Assessing Autumn Cold Hardiness in Newly Planted Fruit Trees and Grapevines

Yıl 2024, Cilt: 41 Sayı: 3, 82 - 89

Ayşe Nilgün Atay , Ersin Atay

https://doi.org/10.16882/hortis.1522161

Öz

Low-temperature damage is one of the key factors that limits the distribution of tree species in an area. This damage is not always the result of low temperatures in winter or during bloom. Actively growing trees or parts of trees do not harden, may be injured by lower temperatures or erratic temperature fluctuations in autumn. It is essential that the capability of each separate scion/rootstock combination to tolerate cold temperatures should be tested especially when the trees are young and a serious climate change is taking place. The overall goal of this study was to investigate the effect of early autumn temperature on fruit and grapevine species, including various cultivars and rootstocks, after plantings and to determine the cold hardiness. The autumn term of 2022 was one of the periods we have experienced notable temperature fluctuations was observed, particularly in September. The day-night temperature difference reached 21.5°C on September 24. Subsequent field observations revealed significant variation in autumn cold tolerance among species, cultivars, and rootstocks. In this study, cold injury was observed in fifteen of the 29 examined species in the autumn after planting. During unfavourable autumn conditions, young trees of fig, persimmon, walnut, and chestnut cultivars were classified as very susceptible. It is most likely that the hardening process in these four species was more affected by erratic temperature fluctuations in the early phase of hardening.

