eBook - ePub

Vascular Transport in Plants

Name: Vascular Transport in Plants
Author: N. Michelle Holbrook,Maciej A. Zwieniecki

N. Michelle Holbrook,Maciej A. Zwieniecki

592 Seiten
English
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eBook - ePub

Vascular Transport in Plants

N. Michelle Holbrook,Maciej A. Zwieniecki

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Inhaltsverzeichnis

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Über dieses Buch

Vascular Transport in Plants provides an up-to-date synthesis of new research on the biology of long distance transport processes in plants. It is a valuable resource and reference for researchers and graduate level students in physiology, molecular biology, physiology, ecology, ecological physiology, development, and all applied disciplines related to agriculture, horticulture, forestry and biotechnology. The book considers long-distance transport from the perspective of molecular level processes to whole plant function, allowing readers to integrate information relating to vascular transport across multiple scales. The book is unique in presenting xylem and phloem transport processes in plants together in a comparative style that emphasizes the important interactions between these two parallel transport systems.

Includes 105 exceptional figures
Discusses xylem and phloem transport in a single volume, highlighting their interactions
Syntheses of structure, function and biology of vascular transport by leading authorities
Poses unsolved questions and stimulates future research
Provides a new conceptual framework for vascular function in plants

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Information

Verlag

Academic Press

Jahr

2011

ISBN

9780080454238

Thema

Biowissenschaften

Thema

Biophysik

Part I

Fundamentals of transport

Perspectives on the Biophysics of Xylem Transport

William F. Pickard and Peter J. Melcher

Publisher Summary

This chapter provides a brief discussion on cohesion-tension theory. The chapter also focuses on factors that affect hydraulic resistance in plants. It addresses how sap is extruded into the empty tracheary element even though the free energy gradient from soil to xylem seems often to be in the wrong direction, how the element is hydraulically isolated during refilling to avoid its new contents being sucked away in the transpiration stream, and how a refilled vessel ultimately reestablishes hydraulic contact with neighboring conduits in such fashion as to become once again useful in water transport. For xylem sap to flow through the plant, the negative hydrostatic pressure gradient must be large enough to overcome the “resistive” force of sap viscosity and the force of gravity. Because the rate of xylem sap flow through plants is relatively slow, the laminar flow pattern within an individual vessel consists of layers of sap that flow past each other in a sheetlike fashion, with the result that neither eddies nor vortices occur and turbulence is absent. However, in both laminar and turbulent flow, viscosity leads to internal friction, which produces energy dissipation. The cohesion-tension theory still stands as the hegemonic model for understanding long-distance sap transport in plants, but a controversy related to it propelled the development of new ideas and possible alternative paradigms to replace the postulates of cohesion-tension theory.

“I’m sorry to say that the subject I most disliked was mathematics. I have thought about it. I think the reason was that mathematics leaves no room for argument. If you made a mistake, that was all there was to it.” (X, 1992, p. 35)

The fundamentals of the cohesion-tension theory of sap ascent are now well covered in textbooks (Taiz and Zeiger, 2002; Fisher, 2000) with which most in our potential readership are familiar. Moreover, many deeper questions of xylem biophysics were covered in now hoary reviews (Pickard, 1981; Zimmermann, 1983) and have been updated by Tyree in a substantial monograph (Tyree and Zimmermann, 2002); there is no need to be encyclopedic. Nevertheless, any review of xylem biophysics must include at least some discussion of the cohesion-tension theory. This will be followed by a rather more extensive discussion of how embolisms within the transpiration stream might be formed and, more important, resorbed. Since cohesion-tension theory has only recently survived a significant assault on its hegemony, we present a brief discussion of this controversy, including what has been learned. Finally, we focus on factors that affect hydraulic resistance in plants. In each of these endeavors, some effort will be expended to define each concept with clarity and to frame each explanation rigorously.*

The Biophysics of Sap Ascent in the Xylem

Fundamentals of Cohesion-Tension Theory

In broad outline, the cohesion-tension theory is familiar to virtually every worker in plant biology. We shall therefore treat it as an exercise in dogmatics requiring but little exposition.

