ارزیابی تحمل به شرایط غرقابی نهال های دوساله ون (Fraxinus excelsior L.)
محورهای موضوعی : ژنتیکقاسم علی پاراد 1 , مسعود طبری کوچکسرایی 2 , علی خدادوست 3 , سید احسان ساداتی 4 , نبی عزیزی 5
1 - گروه جنگلداری، دانشکده منابعطبیعی، دانشگاه تربیت مدرس، نور، ایران
2 - گروه جنگلداری، دانشکده منابعطبیعی، دانشگاه تربیت مدرس، نور، ایران
3 - گروه جنگلداری، دانشکده منابعطبیعی، دانشگاه تربیت مدرس، نور، ایران
4 - موسسه تحقیقات جنگلها و مراتع کشور، مازندران، ایران
5 - گروه جنگلداری، دانشکده منابعطبیعی، دانشگاه علوم کشاورزی و منابع طبیعی، تهران، ایران
کلید واژه: رویش قطری, صفات مورفولوژیکی, احیای اراضی, غرقابی موقت, نرخ فتوسنتز,
چکیده مقاله :
هدف این تحقیق بررسی پاسخهای فیزیولوژیکی و موفولوژیکی نهالهای دو ساله ون (Fraxinus excelsior L.) به شرایط غرقابی بود. بدین منظور نهالهای ون در طرحی کاملا تصادفی به مدت 102 روز تحت تاثیر تیمار غرقابی دائم، غرقاب موقت (غرقاب بهمدت 60 روز و به دنبال آن 42 روز زهکشی) و شاهد قرار گرفتند. نتایج نشان داد در پایان دوره، اگرچه کلیه نهالها در هر سه شرایط آزمایش زنده ماندند اما در محیطهای غرقابی، کاهش تدریجی هدایت روزنهای، تعرق و نرخ فتوسنتز در طول تنش مشاهده شد. این در حالی است که پس از حذف عامل تنش (شرایط غرقاب موقت)، نهالها توانستند تا حد زیادی فعالیتهای فیزیولوژیکی خود را احیا کنند. رویش قطری نهالها در تیمار غرقابی موقت افزایش یافت اما مقادیر رویش ارتفاعی، طول ریشه، سطح برگ و وزن خشک اندامهای مختلف نهالها در هر دو محیط غرقابی روند نزولی را طی نمود. بهطورکلی، میتوان اظهار داشت که نهالهای دوساله ون پاسخ مناسبی نسبت به تنش غرقابی تا روز 60ام داده و بعد از 42 روز زهکشی، مشخصههای فیزیولوژیکی آنها بازیابی شد. از این تحقیق میتوان استنتاج کرد که در شمال کشور، در مناطقی که در معرض سیلابهای دورهای قرار دارند بتوان از نهال ون با اهداف احیاء اراضی و تولید چوب استفاده کرد.
The aim of this study was determining the physiological and morphological responses of two-year-old common ash (Fraxinus excelsior L.) seedlings to flooding stress. For this purpose, seedlings of common ash were examined in a completely randomized design for 102 days under continuous flooding, temporary flooding treatment (for 60 and 42 days drainage, respectively) and control. Stomatal conductance, transpiration, and photosynthesis rate were progressively decreased by flooding while all seedlings survived at the end of flooding. Also, flooded plants were able to adequately recover their physiological activities. In addition, height, root length, leaf area, and biomass accumulation of seedlings decreased under flooding conditions (particularly in continuous flooding). Diameter growth on the other hand, increased in seedlings subjected to temporary flooding. Overall, the results showed that two-year-old seedlings of F. excelsior had a suitable response to flooding stress until day 60. After 42 days drainage, the physiological characteristics of the seedlings were recovered. Generally, on the basis of the findings in this research, it is expected that F. excelsior can be used for the purpose of restoration of lowlands and wood production in areas subjected to periodic flooding.
References
Anderson, P.H. and Pezeshki, S.R. (1999). The effect of intermittent flooding on seedling of three forest species. Photosynthetica. 37(4): 543-552.
Bailey-Serres, J. and Chang, R. (2005). Sensing and signalling in response to oxygen deprivation in plants and other organisms. Annals of Botany. 96(4):507-518.
Bailey-Serres, J. and Voesenek, L.A.C.J. (2008). Flooding stress: Acclimations and genetic diversity. Annual Reviews Plant Biology. 59: 313-339.
Calvo-Polanco, M., Senorans, J. and Zwiazek, J.J. (2012). Role of adventitious roots in water relations of tamarack (Larix laricina) seedlings exposed to flooding. BMC Plant Biology. 12: 99-107
Chen, H., Qualls, R.G. and Blank, R.R. (2005). Effect of soil flooding on photosynthesis, carbohydrate partitioning and nutrient uptake in the invasive exotic Lepidium latifolium. Aquatic Botany. 82(4): 250-268.
Colin-Belgrand, M., Dreyer, E. and Biron, P. (1991). Sensitivity of seedlings from different oak species to waterlogging: effects on root growth and mineral nutrition. Annales for Sciences. 48: 193-204.
Davies, F.S. and Flore, J.A. (1986). Flooding, gas exchange and hydraulic conductivity of highbush blueberry. Physiologia Plantarum. 67(4): 545-551.
Domingo, R., Pe´rez–Pastor, A. and Ruiz–Sa´nchez, M.C. (2002). Physiological responses of apricot plants grafted on two different rootstocks to flooding conditions. Journal of Plant Physiology. 159(7): 725-732.
Du, K., Xu, L., Wu, H., Tu, B. and Zheng, B. (2012). Ecophysiological and morphological adaption to soil flooding of two poplar clones differing in flood-tolerance. Flora-Morphology, Distribution, Functional Ecology of Plants. 207(2):96-106.
