral root emergence,mediates the transport of apoplastic substances such as Ca into the xylem.

20. The MYB36 transcription factor orchestrates Casparian strip formation

Author

Kamiya, Takehiro, Borghi, Monica, Wang, Peng, Danku, John, Kalmbach, Lothar, Hosmani, Prashant S., Naseer, Sadaf, Fujiwara, Toru, Geldner, Niko, Salt, David E., Kamiya, Takehiro, Borghi, Monica, Wang, Peng, Danku, John, Kalmbach, Lothar, Hosmani, Prashant S., Naseer, Sadaf, Fujiwara, Toru, Geldner, Niko, and Salt, David E.

Abstract

The endodermis in roots acts as a selectivity filter for nutrient and water transport essential for growth and development. This selectivity is enabled by the formation of lignin-based Casparian strips. Casparian strip formation is initiated by the localization of the Casparian strip domain proteins (CASPs) in the plasma membrane, at the site where the Casparian strip will form. Localized CASPs recruit Peroxidase 64 (PER64), a Respiratory Burst Oxidase Homolog F, and Enhanced Suberin 1 (ESB1), a dirigent-like protein, to assemble the lignin polymerization machinery. However, the factors that control both expression of the genes encoding this biosynthetic machinery and its localization to the Casparian strip formation site remain unknown. Here, we identify the transcription factor, MYB36, essential for Casparian strip formation. MYB36 directly and positively regulates the expression of the Casparian strip genes CASP1, PER64, and ESB1. Casparian strips are absent in plants lacking a functional MYB36 and are replaced by ectopic lignin-like material in the corners of endodermal cells. The barrier function of Casparian strips in these plants is also disrupted. Significantly, ectopic expression of MYB36 in the cortex is sufficient to reprogram these cells to start expressing CASP1–GFP, correctly localize the CASP1–GFP protein to form a Casparian strip domain, and deposit a Casparian strip-like structure in the cell wall at this location. These results demonstrate that MYB36 is controlling expression of the machinery required to locally polymerize lignin in a fine band in the cell wall for the formation of the Casparian strip.

21. Role of LOTR1 in nutrient transport through organization of spatial distribution of root endodermal barriers

Author

Li, Baohai, Kamiya, Takehiro, Kalmbach, Lothar, Yamagami, Mutsumi, Yamaguchi, Katsushi, Shigenobu, Shuji, Sawa, Shinichiro, Danku, John M.C., Salt, David E., Geldner, Niko, Fujiwara, Toru, Li, Baohai, Kamiya, Takehiro, Kalmbach, Lothar, Yamagami, Mutsumi, Yamaguchi, Katsushi, Shigenobu, Shuji, Sawa, Shinichiro, Danku, John M.C., Salt, David E., Geldner, Niko, and Fujiwara, Toru

Abstract

The formation of Casparian strips and suberin lamellae at the endodermis limits the free diffusion of nutrients and harmful substances via the apoplastic space between the soil solution and the stele in roots [1–3]. Casparian strips are ring-like lignin polymers deposited in the middle of anticlinal cellwalls between endodermal cells and fill the gap between them [4–6]. Suberin lamellae are glycerolipid polymers covering the endodermal cells and likely function as a barrier to limit transmembrane movement of apoplastic solutes into the endodermal cells [7, 8].However, the current knowledge on the formation of these two distinct endodermal barriers and their regulatory role in nutrient transport is still limited. Here, we identify an uncharacterized gene,LOTR1, essential for Casparian strip formation in Arabidopsis thaliana. The lotr1 mutants display altered localization of CASP1, an essential protein for Casparian strip formation [9], disrupted Casparian strips, ectopic suberization of endodermal cells, and low accumulation of shoot calcium (Ca). Degradation by expression of a suberin-degrading enzyme in the mutants revealed that the ectopic suberization at the endodermal cells limits Ca transport through the transmembrane pathway, thereby causing reduced Ca delivery to the shoot. Moreover, analysis of the mutants showed that suberin lamellae function as an apoplastic diffusion barrier to the stele at sites of lateral root emergence where Casparian strips are disrupted. Our findings suggest that the transmembrane pathway through unsuberized endodermal cells, rather than the sites of lateral root emergence,mediates the transport of apoplastic substances such as Ca into the xylem.

