Honey Mesquite Water Relations and Gas Exchange Following Herbicide-Induced Morphological Change

Honey mesquite (Prosopis glandulosa Torr.) may maintain apical dominance after a treatment that causes partial top-kill (PTK) and leaves canopies with “stem flagging.” In contrast, top-killing treatments stimulate multistemmed regrowth (i.e., basal sprouting; BSP). Because this difference may impact...

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Bibliographic Details
Published in:Rangeland ecology & management 2020-09, Vol.73 (5), p.673-686
Main Authors: Cooper, Caitlyn E., Zhang, Tian, Ansley, R. James
Format: Article
Language:English
Subjects:
administrative management
Apical dominance
Basal sprouting
Canopies
canopy
Conductance
Gas exchange
Grasses
herbicide application
Herbicides
Heterogeneity
Honey
Leaf area
leaf water potential
Leaves
Mesquite
Moisture stress
Partial top-kill
Photosynthesis
Physiology
Prescribed fire
Prosopis
Prosopis glandulosa
Protein-tyrosine kinase
rangelands
Regrowth
Resistance
Savannahs
savannas
Soil moisture
Soil stresses
soil water
Species diversity
stand density
Stomata
Stomatal conductance
Texas
Top-kill
Transpiration
Trees
Water potential
Water relations
Water stress
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Summary:Honey mesquite (Prosopis glandulosa Torr.) may maintain apical dominance after a treatment that causes partial top-kill (PTK) and leaves canopies with “stem flagging.” In contrast, top-killing treatments stimulate multistemmed regrowth (i.e., basal sprouting; BSP). Because this difference may impact competition with grasses, a better understanding of physiology associated with PTK and BSP canopies compared with untreated canopies is needed. We quantified predawn leaf water potential (ΨPD), leaf-level gas exchange rates (photosynthesis [A] and stomatal conductance [gs]), and whole-tree stomatal conductance (Gs) of untreated, PTK, and BSP mesquites 2–11 yr after aerial herbicide application in a north Texas savanna. Total leaf area was nearly 4 × greater in untreated and BSP compared with PTK trees. In a few situations where soil moisture stress was greatest, untreated mesquites exhibited more negative ΨPD and lower leaf-level gas exchange than did PTK mesquites. BSP mesquites occasionally had greater ΨPD and leaf-level gas exchange than untreated mesquites. Since imbalances in root-to-shoot ratios caused by PTK were largely not manifested at the leaf-physiology level, PTK mesquites likely adjusted rapidly to herbicide disturbance. When gs was scaled to the whole canopy, Gs estimates were 3–4 × greater in untreated and BSP than PTK trees. Thus, canopy leaf area was the primary driver of differences in whole-canopy Gs. It is LIKELY that transpiration would be lower in a stand of untreated mesquites compared with PTK mesquites of similar stand density and basal areas before treatment, as results from comparing untreated and PTK mesquites indicate. Partially top-killed trees that maintain apical dominance and do not resprout should compete less with grasses for water and light and facilitate species diversity and heterogeneity.
ISSN:1550-7424
1551-5028
DOI:10.1016/j.rama.2020.06.002