Dynamics of low-temperature acclimation in temperate and boreal conifer foliage in a mild winter climate

To provide baseline data for physiological studies of extreme low-temperature (LT) tolerance in boreal conifers, we profiled LT stress responses, liquid nitrogen (LN2)-quench tolerance, and sugar concentrations in foliage of boreal-temperate species pairs in the genera Abies, Picea and Pinus, growin...

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Bibliographic Details
Published in:Tree physiology 2008-09, Vol.28 (9), p.1365-1374
Main Authors: Strimbeck, G. Richard, Kjellsen, Trygve D, Schaberg, Paul G, Murakami, Paula F
Format: Article
Language:English
Subjects:
Abies
acclimation
Acclimatization
boreal species
Carbohydrate Metabolism
chemical concentration
Cold Climate
cold stress
Cold Temperature
cold tolerance
conifer needles
conifers
forest trees
geographical distribution
liquid nitrogen quench
Nitrogen - pharmacology
Picea
Pinaceae - drug effects
Pinaceae - metabolism
Pinaceae - physiology
Pinus
Plant Leaves - drug effects
Plant Leaves - metabolism
Plant Leaves - physiology
provenance
species differences
sugars
temperate species
temperature
winter hardiness
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Summary:To provide baseline data for physiological studies of extreme low-temperature (LT) tolerance in boreal conifers, we profiled LT stress responses, liquid nitrogen (LN2)-quench tolerance, and sugar concentrations in foliage of boreal-temperate species pairs in the genera Abies, Picea and Pinus, growing in an arboretum in a temperate oceanic climate from August 2006 through April 2007. The boreal species acclimated more rapidly and deeply than the temperate species, acquiring LN2-quench tolerance by late November, despite unusually warm conditions throughout the autumn and early winter. Maximum LT tolerance in the temperate species was in the -25 to -35 °C range, and was reached only after a period of freezing temperatures in late January and February. During LT acclimation in the temperate species, sigmoid temperature-relative electrolyte leakage (REL) curves shifted toward lower temperatures, whereas in boreal species there was both a temperature shift and a lowering of the maximum REL until it fell below a threshold associated with irreversible injury. These differences may reflect differences in mechanisms of LT acclimation and LT tolerance. The concentrations of total and individual sugars did not show a clear pattern that could differentiate the boreal and temperate groups. Raffinose and, in three of the six species, stachyose showed the closest association with LT tolerance. Sugar concentrations, principally sucrose, decreased during mild weather, perhaps because of respiratory losses or phloem export, and increased after periods of freezing temperatures. Low-temperature acclimation in boreal species appears to follow a rigid program that may affect their ability to avoid excessive respiratory losses in the event of continued climate warming in boreal regions.
ISSN:0829-318X
1758-4469
DOI:10.1093/treephys/28.9.1365