<i>Tie-dyed2</i>Encodes a Callose Synthase That Functions in Vein Development and Affects Symplastic Trafficking within the Phloem of Maize Leaves

Sap is driven through phloem sieve tubes by an osmotically generated pressure gradient between source and sink tissues. In many plants, source pressure results from thermodynamically active loading in which energy is used to transfer sucrose (Suc) from mesophyll cells to the phloem of leaf minor veins against a concentration gradient. However, in some species, almost all trees, correlative evidence suggests that sugar migrates passively through plasmodesmata from mesophyll cells into the sieve elements. The possibility of alternate loading mechanisms has important ramifications for the regulation of phloem transport and source-sink interactions. Here, we provide experimental evidence that, in gray poplar (Populus tremula 3 Populus alba), Suc enters the phloem through plasmodesmata. Transgenic plants were generated with yeast invertase in the cell walls to prevent Suc loading by this route. The constructs were driven either by the constitutive 35S promoter or the minor vein-specific galactinol synthase promoter. Transgenic plants grew at the same rate as the wild type without symptoms of loading inhibition, such as accumulation of carbohydrates or leaf chlorosis. Rates of photosynthesis were normal. In contrast, alfalfa (Medicago sativa) plants, which have limited numbers of plasmodesmata between mesophyll and phloem, displayed typical symptoms of loading inhibition when transformed with the same DNA constructs. The results are consistent with passive loading of Suc through plasmodesmata in poplar. We also noted defense-related symptoms in leaves of transgenic poplar when the plants were abruptly exposed to excessively high temperatures, adding to evidence that hexose is involved in triggering the hypersensitive response.

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“…The primers used for quantification are listed in Supplemental Table S2. Callose staining followed the procedure in Slewinski et al, 2012.…”

Section: Semiquantitative Analysis Of the Expression Of Pr Gene And Cmentioning

confidence: 99%

Symplastic Phloem Loading in Poplar

et al. 2014

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“…Although apoplasmic phloem loading in maize is physiologically and anatomically well established Heyser et al, 1978;Slewinski et al, 2009Slewinski et al, , 2012, the exact role of ZmSut1 in this process is not well defined. Specifically, does ZmSUT1 mediate Suc phloem loading?…”

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Sucrose Transporter ZmSut1 Expression and Localization Uncover New Insights into Sucrose Phloem Loading

et al. 2016

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“…In maize, the tie dyed1 (Tdy1) mutant is impaired in a regulatory process that affects loading and consequently has a general defect of sugar export (Braun et al, 2006;Ma et al, 2008Ma et al, , 2009). The maize Tdy2 mutant, in which a callose synthase is defective, also displays impaired phloem transport (Slewinski et al, 2012). The Arabidopsis pho3 mutant, which has a weak allele of suc2, has a deficiency of the Suc transporter SUC2 (Gottwald et al, 2000;Zakhleniuk et al, 2001), which controls the influx of Suc into the CC-SE complex.…”

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Increased Expression of a Phloem Membrane Protein Encoded by NHL26 Alters Phloem Export and Sugar Partitioning in Arabidopsis

Vilaine

Kerchev

Clément³

et al. 2013

Plant Cell

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The complex process of phloem sugar transport involves symplasmic and apoplasmic events. We characterized Arabidopsis thaliana lines ectopically expressing a phloem-specific gene encoding NDR1/HIN1-like26 (NHL26), a putative membrane protein. NHL26 overexpressor plants grew more slowly than wild-type plants, accumulated high levels of carbohydrates in mature leaves, and had a higher shoot biomass, contrasting with slower root growth and a lower seed yield. Similar effects were observed when NHL26 was overexpressed in companion cells, under the control of a companion cell-specific promoter. The soluble sugar content of the phloem sap and sink organs was lower than that in the wild type, providing evidence of a sugar export defect. This was confirmed in a phloem-export assay with the symplastic tracer carboxyfluorescein diacetate. Leaf sugar accumulation was accompanied by higher organic acid, amino acid, and protein contents, whereas analysis of the metabolite profile of phloem sap exudate revealed no change in amino acid or organic acid content, indicating a specific effect on sugar export. NHL26 was found to be located in the phloem plasmodesmata and the endoplasmic reticulum. These findings reveal that NHL26 accumulation affects either the permeability of plasmodesmata or sugar signaling in companion cells, with a specific effect on sugar export. INTRODUCTIONPlants are photoautotrophic organisms, producing carbohydrates in photosynthetic organs and distributing them to heterotrophic organs. The phloem manages the partitioning of sugars in the plant, controlling the entry of sugars into the translocation stream, sugar transport from source to sink organs, and delivery to the various competing sink organs (van Bel, 2003). Sugar transport involves the delivery of these molecules from photosynthetic cells to the phloem sieve elements (SEs) (Sjölund, 1997;Lalonde et al., 2003). Three transport strategies have been described in different species: active loading from the apoplasm, passive diffusion via the symplasm, and passive symplasmic transfer followed by polymer trapping (Rennie and Turgeon, 2009). Plasmodesmata (PD) are directly involved in the symplasmic steps, whereas Suc symporters at the plasma membrane of the phloem cells are involved in apoplasmic loading (Dinant and Lemoine, 2010;Ayre, 2011). The sugar loading process comprises several steps (Lalonde et al., 2003;Ayre, 2011), including efflux into the apoplasm by transporters from the SWEET family (Chen et al., 2012) and influx into the companion cell (CC)-SE complex by transporters from the SUC/SUT family (Sauer, 2007). However, other aspects, such as the sugar signaling pathways involved in coordinating the symplasmic or apoplasmic steps and the mechanisms preventing the flow of Suc back through PD in various cell types (Turgeon, 2006) remain unclear. It is also possible that both the apoplasmic and symplasmic pathways contribute to photoassimilate flux (Turgeon and Ayre, 2005). A recent study showed that, in cantaloupe (Cucumis melo), a species define...

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Tie-dyed2Encodes a Callose Synthase That Functions in Vein Development and Affects Symplastic Trafficking within the Phloem of Maize Leaves

Cited by 68 publications

References 76 publications

Symplastic Phloem Loading in Poplar

Symplastic Phloem Loading in Poplar

Sucrose Transporter ZmSut1 Expression and Localization Uncover New Insights into Sucrose Phloem Loading

Increased Expression of a Phloem Membrane Protein Encoded by NHL26 Alters Phloem Export and Sugar Partitioning in Arabidopsis

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