Evidence for functional heterogeneity of sieve element–companion cell complexes in minor vein phloem of Alonsoa meridionalis

Voitsekhovskaja, Olga V.; Rudashevskaya, Elena L.; Demchenko, Kirill N.; Pakhomova, M. V.; Batashev, Denis R.; Gamalei, Yuri V.; Lohaus, Gertrud; Pawlowski, Katharina

doi:10.1093/jxb/erp074

Cited by 40 publications

(39 citation statements)

References 33 publications

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“…The percentage of Asteridae species with “open” minor vein cytology which also contain sieve-element-companion cell complexes with “closed” cytology, i.e., that show specialization for both symplasmic and apoplasmic phloem loading, was determined. Along with recent data confirming the dissimilar functional specialization of structurally different parts of minor vein phloem in the stachyose-translocating species Alonsoa meridionalis (Voitsekhovskaja et al, 2009), these findings suggest that apoplasmic loading is indispensable in a large group of species previously classified as putative symplasmic loaders. Altogether, this study provides formal classifications of companion cells and of minor veins, respectively, in 24 families of the Asteridae based on their structural features, opening the way to a close investigation of the relationship between structure and function in phloem loading.…”

supporting

confidence: 76%

“…In all these cases, there are asymmetrically branched plasmodesmata the exclusion limit of which is probably regulated, analogous to the situation in ICs. The polymer trap model proposing RFO synthesis as a mechanism regulating barrier properties of such plasmodesmata in species with ICs was cast into doubt based on results obtained using the ICs-containing species Alonsoa meridionalis (Voitsekhovskaja et al, 2006, 2009); moreover, in leaves of species containing MIC-b and CC-b, no RFOs could be detected by GC-MS which, considering the sensitivity of the method, leads to the conclusion that RFOs cannot be the main transport form in these species, at least not at all developmental stages.…”

Section: Discussionmentioning

confidence: 99%

“…At the same time, many plants contain companion cells of more than one structural type in their minor veins, a fact which renders them beyond the scope of a division into “open” and “closed” types and becomes important when analyzing phloem loading mechanisms and their relative contribution to phloem transport in a given species. An example is Alonsoa meridionalis , a type 1 species, which contains ICs in its minor veins and was originally classified as a putative symplasmic loader but was shown to perform also apoplasmic sucrose loading in a second type of companion cells present in its minor veins, the OC (Voitsekhovskaja et al, 2009). Thus, a comprehensive view of a phloem ending as a functional unit can rely only on the cytology of all cells involved in assimilate loading.…”

Section: Introductionmentioning

confidence: 99%

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Cytology of the minor-vein phloem in 320 species from the subclass Asteridae suggests a high diversity of phloem-loading modes†

Batashev¹,

Pakhomova²,

Razumovskaya³

et al. 2013

Front. Plant Sci.

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The discovery of abundant plasmodesmata at the bundle sheath/phloem interface in Oleaceae (Gamalei, 1974) and Cucurbitaceae (Turgeon et al., 1975) raised the questions as to whether these plasmodesmata are functional in phloem loading and how widespread symplasmic loading would be. Analysis of over 800 dicot species allowed the definition of “open” and “closed” types of the minor vein phloem depending on the abundance of plasmodesmata between companion cells and bundle sheath (Gamalei, 1989, 1990). These types corresponded to potential symplasmic and apoplasmic phloem loaders, respectively; however, this definition covered a spectrum of diverse structures of phloem endings. Here, a review of detailed cytological analyses of minor veins in 320 species from the subclass Asteridae is presented, including data on companion cell types and their combinations which have not been reported previously. The percentage of Asteridae species with “open” minor vein cytology which also contain sieve-element-companion cell complexes with “closed” cytology, i.e., that show specialization for both symplasmic and apoplasmic phloem loading, was determined. Along with recent data confirming the dissimilar functional specialization of structurally different parts of minor vein phloem in the stachyose-translocating species Alonsoa meridionalis (Voitsekhovskaja et al., 2009), these findings suggest that apoplasmic loading is indispensable in a large group of species previously classified as putative symplasmic loaders. Altogether, this study provides formal classifications of companion cells and of minor veins, respectively, in 24 families of the Asteridae based on their structural features, opening the way to a close investigation of the relationship between structure and function in phloem loading.

