Translocation of organic compounds

Helgi Öpik; Stephen A. Rolfe

doi:10.1017/CBO9781139164450.006

Chapter 5 - Translocation of organic compounds

Published online by Cambridge University Press: 05 June 2012

Helgi Öpik and

Stephen A. Rolfe

Edited in consultation with

Arthur J. Willis

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Helgi Öpik: Affiliation:
University of Wales, Swansea
Stephen A. Rolfe: Affiliation:
University of Sheffield
Arthur J. Willis: Affiliation:
University of Sheffield

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Summary

Introduction

Flowering plants are described as being autotrophic, ‘self-feeding’, capable of synthesizing all their organic material via photosynthesis. But a flowering plant is a complex organism with cells and organs specialized for diverse functions, and only the green photosynthetic cells are truly autotrophic; they must accordingly supply all the non-photosynthetic parts with organic carbon. Over small distances, i.e. between individual cells and within small groups of cells, chemicals can move by diffusion through plasmodesmata, or across plasma membranes by diffusion and by active transport. But organic materials must move for long distances; the growing tips of the roots of a tree are many metres away from the nearest photosynthetic leaves and even in a herbaceous plant diffusion would be too slow for the distances involved. We have already seen (Chapter 3) how water moves in plants over long distances in a specialized transport tissue, the xylem. The subject of this chapter is the long-distance, multidirectional movement or translocation of organic compounds which takes place in the phloem.

Phloem as the channel for organic translocation

Evidence for translocation in the phloem

In flowering plants, the xylem is regularly associated with the phloem, the two together making up the vascular tissues. In young organs the two tissues are in contact; when secondary growth occurs they become separated by the vascular cambium, the meristem which then adds xylem to one side and phloem to the other.

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Type: Chapter
Information: The Physiology of Flowering Plants , pp. 133 - 158

DOI: https://doi.org/10.1017/CBO9781139164450.006 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2005

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References

Esau, K. & Cheadle, V. I.Size of pores and their contents in sieve elements of dicotyledons. Proceedings of the National Academy of Sciences (USA), 45 (1959), 156–62.CrossRef Google Scholar PubMed

Fisher, D. B.The estimation of sugar concentration in individual sieve-tube elements by negative staining. Planta, 139 (1978), 19–24.CrossRef Google Scholar PubMed

Fisher, D. B. & Cash-Clark, C. E.Sieve tube unloading and post-phloem transport of fluorescent tracers and proteins injected into sieve tubes via severed aphid stylets. Plant Physiology, 123 (2000), 125–37.CrossRef Google Scholar PubMed

Flowers, T. J. & Yeo, A. R.Solute Transport in Plants. London: Blackie/Chapman & Hall, 1992.CrossRef Google Scholar

Golecki, B., Schulz, A., Carstens-Behrens, U. & Kollmann, R.Evidence of graft transmission of structural phloem proteins or their precursors in heterografts of Cucurbitaceae. Planta, 206 (1998), 630–40.CrossRef Google Scholar

Haupt, S., Duncan, G. H., Holzberg, S. & Oparka, K. J.Evidence for symplastic unloading in sink leaves of barley. Plant Physiology, 125 (2001), 209–18.CrossRef Google Scholar PubMed

Köckenberger, W., Pope, J. M., Xia, Y., Jeffrey, K. R., Komor, E. & Callaghan, P. T.A non-invasive measurement of phloem and xylem water flow in castor bean seedlings by nuclear magnetic resonance microimaging. Planta, 201 (1997), 53–63.CrossRef Google Scholar

Mauseth, J. D.Plant Anatomy. Menlo Park, CA: Benjamin/Cummings, 1988.Google Scholar

Patrick, J. W.Phloem unloading: sieve element unloading and post-sieve element transport. Annual Review of Plant Physiology and Plant Molecular Biology, 48 (1997), 191–222.CrossRef Google Scholar PubMed

Pickard, B. G. & Beachy, R. N.Intercellular connections are developmentally controlled to help move molecules through the plant. Cell, 98 (1999), 5–8.CrossRef Google Scholar PubMed

Sasaki, T., Chino, M., Hayashi, H. & Fujiwara, T.Detection of several mRNA species in rice phloem sap. Plant and Cell Physiology, 39 (1998), 895–7.CrossRef Google Scholar PubMed

Sideman, E. J. & Scheirer, D. C.Some fine structural observations on developing and mature sieve elements in the brown alga Laminaria saccharina. American Journal of Botany, 64 (1977), 649–57.CrossRef Google Scholar

Sweetlove, L. J. & Hill, S. A.Source metabolism dominates the control of source to sink carbon flux in tuberizing potato plants throughout the diurnal cycle and under a range of environmental conditions. Plant, Cell and Environment, 23 (2000), 523–9.CrossRef Google Scholar

Bel, A. J. E.The phloem, a miracle of ingenuity. Plant, Cell and Environment, 26 (2003), 125–49.Google Scholar

Bel, A. J. E. & Gamalei, Y. V.Ecophysiology of phloem loading in source leaves. Plant, Cell and Environment, 15 (1992), 265–70.CrossRef Google Scholar

Versch, J., Kalusche, B., Köhler, J.et al. The kinetics of sucrose concentration in the phloem of individual vascular bundles of the Ricinus communis seedling measured by nuclear magnetic resonance. Planta, 205 (1998), 132–9.CrossRef Google Scholar

Wark, M. C.Fine structure of the phloem of Pisum sativum II. The companion cell and phloem parenchyma. Australian Journal of Botany, 13 (1965), 185–93.Google Scholar

Wark, M. C. & Chambers, T. C.Fine structure of the phloem of Pisum sativum. I. The sieve element ontogeny. Australian Journal of Botany, 13 (1965), 171–83.Google Scholar

Balachandaran, S., Xiang, Y., Schobert, C., Thompson, G. A. & Lucas, W. J. (1997). Phloem sap proteins from Cucurbita maxima and Ricinus communis have the capacity to traffic cell to cell through plasmodesmata. Proceedings of the National Academy of Sciences (USA), 94, 14150–5.CrossRef Google Scholar

Farrar, J. F. (1996). Sinks: integral parts of a whole plant. Journal of Experimental Botany, 47, 1273–9.CrossRef Google Scholar PubMed

Knoblauch, M. & Bel, A. J. E. (1998). Sieve tubes in action. The Plant Cell, 10, 35–50.CrossRef Google Scholar

Matsukura, C., Saitoh, T., Hirose, T., Ohsugi, R., Perata, P. & Yamaguchi, J. (2000). Sugar uptake and transport in rice embryo. Expression of companion cell-specific sucrose transporter (OsSUT1) induced by sugar and light. Plant Physiology, 124, 85–93.CrossRef Google Scholar PubMed

Oparka, K. J. & Santa Cruz, S. (2000). The great escape: phloem transport and unloading of macromolecules. Annual Review of Plant Physiology and Plant Molecular Biology, 51, 323–47.CrossRef Google Scholar

Sjölund, R. D. (1997). The phloem sieve element: a river runs through it. The Plant Cell, 9, 1137–46.CrossRef Google Scholar

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