Dogma I (Hales, 1727, expt. XXXV):* The rise of the xylem sap during transpiration is due to the transpiration itself, the “capillary… orifices” in the leaves being able “as any sap is evaporated off” to “supply the great quantities of sap drawn off by perspiration” by “their strong attraction (assisted by the genial warmth of the sun).” In modern scientific terminology^†: the capillary menisci of the cell walls within the substomatal cavities, being evaporatively depleted by solar heating, contract and draw the sap upwards. Ascribing this core dogma of cohesion-tension theory to Hales is uncommon (but cf. Floto, 1999), it being more usual (e.g., Dixon, 1914; Pickard, 1981) to ascribe it instead to Dixon and Joly (1895) or (e.g., Steudle, 2001) to Böhm (1893).

Dogma II (cf. Dixon, 1914): Water possesses considerable tensile strength, which allows it to be drawn upward by capillary menisci in the leaves. Evidence for this has been reviewed, for example, by Dixon (1914), Pickard (1981), and Steudle (2001).

Dogma III (cf. Haberlandt, 1914): Nevertheless bubbles can form in tracheary elements and interrupt sap flow. This was reported early on (Dixon, 1914; Haberlandt, 1914) and has been much commented upon since (Tyree and Sperry, 1989; McCully, 1999; Canny et al., 2001; Facette et al., 2001).

Dogma IV: Fortunately, plants have developed ways of coping with the challenges posed by emboli. These include (1) anatomical adaptations such as cavitation-resistant conduits and redundancy of hydraulic capacity, (2) new growth, (3) and global pressurization of the xylem as by root pressure. Within the past decade, evidence has appeared for embolus resorption despite the existence of nearby water putatively under tension (e.g., Canny, 1997; McCully et al., 2000; Cochard et al., 2000; Facette et al., 2001; Pickard, 2001; Tyree and Zimmermann, 2002); however, there is as yet no consensus on the precise mechanism(s) by which this might occur (e.g., Hacke and Sperry, 2003; Konrad and Roth-Nebelsick, 2003; Pickard, 2003a; Vesala et al., 2003; Chapter 18, this volume).

The Etiology of an Embolism

Despite the long awareness of tracheary bubbles, there has always been some uncertainty about the mechanism by which they got there, especially after the discovery within the stem of acoustic (Ritman and Milburn, 1988) and electric (Pickard, 2001) transients, which were assumed to arise from putative* cavitation events within the tracheae.

There are four obvious ways by which tension within a liquid-filled pipe could produce an embolism (Pickard, 1981; Zimmermann, 1983; Tyree, 1997).

Homogeneous Nucleation

Consider a spherical bubble of radius r [m] in a liquid of pressure P [Pa] and surface tension γ [N•m⁻¹]; and let the amount of ideal vapor in the bubble be N [mol]. It then follows from the Young-Laplace equation (Pickard, 1981) and the perfect gas law that the pressure differential across the interface is

2 γ/r+P-3/4NRT/ ({πr}^{3})

(1)

where R [= 8.314 J•mol⁻¹•K⁻¹] is the gas constant and T [K] is the absolute temperature. If the net pressure begins positive, then the bubble will shrink to zero as liquid vapor condenses on its inner surface and other gas is pressurized into solution. If it begins negative and P < 0, then the bubble should expand and fill the available space. What is required is an initial bubble radius such that the net pressure across the interface is negative; and we do not know why that might occur. Detailed theoretical treatments have tradi...

Inhaltsverzeichnis

Cover image
Title page
Table of Contents
Contributors
Preface
Acknowledgment
Part I: Fundamentals of transport
Part II: Transport attributes of leaves, roots, and fruits
Part III: Integration of xylem and phloem
Part IV: Development, structure, and function
Part V: Limits to long distance transport
Part VI: Evolution of transport tissues
Part VII: Synthesis
Index
Physiological Ecology

Zitierstile für Vascular Transport in Plants

APA 6 Citation

[author missing]. (2011). Vascular Transport in Plants ([edition unavailable]). Elsevier Science. Retrieved from https://www.perlego.com/book/1836832/vascular-transport-in-plants-pdf (Original work published 2011)

Chicago Citation

[author missing]. (2011) 2011. Vascular Transport in Plants. [Edition unavailable]. Elsevier Science. https://www.perlego.com/book/1836832/vascular-transport-in-plants-pdf.

Harvard Citation

[author missing] (2011) Vascular Transport in Plants. [edition unavailable]. Elsevier Science. Available at: https://www.perlego.com/book/1836832/vascular-transport-in-plants-pdf (Accessed: 15 October 2022).

MLA 7 Citation

[author missing]. Vascular Transport in Plants. [edition unavailable]. Elsevier Science, 2011. Web. 15 Oct. 2022.