22. The MYB36 transcription factor orchestrates Casparian strip formation

Author

Kamiya, Takehiro, Borghi, Monica, Wang, Peng, Danku, John, Kalmbach, Lothar, Hosmani, Prashant S., Naseer, Sadaf, Fujiwara, Toru, Geldner, Niko, Salt, David E., Kamiya, Takehiro, Borghi, Monica, Wang, Peng, Danku, John, Kalmbach, Lothar, Hosmani, Prashant S., Naseer, Sadaf, Fujiwara, Toru, Geldner, Niko, and Salt, David E.

Abstract

The endodermis in roots acts as a selectivity filter for nutrient and water transport essential for growth and development. This selectivity is enabled by the formation of lignin-based Casparian strips. Casparian strip formation is initiated by the localization of the Casparian strip domain proteins (CASPs) in the plasma membrane, at the site where the Casparian strip will form. Localized CASPs recruit Peroxidase 64 (PER64), a Respiratory Burst Oxidase Homolog F, and Enhanced Suberin 1 (ESB1), a dirigent-like protein, to assemble the lignin polymerization machinery. However, the factors that control both expression of the genes encoding this biosynthetic machinery and its localization to the Casparian strip formation site remain unknown. Here, we identify the transcription factor, MYB36, essential for Casparian strip formation. MYB36 directly and positively regulates the expression of the Casparian strip genes CASP1, PER64, and ESB1. Casparian strips are absent in plants lacking a functional MYB36 and are replaced by ectopic lignin-like material in the corners of endodermal cells. The barrier function of Casparian strips in these plants is also disrupted. Significantly, ectopic expression of MYB36 in the cortex is sufficient to reprogram these cells to start expressing CASP1–GFP, correctly localize the CASP1–GFP protein to form a Casparian strip domain, and deposit a Casparian strip-like structure in the cell wall at this location. These results demonstrate that MYB36 is controlling expression of the machinery required to locally polymerize lignin in a fine band in the cell wall for the formation of the Casparian strip.

23. Role of LOTR1 in nutrient transport through organization of spatial distribution of root endodermal barriers

Author

Li, Baohai, Kamiya, Takehiro, Kalmbach, Lothar, Yamagami, Mutsumi, Yamaguchi, Katsushi, Shigenobu, Shuji, Sawa, Shinichiro, Danku, John M.C., Salt, David E., Geldner, Niko, Fujiwara, Toru, Li, Baohai, Kamiya, Takehiro, Kalmbach, Lothar, Yamagami, Mutsumi, Yamaguchi, Katsushi, Shigenobu, Shuji, Sawa, Shinichiro, Danku, John M.C., Salt, David E., Geldner, Niko, and Fujiwara, Toru

Abstract

The formation of Casparian strips and suberin lamellae at the endodermis limits the free diffusion of nutrients and harmful substances via the apoplastic space between the soil solution and the stele in roots [1–3]. Casparian strips are ring-like lignin polymers deposited in the middle of anticlinal cellwalls between endodermal cells and fill the gap between them [4–6]. Suberin lamellae are glycerolipid polymers covering the endodermal cells and likely function as a barrier to limit transmembrane movement of apoplastic solutes into the endodermal cells [7, 8].However, the current knowledge on the formation of these two distinct endodermal barriers and their regulatory role in nutrient transport is still limited. Here, we identify an uncharacterized gene,LOTR1, essential for Casparian strip formation in Arabidopsis thaliana. The lotr1 mutants display altered localization of CASP1, an essential protein for Casparian strip formation [9], disrupted Casparian strips, ectopic suberization of endodermal cells, and low accumulation of shoot calcium (Ca). Degradation by expression of a suberin-degrading enzyme in the mutants revealed that the ectopic suberization at the endodermal cells limits Ca transport through the transmembrane pathway, thereby causing reduced Ca delivery to the shoot. Moreover, analysis of the mutants showed that suberin lamellae function as an apoplastic diffusion barrier to the stele at sites of lateral root emergence where Casparian strips are disrupted. Our findings suggest that the transmembrane pathway through unsuberized endodermal cells, rather than the sites of lateral root emergence,mediates the transport of apoplastic substances such as Ca into the xylem.

24. The MYB36 transcription factor orchestrates Casparian strip formation

Author

Kamiya, Takehiro, Borghi, Monica, Wang, Peng, Danku, John, Kalmbach, Lothar, Hosmani, Prashant S., Naseer, Sadaf, Fujiwara, Toru, Geldner, Niko, Salt, David E., Kamiya, Takehiro, Borghi, Monica, Wang, Peng, Danku, John, Kalmbach, Lothar, Hosmani, Prashant S., Naseer, Sadaf, Fujiwara, Toru, Geldner, Niko, and Salt, David E.

