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PLANT PHYSIOLOGY , Vol 101, Issue 3 1063-1071, Copyright © 1993 by American Society of Plant Biologists
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PLANT-MICROBE INTERACTIONS |
Growth Depression in Mycorrhizal Citrus at High-Phosphorus Supply (Analysis of Carbon Costs)
S. Peng, D. M. Eissenstat, J. H. Graham, K. Williams and N. C. Hodge
Citrus Research and Education Center, University of Florida, Institute of Food and Agricultural Sciences, Lake Alfred, Florida 33850 (S.P., D.M.E., J.H.G.)
Mycorrhizal-induced growth depression of plants in high-P soil has been
reported in many species. The carbon costs of factors contributing to this
growth depression were analyzed in Volkamer lemon (Citrus volkameriana Tan.
& Pasq.) colonized by the mycorrhizal (M) fungus Glomus intraradices
Schenck and Smith. M and nonmycorrhizal (NM) plants were each grown at two
P-supply rates. Carbon budgets of M and NM plants were determined by
measuring whole-plant carbon assimilation and respiration rates using
gas-exchange techniques. Biomass, M colonization, tissue-P concentration,
and total fatty acid concentration in the fibrous roots were determined.
Construction costs of the fibrous roots were estimated from heat of
combustion, N, and ash content. Root-growth respiration was derived from
daily root growth and root-construction cost. M and NM plants grown in
high-P soil were similar in P concentration, daily shoot carbon
assimilation, and daily shoot dark respiration. At 52 d after transplanting
(DAT), however, combined daily root plus soil respiration was 37% higher
for M than for NM plants, resulting in a 20% higher daily specific carbon
gain (mmol CO2 [mmol carbon]-1 d-1) in NM than M plants. Estimates of
specific carbon gain from specific growth rates indicated about a 10%
difference between M and NM plants. Absolute values of specific carbon gain
estimated by whole-plant gas exchange and by growth analysis were in
general agreement. At 52 DAT, M and NM plants at high P had nearly
identical whole-plant growth rates, but M plants had 19% higher root dry
weight with 10% higher daily rates of root growth. These allocation
differences at high P accounted for about 51% of the differences in
root/soil respiration between M and NM plants. Significantly higher fatty
acid concentrations in M than NM fibrous roots were correlated with
differences in construction costs of the fibrous roots. Of the 37%
difference in daily total root/soil respiration observed between high-P M
and NM plants at 52 DAT, estimated daily growth respiration accounted for
only about 16%, two-thirds of which was associated with construction of
lipid-rich roots, and the remaining one-third with greater M root growth
rates. Thus, of the 37% more root/soil respiration associated with M
colonization of high-P plants, 10% was directly attributable to building
lipid-rich roots, 51% to greater M root biomass allocation, and the
remaining 39% could have been used for maintenance of the fungal tissue in
the root and growth and maintenance of the extramatrical hyphae.
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