Anahtar Kelimeler

Cultivar, Rootstock, Hardening, Nursery trees, Climate change

Kaynakça

• Améglio, T., Decourteix, M., Alves, G., Valentin, V., Sakr, S., Julien, J.L., Pétel, G., Guilliot, A., & Lacointe, A (2004). Temperature effects on xylem sap osmolarity in walnut trees: evidence for a vitalistic model of winter embolism repair. Tree Physiology, 24:785–793.
• Arora, R., & Taulavuori, K. (2016). Increased risk of freeze damage in woody perennials VIS-À-VIS climate change: Importance of deacclimation and dormancy response. Frontiers in Environmental Science, 4:44.
• Arias, N.S., Bucci, S.J., Scholz, F.G., & Goldstein, G. (2015). Freezing avoidance by supercooling in Olea europaea cultivars: the role of apoplastic water, solute content and cell wall rigidity. Plant, Cell & Environment, 38: 2061–2070.
• Arisz, S.A., Wijk, R.V., Roels, W., Zhu, J.K., Haring, M.A., & Munnik, T. (2013). Rapid phosphatidic acid accumulation in response to low temperature stress in Arabidopsis is generated through diacylglycerol kinase. Frontiers in Plant Science, 4:1–15.
• Ashworth, E.N., & Wisniewski, M.E. (1991). Response of fruit tree tissues to freezing temperatures. HortScience, 26: 501-504.
• Charrier, G., & Améglio, T. (2011). The timing of leaf fall affects cold acclimation by interactions with air temperature through water and carbohydrate contents. Environmental and Experimental Botany, 72:351–357.
• Charrier, G., Bonhomme, M., Lacointe, A., & Améglio, T. (2011). Are budburst dates, dormancy and cold acclimation in walnut trees (Juglans regia L.) under mainly genotypic or environmental control? Int J Biometeorol, 55:763–774.
• Chmielewski, F.M., Götz, K.P., Weber, K.C., & Moryson, S. (2018). Climate change and spring frost damages for sweet cherries in Germany. International Journal of Biometeorology, 62: 217–228.
• Çelik, H., Ağaoğlu, Y.S., Fidan, Y., Marasalı, B., Söylemezoğlu, G. (1998). Genel Bağcılık. Sunfidan A. Ş. Mesleki Kitaplar Serisi: 1, Ankara, 253s.
• Demirsoy, H., Demirsoy, L., & Lang, G.A. (2022). Research on spring frost damage in cherries. Horticultural Science, 49(2): 89–94.
• Dominguez, T., Hernandez, M.L., Pennycooke, J.C., Jimenez, P., Martinez-Rivas, J.M., San, C., Stockinger, E.J., Sanchez Serrano, J.J., & Sanmartin, M. (2010). Increasing omega-3 desaturase expression in tomato results in altered aroma profile and enhanced resistance to cold stress. Plant Physiology, 153(2):655–665.
• Dumanoglu, H., Erdoğan, V., Kesik, A., Dost, S.E., Albayrak Delialioglu, R., Kocabas, Z., Ernim, C., Macit, T., & Bakir, M. (2019). Spring late frost resistance of selected wild apricot genotypes (Prunus armeniaca L.) from Cappadocia region, Turkey, Scientia Horticulturae, 246: 347-353.
• Gusta, L.V., & Wisniewski, M. (2013). Understanding plant cold hardiness: an opinion. Physiologia Plantarum, 147: 4–14.
• Janes, H., & Kahu, K. (2008). Winter injuries of plum cultivars in winters 2005–2007 in Estonia. Proceedings of International Scientific Conference, Sustainable Fruit Growing: From Plant to Product, May 28 – 31, 2008, Jūrmala – Dobele, Latvia p: 149-153.
• Krasova, N., Ikase, L., & Dēķena, D. (2020). Evaluation of the main biological and production traits of Latvian apple cultivars in the conditions of Central Russia. Agronomy Research, 18(S4): 2727–2742.
• Lenz, A., Hoch, G., Vitasse, Y., & Korner, C. (2013). European deciduous trees exhibit similar safety margins against damage by spring freeze events along elevational gradients. New Phytologist. 200: 1166–1175.
• Lim, C.C., Krebs, S.L., & Arora, R. (2014). Cold hardiness increases with age in juvenile Rhododendron populations. Frontiers in Plant Science, 5: 542.
• Morin, X., Améglio, T., Ahas, R., Kurz-Besson, C., Lanta, V., Lebourgeois, F., Miglietta, F., & Chuine, I., (2007). Variation in cold hardiness and carbohydrate concentration from dormancy induction to bud burst among provenances of three European oak species. Tree Physiology, 27:817–825.
• Mukhopadhyay, J., Roychoudhury, A. (2018). Cold-Induced Injuries and Signaling Responses in Plants. Wani, S. H., Herath, V. (eds.) Cold Tolerance in Plants, Springer Nature Switzerland.
• Neuner, G., Monitzer, K., Kaplenig, D., & Ingruber, J., (2019). Frost survival mechanism of vegetative buds in temperate trees: Deep supercooling and extraorgan freezing vs. ice tolerance. Frontiers in Plant Science, 10:537.
• Pearce, R.S. (2001). Plant freezing and damage. Annual Botany, 87:417–424.
• Poirier, M., Lacointe, A., & Améglio, T. (2010). A semi-physiological model of cold hardening and dehardening in walnut stem. Tree Physiology, 30: 1555–1569.
• Pogosyan, K.S., & Sakai, A. (1969). Freezing resistance in grape vines. Low Temp Sci Ser B 27:125–142.
• R Core Team, (2022). R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. URL https://www.R-project.org/.
• Ren, C., Fan, P., Li, S., Liang, Z. (2023). Advances in understanding cold tolerance in grapevine. Plant Physiology, 192(3): 1733–1746.
• Repo, T., Wu, D., & Hänninen, H., (2021). Autumn cold acclimation of shoots does not explain the northern distribution limit of three southern exotic tree species in Finland. Environmental and Experimental Botany, 188.
• Rochette, P., Bélanger, G., Castonguay, Y., Bootsma, A., & Mongrain, D. (2004). Climate change and winter damage to fruit trees in eastern Canada. Canadian Journal of Plant Science, 84: 1113–1125.
• Rodrigo, J. (2000). Spring frosts in deciduous fruit trees: morphological damage and fower hardiness. Scientia Horticulturae, 85:155–173.
• Shi, Y.T., Ding, Y.L., & Yang, S.H. (2015). Cold signal transduction and its interplay with phytohormones during cold acclimation. Plant Cell Physiology, 56(1): 7–15.
• Tauzin, A.S., & Giardina, T. (2014). Sucrose and invertases, a part of the plant defense response to the biotic stresses. Frontiers in Plant Science, 5: 541.
• Tromp, J. (2005). Frost and plant hardiness. In: Tromp, J., Webster, A.D., Wertheim, S.J. (eds.). Fundamentals of temperate zone tree fruit production. Leiden, The Netherlands, p. 74-83.
• Vitasse, Y. (2013). Ontogenic changes rather than difference in temperature cause understory trees to leaf out earlier. New Phytologist, 198, 149–155.
• Vitasse, Y., Lenz, A., & Körner, C. (2014). The interaction between freezing tolerance and phenology in temperate deciduous trees. Frontiers in Plant Science, 5: 541.
• Yu, D.J., & Lee, H.J. (2020). Evaluation of freezing injury in temperate fruit trees. Horticulture, Environment, and Biotechnology, 61: 787–794.
• Walke, C.J. (2014). Cold Hardiness and Winter Injury in Fruit Trees. https://www.mofga.org/resources/ orcharding/cold-hardiness-and-winter-injury-in-fruit-trees/. Date accessed: February 02, 2024. Westwood, M.N. (1993). Temperate-zone Pomology: Physiology and Culture. Timber Press, Portland.
• Wisniewski, M., Nassuth, A., & Arora, R. (2018). Cold Hardiness in Trees: A Mini-Review. Frontiers in Plant Science, 1394.
• Wolkovich, E.M., Cook, B.I., Allen, J.M., Crimmins, T.M., Betancourt, J.L., Travers, S.E., Pau, S., Regetz, J., Davies, T.J., Kraft, N.J.B., Ault, T.R., Bolmgren, K., Mazer, S.J., McCabe, G.J., McGill, B.J., Parmesan, C., Salamin, N., Schwartz M.D., & & Cleland, E.E. (2012). Warming experiments underpredict plant phenological responses to climate change. Nature, 485: 494–497.
• Zuther, E., Schulz, E., Childs, L.H., & Hincha, D.K. (2012). Clinal variation in the non-acclimated and cold-acclimated freezing tolerance of Arabidopsis thaliana accessions. Plant Cell Environment, 35: 1860–1878.