Abstract

The endodermis in roots acts as a selectivity filter for nutrient and water transport essential for growth and development. This selectivity is enabled by the formation of lignin-based Casparian strips. Casparian strip formation is initiated by the localization of the Casparian strip domain proteins (CASPs) in the plasma membrane, at the site where the Casparian strip will form. Localized CASPs recruit Peroxidase 64 (PER64), a Respiratory Burst Oxidase Homolog F, and Enhanced Suberin 1 (ESB1), a dirigent-like protein, to assemble the lignin polymerization machinery. However, the factors that control both expression of the genes encoding this biosynthetic machinery and its localization to the Casparian strip formation site remain unknown. Here, we identify the transcription factor, MYB36, essential for Casparian strip formation. MYB36 directly and positively regulates the expression of the Casparian strip genes CASP1, PER64, and ESB1. Casparian strips are absent in plants lacking a functional MYB36 and are replaced by ectopic lignin-like material in the corners of endodermal cells. The barrier function of Casparian strips in these plants is also disrupted. Significantly, ectopic expression of MYB36 in the cortex is sufficient to reprogram these cells to start expressing CASP1–GFP, correctly localize the CASP1–GFP protein to form a Casparian strip domain, and deposit a Casparian strip-like structure in the cell wall at this location. These results demonstrate that MYB36 is controlling expression of the machinery required to locally polymerize lignin in a fine band in the cell wall for the formation of the Casparian strip.

25. Role of LOTR1 in nutrient transport through organization of spatial distribution of root endodermal barriers

Author

Li, Baohai, Kamiya, Takehiro, Kalmbach, Lothar, Yamagami, Mutsumi, Yamaguchi, Katsushi, Shigenobu, Shuji, Sawa, Shinichiro, Danku, John M.C., Salt, David E., Geldner, Niko, Fujiwara, Toru, Li, Baohai, Kamiya, Takehiro, Kalmbach, Lothar, Yamagami, Mutsumi, Yamaguchi, Katsushi, Shigenobu, Shuji, Sawa, Shinichiro, Danku, John M.C., Salt, David E., Geldner, Niko, and Fujiwara, Toru

Abstract

The formation of Casparian strips and suberin lamellae at the endodermis limits the free diffusion of nutrients and harmful substances via the apoplastic space between the soil solution and the stele in roots [1–3]. Casparian strips are ring-like lignin polymers deposited in the middle of anticlinal cellwalls between endodermal cells and fill the gap between them [4–6]. Suberin lamellae are glycerolipid polymers covering the endodermal cells and likely function as a barrier to limit transmembrane movement of apoplastic solutes into the endodermal cells [7, 8].However, the current knowledge on the formation of these two distinct endodermal barriers and their regulatory role in nutrient transport is still limited. Here, we identify an uncharacterized gene,LOTR1, essential for Casparian strip formation in Arabidopsis thaliana. The lotr1 mutants display altered localization of CASP1, an essential protein for Casparian strip formation [9], disrupted Casparian strips, ectopic suberization of endodermal cells, and low accumulation of shoot calcium (Ca). Degradation by expression of a suberin-degrading enzyme in the mutants revealed that the ectopic suberization at the endodermal cells limits Ca transport through the transmembrane pathway, thereby causing reduced Ca delivery to the shoot. Moreover, analysis of the mutants showed that suberin lamellae function as an apoplastic diffusion barrier to the stele at sites of lateral root emergence where Casparian strips are disrupted. Our findings suggest that the transmembrane pathway through unsuberized endodermal cells, rather than the sites of lateral root emergence,mediates the transport of apoplastic substances such as Ca into the xylem.

26. The MYB36 transcription factor orchestrates Casparian strip formation

Author

Kamiya, Takehiro, Borghi, Monica, Wang, Peng, Danku, John, Kalmbach, Lothar, Hosmani, Prashant S., Naseer, Sadaf, Fujiwara, Toru, Geldner, Niko, Salt, David E., Kamiya, Takehiro, Borghi, Monica, Wang, Peng, Danku, John, Kalmbach, Lothar, Hosmani, Prashant S., Naseer, Sadaf, Fujiwara, Toru, Geldner, Niko, and Salt, David E.

