|Kreyling, J; Wiesenberg, Guido LB; Huber, G; Jentsch, A; Konnert, M; Thiel, D; Walter, J; Wohlfahrt, C; Beierkuhnlein, C: Cold hardiness of Pinus nigra Arnold as influenced by geographic origin, warming, and extreme summer drought, Environmental and Experimental Botany, 78, 99-108 (2012), doi:10.1016/j.envexpbot.2011.12.026|
|Key words: EVENT 3|
Adaptation to the adverse effects of climate change is being investigated more and more through the introduction of species from warmer and drier climates, such as the (sub-) mediterranean Pinus nigra to dry sites in temperate Central Europe. Winter survival, however, may pose a serious threat to this strategy as cold extremes, which naturally determine the poleward range limits of forest trees, are not expected to follow the general warming trend in the near future. Here, juveniles of P. nigra from eight provenances throughout Europe were exposed to different climate change scenarios (factorial combinations of 42 days of drought and warming by 1.6°C) in a common garden experiment in Bayreuth, Germany. Cold hardiness (LT50) was determined by the Relative Electrolyte Leakage method (REL) in two consecutive winters. Cold hardiness of foliage differed by 10°C between the provenances studied and a local adaptation to minimum temperature was found. Cold hardiness was further affected by extreme summer drought, increasing cold hardiness by 3.9°C on average in the subsequent winter, and by summer warming, increasing cold hardiness by 3.4°C. Year-round warming had no significant effect on cold hardiness. Cold hardiness was related to the content of soluble carbohydrates and to the composition of fatty acids and alkanes in the needles. Juveniles of P. nigra exhibited a comparable cold hardiness as juveniles of species native to Central Europe (P. sylvestris, Picea abies, Fagus sylvatica and Quercus petraea) under the same climatic conditions. Cold hardiness of the fine roots of P. nigra averaged -16.5°C compared to -23.8°C on average for needles. Our results imply that the cold hardiness of the foliage is adaptive to both long-term growing conditions at the seed origin (genetic heritage) and short-term alterations of these conditions (individual plasticity), while first hints suggest that cold hardiness of the roots is high and might not be adaptive. For P. nigra, below- and above-ground cold hardiness of selected provenances in mid-winter appear suitable for cultivation in temperate regions.
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