Sugar transporters for intercellular exchange and nutrition of pathogens

Chen, Lei; Hou, Bi Huei; Lalonde, Sylvie; Takanaga, Hitomi; Hartung, Mara L.; Qu, Xiao Qing; Guo, Woei Jiun; Kim, Jung Gun; Underwood, William; Chaudhuri, Bhavna; Chermak, Diane; Antony, Ginny; White, Frank F.; Somerville, Shauna; Mudgett, Mary Beth; Frommer, Wolf B.

doi:10.1038/nature09606

Cited by 1,301 publications

(1,729 citation statements)

References 57 publications

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“…Several nodulin genes are also activated in response to inoculation with AM fungi (Harrison 1998 The other nodulin gene that was up-regulated significantly in the basal part of mycorrhizal protocorms containing the fungal pelotons was SvNod9, which codes for a putative bidirectional sugar transporter of the SWEET family. These are uniporters (Chen et al 2010) that can transfer hexoses across the plasma membrane in both directions, depending on the sugar gradient. SWEETs can serve for sugar export from cells, and they can be exploited by bacterial and fungal pathogens to acquire carbohydrates for energy and carbon (Chen et al 2010).…”

Section: Discussionmentioning

confidence: 99%

“…These are uniporters (Chen et al 2010) that can transfer hexoses across the plasma membrane in both directions, depending on the sugar gradient. SWEETs can serve for sugar export from cells, and they can be exploited by bacterial and fungal pathogens to acquire carbohydrates for energy and carbon (Chen et al 2010). The nodule-specific MtN3 is a member of the M. truncatula SWEET family, and an involvement in bacteroid nutrition inside the nodule has been suggested (Bapaume and Reinhardt 2012), even though previous studies indicated that dicarboxylic acids are likely the carbon source supplied to intracellular bacteroids (see in White et al 2007).…”

Section: Discussionmentioning

confidence: 99%

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Gene expression in mycorrhizal orchid protocorms suggests a friendly plant–fungus relationship

Perotto

Rodda

Benetti

et al. 2014

Planta

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Main conclusionOrchid mycorrhiza has been often interpreted as an antagonistic relationship. Our data on mycorrhizal protocorms do not support this view as plant defence genes were not induced, whereas some nodulinlike genes were significantly up-regulated.Orchids fully depend on symbiotic interactions with specific soil fungi for seed germination and early development. Germinated seeds give rise to a protocorm, a heterotrophic organ that acquires nutrients, including organic carbon, from the mycorrhizal partner. It has long been debated if this interaction is mutualistic or antagonistic. To investigate the molecular bases of the orchid response to mycorrhizal invasion, we developed a symbiotic in vitro system between Serapias vomeracea, a Mediterranean green meadow orchid, and the rhizoctonia-like fungus Tulasnella calospora. 454 pyrosequencing was used to generate an inventory of plant and fungal genes expressed in mycorrhizal protocorms, and plant genes could be reliably identified with a customized bioinformatic pipeline. A small panel of plant genes was selected and expression was assessed by real-time quantitative PCR in mycorrhizal and non-mycorrhizal protocorm tissues. Among these genes were some markers of mutualistic (e.g. nodulins) as well as antagonistic (e.g. pathogenesis-related and wound/stress-induced) genes. None of the pathogenesis or wound/stress-related genes were significantly up-regulated in mycorrhizal tissues, suggesting that fungal colonization does not trigger strong plant defence responses. In addition, the highest expression fold change in mycorrhizal tissues was found for a nodulin-like gene similar to the plastocyanin domaincontaining ENOD55. Another nodulin-like gene significantly more expressed in the symbiotic tissues of mycorrhizal protocorms was similar to a sugar transporter of the SWEET family. Two genes coding for mannose-binding lectins were significantly up-regulated in the presence of the mycorrhizal fungus, but their role in the symbiosis is unclear.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Gene expression in mycorrhizal orchid protocorms suggests a friendly plant–fungus relationship

Perotto

Rodda

Benetti

et al. 2014

Planta

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“…The source is involved in the storage and transport of nutrients in plants (Ruan 2014;Rolland et al 2002). However, sugar cannot be transported independently across the plant cell membrane system and requires the assistance of appropriate sugar transporters, such as MSTs (monosaccharide transporters) (Slewinski 2011), SUTs (sucrose transporters) (Kuhn and Grof 2010;Ayre 2011) and SWEETs (sugars will eventually be exported transporters) (Chen et al 2010).…”

Section: Introductionmentioning

confidence: 99%

“…SWEET shows the function of bidirectional reversible transport of sugar, and promotes the diffusion of sucrose to the apoplast pathway through transmembrane across the gradient of concentration on cell efflux (Baker et al 2012;Lin et al 2014;Eom et al 2015). Since SWEET was first discovered using Forster resonance energy transfer (FRET) by optical glucose sensors (Chen et al 2010), SWEET family members have been identified by genome-wide analyses in different plant species, such as Arabidopsis (Chen et al 2010), rice (Yuan and Wang 2013), tomato (Feng et al 2015), soybean (Patil et al 2015) and cucumber (Hu et al 2017).…”

Section: Introductionmentioning

confidence: 99%

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A genome-wide analysis of SWEET gene family in cotton and their expressions under different stresses

et al. 2018

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Background: The SWEET (Sugars will eventually be exported transporters) gene family plays multiple roles in plant physiological activities and development process. It participates in reproductive development and in the process of sugar transport and absorption, plant senescence and stress responses and plant-pathogen interaction. However, thecomprehensive analysis of SWEET genes has not been reported in cotton.

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The SWEET gene family in Hevea brasiliensis – its evolution and expression compared with four other plant species

Sui

Xiao

et al. 2017

FEBS Open Bio

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SWEET proteins play an indispensable role as a sugar efflux transporter in plant development and stress responses. The SWEET genes have previously been characterized in several plants. Here, we present a comprehensive analysis of this gene family in the rubber tree, Hevea brasiliensis . There are 36 members of the SWEET gene family in this species, making it one of the largest families in plant genomes sequenced so far. Structure and phylogeny analyses of these genes in Hevea and in other species demonstrated broad evolutionary conservation. RNA‐seq analyses revealed that SWEET2, 16, and 17 might represent the main evolutionary direction of SWEET genes in plants. Our results in Hevea suggested the involvement of HbSWEET1a , 2e , 2f , and 3b in phloem loading, HbSWEET10a and 16b in laticifer sugar transport , and HbSWEET9a in nectary‐specific sugar transport. Parallel studies of RNA‐seq analyses extended to three other plant species ( Manihot esculenta , Populus trichocarpa , and Arabidopsis thaliana ) produced findings which implicated MeSWEET10a, 3a, and 15b in M. esculenta storage root development, and the involvement of PtSWEET16b and PtSWEET16d in P. trichocarpa xylem development. RT‐qPCR results further revealed that HbSWEET10a, 16b, and 1a play important roles in phloem sugar transport. The results from this study provide a foundation not only for further investigation into the functionality of the SWEET gene family in Hevea, especially in its sugar transport for latex production, but also for related studies of this gene family in the plant kingdom.

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Sugar transporters for intercellular exchange and nutrition of pathogens

Cited by 1,301 publications

References 57 publications

Gene expression in mycorrhizal orchid protocorms suggests a friendly plant–fungus relationship

Gene expression in mycorrhizal orchid protocorms suggests a friendly plant–fungus relationship

A genome-wide analysis of SWEET gene family in cotton and their expressions under different stresses

The SWEET gene family in Hevea brasiliensis – its evolution and expression compared with four other plant species

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