Abstract

The endodermis in roots acts as a selectivity filter for nutrient and water transport essential for growth and development. This selectivity is enabled by the formation of lignin-based Casparian strips. Casparian strip formation is initiated by the localization of the Casparian strip domain proteins (CASPs) in the plasma membrane, at the site where the Casparian strip will form. Localized CASPs recruit Peroxidase 64 (PER64), a Respiratory Burst Oxidase Homolog F, and Enhanced Suberin 1 (ESB1), a dirigent-like protein, to assemble the lignin polymerization machinery. However, the factors that control both expression of the genes encoding this biosynthetic machinery and its localization to the Casparian strip formation site remain unknown. Here, we identify the transcription factor, MYB36, essential for Casparian strip formation. MYB36 directly and positively regulates the expression of the Casparian strip genes CASP1, PER64, and ESB1. Casparian strips are absent in plants lacking a functional MYB36 and are replaced by ectopic lignin-like material in the corners of endodermal cells. The barrier function of Casparian strips in these plants is also disrupted. Significantly, ectopic expression of MYB36 in the cortex is sufficient to reprogram these cells to start expressing CASP1–GFP, correctly localize the CASP1–GFP protein to form a Casparian strip domain, and deposit a Casparian strip-like structure in the cell wall at this location. These results demonstrate that MYB36 is controlling expression of the machinery required to locally polymerize lignin in a fine band in the cell wall for the formation of the Casparian strip.

27. Role of LOTR1 in nutrient transport through organization of spatial distribution of root endodermal barriers

Author

Li, Baohai, Kamiya, Takehiro, Kalmbach, Lothar, Yamagami, Mutsumi, Yamaguchi, Katsushi, Shigenobu, Shuji, Sawa, Shinichiro, Danku, John M.C., Salt, David E., Geldner, Niko, Fujiwara, Toru, Li, Baohai, Kamiya, Takehiro, Kalmbach, Lothar, Yamagami, Mutsumi, Yamaguchi, Katsushi, Shigenobu, Shuji, Sawa, Shinichiro, Danku, John M.C., Salt, David E., Geldner, Niko, and Fujiwara, Toru

Abstract

The formation of Casparian strips and suberin lamellae at the endodermis limits the free diffusion of nutrients and harmful substances via the apoplastic space between the soil solution and the stele in roots [1–3]. Casparian strips are ring-like lignin polymers deposited in the middle of anticlinal cellwalls between endodermal cells and fill the gap between them [4–6]. Suberin lamellae are glycerolipid polymers covering the endodermal cells and likely function as a barrier to limit transmembrane movement of apoplastic solutes into the endodermal cells [7, 8].However, the current knowledge on the formation of these two distinct endodermal barriers and their regulatory role in nutrient transport is still limited. Here, we identify an uncharacterized gene,LOTR1, essential for Casparian strip formation in Arabidopsis thaliana. The lotr1 mutants display altered localization of CASP1, an essential protein for Casparian strip formation [9], disrupted Casparian strips, ectopic suberization of endodermal cells, and low accumulation of shoot calcium (Ca). Degradation by expression of a suberin-degrading enzyme in the mutants revealed that the ectopic suberization at the endodermal cells limits Ca transport through the transmembrane pathway, thereby causing reduced Ca delivery to the shoot. Moreover, analysis of the mutants showed that suberin lamellae function as an apoplastic diffusion barrier to the stele at sites of lateral root emergence where Casparian strips are disrupted. Our findings suggest that the transmembrane pathway through unsuberized endodermal cells, rather than the sites of lateral root emergence,mediates the transport of apoplastic substances such as Ca into the xylem.

28. The MYB36 transcription factor orchestrates Casparian strip formation

Author

Kamiya, Takehiro, Borghi, Monica, Wang, Peng, Danku, John, Kalmbach, Lothar, Hosmani, Prashant S., Naseer, Sadaf, Fujiwara, Toru, Geldner, Niko, Salt, David E., Kamiya, Takehiro, Borghi, Monica, Wang, Peng, Danku, John, Kalmbach, Lothar, Hosmani, Prashant S., Naseer, Sadaf, Fujiwara, Toru, Geldner, Niko, and Salt, David E.