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supporting

confidence: 76%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Cytology of the minor-vein phloem in 320 species from the subclass Asteridae suggests a high diversity of phloem-loading modes†

Batashev¹,

Pakhomova²,

Razumovskaya³

et al. 2013

Front. Plant Sci.

Self Cite

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“…Consistent with this hypothesis is that downregulation of a key RFO biosynthetic gene depressed photoassimilate export (McCaskill & Turgeon 2007). In some RFO-translocating species, SUTs may be present in SE/CC complexes but absent from ICs, indicating concurrent sym-and apoplastic loading within the same vein (e.g., Voitsekhovskaja et al 2009). However, transgenic downregulation of SUT activity does not affect photoassimilate export, suggesting SUTs in symplastic species serve to retrieve sucrose leaked from transport phloem rather than a loading function per se (Zhang & Turgeon 2009).…”

Section: Phloem Loadingmentioning

confidence: 80%

Phloem Transport of Resources

Grof¹,

Byrt²,

Patrick³

2013

Sugarcane: Physiology, Biochemistry, and Functional Biology

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This chapter reviews the principles and concepts of resource transport in the phloem in general and then moves to describe the physiology of phloem translocation in sugarcane. The movement of resources through the phloem is interpreted through the Münch pressure flow hypothesis. The phloem transport rate is determined by magnitudes of pressure differences between the source and sink ends of the pathway and the phloem sap concentration of each transported nutrient. Phloem rate is regulated by loading and unloading activities, sink hydrostatic pressures, and hydraulic conductivities of plasmodesmata interconnecting sieve element/companion cell complexes with phloem parenchyma cells. A description of the leaf structural framework in sugarcane is provided and the phloem pathways in sugarcane are dissected from loading of collection phloem in source leaves, transit through transport phloem, to release phloem where resources are unloaded into growth and storage sinks. Phloem conductivities in sugarcane, mechanisms of loading and unloading of solutes, and the environmental effects on phloem translocation are considered.

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“…However, available evidence does not support the presence of complementary apoplastic and symplastic mechanisms in intermediary cells: The Suc transporter does not immunolocalize to the intermediary cell plasma membrane (Voitsekhovskaja et al, 2009). It is possible, even likely, that apoplastic loading occurs in other companion cells in RFO plants (those that do not express the RFO pathway), but if so this contribution is apparently minimal since blocking the Suc transporter chemically (Turgeon and Gowan, 1990) or by RNAi (Zhang and Turgeon, 2009) does not noticeably inhibit growth.…”

Section: Discussionmentioning

confidence: 99%

Phloem Loading through Plasmodesmata: A Biophysical Analysis

2017

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In many species, Suc en route out of the leaf migrates from photosynthetically active mesophyll cells into the phloem down its concentration gradient via plasmodesmata, i.e. symplastically. In some of these plants, the process is entirely passive, but in others phloem Suc is actively converted into larger sugars, raffinose and stachyose, and segregated (trapped), thus raising total phloem sugar concentration to a level higher than in the mesophyll. Questions remain regarding the mechanisms and selective advantages conferred by both of these symplastic-loading processes. Here, we present an integrated model-including local and global transport and kinetics of polymerization-for passive and active symplastic loading. We also propose a physical model of transport through the plasmodesmata. With these models, we predict that (1) relative to passive loading, polymerization of Suc in the phloem, even in the absence of segregation, lowers the sugar content in the leaf required to achieve a given export rate and accelerates export for a given concentration of Suc in the mesophyll and (2) segregation of oligomers and the inverted gradient of total sugar content can be achieved for physiologically reasonable parameter values, but even higher export rates can be accessed in scenarios in which polymers are allowed to diffuse back into the mesophyll. We discuss these predictions in relation to further studies aimed at the clarification of loading mechanisms, fitness of active and passive symplastic loading, and potential targets for engineering improved rates of export.

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Evidence for functional heterogeneity of sieve element–companion cell complexes in minor vein phloem of Alonsoa meridionalis

Cited by 40 publications

References 33 publications

Cytology of the minor-vein phloem in 320 species from the subclass Asteridae suggests a high diversity of phloem-loading modes†

Cytology of the minor-vein phloem in 320 species from the subclass Asteridae suggests a high diversity of phloem-loading modes†

Phloem Transport of Resources

Phloem Loading through Plasmodesmata: A Biophysical Analysis

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