Drought-Mediated Changes in Tree Physiological Processes Weaken Tree Defenses to Bark Beetle Attack

Drought-Mediated Changes in Tree Physiological Processes Weaken Tree Defenses to Bark Beetle Attack

Interactions between water stress and induced defenses and their role in tree mortality due to bark beetles are poorly understood. We performed a factorial experiment on 48 mature ponderosa pines ( Pinus ponderosa ) in northern Arizona over three years that manipulated a) tree water stress by cuttin...

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Bibliographic Details
Published in:Journal of chemical ecology Vol. 45; no. 10; pp. 888 - 900
Main Authors: Kolb, Thomas, Keefover-Ring, Ken, Burr, Stephen J., Hofstetter, Richard, Gaylord, Monica, Raffa, Kenneth F.
Format: Journal Article
Language:English
Published: New York Springer US 01-10-2019
Springer Nature B.V
Subjects:
3-Carene
Agriculture
Animals
Bark
Beetles
Biochemistry
Biological Microscopy
Biomedical and Life Sciences
Biota
Chromatography, Gas
Coleoptera
Coleoptera - physiology
Drought
Droughts
Ecology
Entomology
Factorial experiments
Gas exchange
Host-Parasite Interactions - drug effects
Leaves
Life Sciences
Limonene
Mortality
Pheromone traps
Phloem
Pine trees
Pinus ponderosa
Pinus ponderosa - chemistry
Pinus ponderosa - metabolism
Plant Bark - chemistry
Plant Bark - metabolism
Plant growth
Resins
Resins, Plant - chemistry
Resins, Plant - metabolism
Seasons
Terpenes
Terpenes - analysis
Terpenes - chemistry
Terpenes - pharmacology
Trees
Water potential
Water stress
Xylem
α-Pinene
Tree mortality
Tree chemical defense
Induced defenses
Drought
Terpenes
Pinus ponderosa
Dendroctonus
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Summary:Interactions between water stress and induced defenses and their role in tree mortality due to bark beetles are poorly understood. We performed a factorial experiment on 48 mature ponderosa pines ( Pinus ponderosa ) in northern Arizona over three years that manipulated a) tree water stress by cutting roots and removing snow; b) bark beetle attacks by using pheromone lures; and c) phloem exposure to biota vectored by bark beetles by inoculating with dead beetles. Tree responses included resin flow from stem wounds, phloem composition of mono- and sesqui-terpenes, xylem water potential, leaf gas exchange, and survival. Phloem contained 21 mono- and sesqui-terpenes, which were dominated by (+)-α-pinene, (−)-limonene, and δ-3-carene. Bark beetle attacks (mostly Dendroctonus brevicomis ) and biota carried by beetles induced a general increase in concentration of phloem mono- and sesqui-terpenes, whereas water stress did not. Bark beetle attacks induced an increase in resin flow for unstressed trees but not water-stressed trees. Mortality was highest for beetle-attacked water-stressed trees. Death of beetle-attacked trees was preceded by low resin flow, symptoms of water stress (low xylem water potential, leaf gas exchange), and an ephemeral increase in concentrations of mono- and sesqui-terpenes compared to surviving trees. These results show a) that ponderosa pine can undergo induction of both resin flow and phloem terpenes in response to bark beetle attack, and that the former is more constrained by water stress; b) experimental evidence that water stress predisposes ponderosa pines to mortality from bark beetles.
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ISSN:0098-0331
1573-1561
DOI:10.1007/s10886-019-01105-0