Abstract

The endodermis in roots acts as a selectivity filter for nutrient and water transport essential for growth and development. This selectivity is enabled by the formation of lignin-based Casparian strips. Casparian strip formation is initiated by the localization of the Casparian strip domain proteins (CASPs) in the plasma membrane, at the site where the Casparian strip will form. Localized CASPs recruit Peroxidase 64 (PER64), a Respiratory Burst Oxidase Homolog F, and Enhanced Suberin 1 (ESB1), a dirigent-like protein, to assemble the lignin polymerization machinery. However, the factors that control both expression of the genes encoding this biosynthetic machinery and its localization to the Casparian strip formation site remain unknown. Here, we identify the transcription factor, MYB36, essential for Casparian strip formation. MYB36 directly and positively regulates the expression of the Casparian strip genes CASP1, PER64, and ESB1. Casparian strips are absent in plants lacking a functional MYB36 and are replaced by ectopic lignin-like material in the corners of endodermal cells. The barrier function of Casparian strips in these plants is also disrupted. Significantly, ectopic expression of MYB36 in the cortex is sufficient to reprogram these cells to start expressing CASP1–GFP, correctly localize the CASP1–GFP protein to form a Casparian strip domain, and deposit a Casparian strip-like structure in the cell wall at this location. These results demonstrate that MYB36 is controlling expression of the machinery required to locally polymerize lignin in a fine band in the cell wall for the formation of the Casparian strip.

29. The endodermis—development and differentiation of the plant's inner skin

Author

Alassimone, Julien, Roppolo, Daniele, Geldner, Niko, Vermeer, Joop, Alassimone, Julien, Roppolo, Daniele, Geldner, Niko, and Vermeer, Joop

Abstract

Controlling external compound entrance is essential for plant survival. To set up an efficient and selective sorting of nutrients, free diffusion via the apoplast in vascular plants is blocked at the level of the endodermis. Although we have learned a lot about endodermal specification in the last years, information regarding its differentiation is still very limited. A differentiated endodermal cell can be defined by the presence of the "Casparian strip” (CS), a cell wall modification described first by Robert Caspary in 1865. While the anatomical description of CS in many vascular plants has been very detailed, we still lack molecular information about the establishment of the Casparian strips and their actual function in roots. The recent isolation of a novel protein family, the CASPs, that localizes precisely to a domain of the plasma membrane underneath the CS represents an excellent point of entry to explore CS function and formation. In addition, it has been shown that the endodermis contains transporters that are localized to either the central (stele-facing) or peripheral (soil-facing) plasma membranes. These features suggest that the endodermis functions as a polar plant epithelium

30. In roots of Arabidopsis thaliana, the damage-associated molecular pattern AtPep1 is a stronger elicitor of immune signalling than flg22 or the chitin heptamer

Author

Poncini, Lorenzo, Wyrsch, Ines, Tendon, Valérie Dénervaud, Vorley, Thomas, Boller, Thomas, Geldner, Niko, Métraux, Jean-Pierre, Lehmann, Silke, Poncini, Lorenzo, Wyrsch, Ines, Tendon, Valérie Dénervaud, Vorley, Thomas, Boller, Thomas, Geldner, Niko, Métraux, Jean-Pierre, and Lehmann, Silke

Abstract

Plants interpret their immediate environment through perception of small molecules. Microbe-associated molecular patterns (MAMPs) such as flagellin and chitin are likely to be more abundant in the rhizosphere than plant-derived damage-associated molecular patterns (DAMPs). We investigated how the Arabidopsis thaliana root interprets MAMPs and DAMPs as danger signals. We monitored root development during exposure to increasing concentrations of the MAMPs flg22 and the chitin heptamer as well as of the DAMP AtPep1. The tissue-specific expression of defence- related genes in roots was analysed using a toolkit of promoter::YFPN lines reporting jasmonic acid (JA)-, salicylic acid (SA)-, ethylene (ET)- and reactive oxygen species (ROS)- dependent signalling. Finally, marker responses were analysed during invasion by the root pathogen Fusarium oxysporum. The DAMP AtPep1 triggered a stronger activation of the defence markers compared to flg22 and the chitin heptamer. In contrast to the tested MAMPs, AtPep1 induced SA- and JA-signalling markers in the root and caused a severe inhibition of root growth. Fungal attack resulted in a strong activation of defence genes in tissues close to the invading fungal hyphae. The results collectively suggest that AtPep1 presents a stronger danger signal to the Arabidopsis root than the MAMPs flg22 and chitin heptamer.