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PLANT PHYSIOLOGY , Vol 103, Issue 2 335-349, Copyright © 1993 by American Society of Plant Biologists
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ENVIRONMENTAL AND STRESS PHYSIOLOGY |
Transport of Water and Solutes across Maize Roots Modified by Puncturing the Endodermis (Further Evidence for the Composite Transport Model of the Root)
E. Steudle, M. Murrmann and C. A. Peterson
Lehrstuhl fur Pflanzenokologie, Universitat Bayreuth, D-95440 Bayreuth, Germany (E.S., M.M.)
The effects of puncturing the endodermis of young maize roots (Zea mays L.)
on their transport properties were measured using the root pressure probe.
Small holes with a diameter of 18 to 60 [mu]m were created 70 to 90 mm from
the tips of the roots by pushing fine glass tubes radially into them. Such
wounds injured about 10-2 to 10-3% of the total surface area of the
endodermis, which, in these hydroponically grown roots, had developed a
Casparian band but no suberin lamellae. The small injury to the endodermis
caused the original root pressure, which varied from 0.08 to 0.19 MPa, to
decrease rapidly (half-time = 10-100 s) and substantially to a new
steady-state value between 0.02 and 0.07 MPa. The radial hydraulic
conductivity (Lpr) of control (uninjured) roots determined using
hydrostatic pressure gradients as driving forces was larger by a factor of
10 than that determined using osmotic gradients (averages: Lpr
[hydrostatic] = 2.7 x 10-7 m s-1 MPa-1; Lpr [osmotic] = 2.2 x 10-8 m s-1
MPa-1; osmotic solute: NaCl). Puncturing the endodermis did not result in
measurable increases in hydraulic conductivities measured by either method.
Thus, the endodermis was not rate-limiting root Lpr: apparently the
hydraulic resistance of roots was more evenly distributed over the entire
root tissue. However, puncturing the endodermis did substantially change
the reflection ([sigma]sr) and permeability (Psr) coefficients of roots for
NaCl, indicating that the endodermis represented a considerable barrier to
the flow of nutrient ions. Values of [sigma]sr decreased from 0.64 to 0.41
(average) and Psr increased by a factor of 2.6, i.e. from 3.8 x 10-9 to
10.1 x 10.-9 m s-1(average). The roots recovered from puncturing after a
time and regained root pressure. Measurable increases in root pressure
became apparent as soon as 0.5 to 1 h after puncturing, and original or
higher root pressures were attained 1.5 to 20 h after injury. However,
after recovery roots often did not maintain a stable root pressure, and no
further osmotic experiments could be performed with them. The Casparian
band of the endodermis is discontinuous at the root tip, where the
endodermis has not yet matured, and at sites of developing lateral roots.
Measurements of the cross-sectional area of the apoplasmic bypass at the
root tip yielded an area of 0.031% of the total surface area of the
endodermis. An additional 0.049% was associated with lateral root
primordia. These areas are larger than the artificial bypasses created by
wounding in this study and may provide pathways for a "natural bypass flow"
of water and solutes across the intact root. If there were such a pathway,
either in these areas or across the Casparian band itself, roots would have
to be treated as a system composed of two parallel pathways (a cell-to-cell
and an apoplasmic path). It is demonstrated that this "composite transport
model of the root" allows integration of several transport properties of
roots that are otherwise difficult to understand, namely (a) the
differences between osmotic and hydrostatic water flow, (b) the dependence
of root hydraulic resistance on the driving force or water flow across the
root, and (c) low reflection coefficients of roots.
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