Farmer, J. and Pezeshki, S. (2004). Effects of periodic flooding and root pruning on Quercus nuttallii seedlings. Wetlands Ecology and Management. 12(3): 205-214.
Glenz, C., Schlaepfer, R., Iorgulescu, I. and Kienast, F. (2006). Flooding tolerance of Central European tree and shrub species. Forest Ecology and Management. 235(1-3): 1-13.
Kai-yue, H., Jing, Y. and Li-bin, H. (2008). Physiological responses of seedlings of two oak species to flooding stress. Forestry Studies in China. 10(4): 259-264.
Imaz J.A., Giménez D.O., Grimoldi A.A. and Striker G.G. (2013). The effects of submergence on anatomical, morphological and biomass allocation responses of tropical grasses Chloris gayana and Panicum coloratum at seedling stage. Crop and Pasture Science. 63(12): 1145-1155.
Imaz J.A., Giménez D.O., Grimoldi A.A. and Striker G.G. (2015). Ability to recover overrides the negative effects of flooding on growth of tropical grasses Chloris gayana and Panicum coloratum. Crop and Pasture Science. 66(1): 100-106.
Islam, M.A. and Macdonald, S.E. (2004). Ecophysiological adaptations of black spruce (Picea mariana) and tamarack (Larix laricina) seedlings to flooding. Trees, Structure and Function. 18(1): 35-42.
Ismond, K.P., Dolferus, R., De Pauw, M., Dennis, E.S. and Good, A.G. (2003). Enhanced low oxygen survival in Arabidopsis through increased metabolic flux in the fermentative pathway. Plant Physiology. 132(3): 1292- 302.
Iwanaga, F. and Yamamoto, F. (2007). Growth, morphology and photosynthetic activity in flooded Alnus japonica seedlings. Journal of Forest Research. 12(3): 243-246.
Kissmann, C., Borges D.V., Eduardo, E., Mayra, T. and Gustavo, H. (2014). Morphological effects of flooding on Styrax pohlii and the dynamics of physiological responses during flooding and post-flooding conditions. Aquatic Botany. 119: 7-14.
Kozlowski, T.T. (1984). Plant responses to flooding of soil. Bioscience. 34(3): 162-167.
Kozlowski, T.T. (1997). Responses of woody plants to flooding and salinity. Tree Physiology Monograph. 1: 1-29.
Larson, K.D., Schaffer, B. and Davies, F.S. (1991). Flooding, leaf gas exchange and growth of mango in containers. Journal of the American Society for Horticultural Science. 116(1): 156-160.
Li, S., Martin, L.T., Pezeshki, S.R. and Shields, J.R.F.D. (2005). Responses of black willow (Salix nigra) cuttings to simulated herbivory and flooding. Acta Oecologica. 28(2): 173-180.
Licausi, F., Van Dongen, J.T., Giuntoli, B., Novi, G., Santaniello, A., Geigenberger, P. and Perata, P. (2010). HRE1 and HRE2, two hypoxia-inducible ethylene response factors, affect anaerobic responses in Arabidopsis thaliana. The Plant Journal. 62(2): 302-315.
McDonald, M.P., Galwey, N.W. and Colmer, T.D. (2002). Similarity and diversity in adventitious root anatomy as related to root aeration among a range of wetland and dryland grass species. Plant, Cell and Environment. 25(3): 441-451.
Megonigal, J.P. and Day, F.P. (1992). Effects of flooding on root and shoot production of bald cypress in large experimental enclosures. Ecology. 73(4): 1182-1193.
Ortuño, M., Alarcón, J., Nicolás, E. and Torrecillas, A. (2007). Water status indicators of lemon trees in response to flooding and recovery. Biologia Plantarum. 51(2): 292-296.
Parad, G.A., Tabari Kouchaksaraei, M., Striker, G.G., Sadati, S.E. and Nourmohammadi, K. (2016). Growth, morphology and gas exchange responses of two-year-old Quercus Castaneifolia seedlings to flooding stress. Scandinavian Journal of Forest Research. 31(5): 458-466.
Parad, G.A., Zarafshar, M., Striker, G.G. and Sattarian, A. (2013a). Some physiological and morphological responses of Pyrus boissieriana to flooding. Trees, Structure and Function. 27(5): 1387-1393.
Parad,G.A., Tabari, M. and Sadati, E. (2014a). Changes of macro and micro elements concentration in shoots and soil of Quercus castaneifolia seedling grown in flooding conditions. Iranian Journal of Forest. 6(1): 23-34.
Parad, G.A., Tabari, M., and Sadati, E. (2013b). Survival, growth and biomass allocation in seedlings of common ash (Fraxinus excelsior L.) as affected by flooding stress. Journal of Applied Biology. 26(1): 9-20.
Parad, G.A., Tabari, M., and Sadati, E. (2014b). Effect of permanent and periodic flooding treatments on growth, morphological and physiological characteristics of one-year old potted seedlings of Quercus castaneifolia in Noor lowland. Journal of Wood and Forest Science and Technology. 20(4): 167-181.
Pezeshki, S.R., Anderson, P.H. and Shields, J.R.F.D. (1998). Effects of soil moisture regimes on growth and survival of black willow (Salix nigra) posts (cuttings). Wetlands. 18(3): 460-470.
Pimentel, P., Almada, D.R., Salvatierra, A., Toro, G., Arismendi, M., Pino, M., Sagredo, B. and Pinto, M. (2014). Physiological and morphological responses of Prunus species with different degree of tolerance to long-term root hypoxia. Scientia Horticulturae. 180(1): 14-23.
Sagheb Talebi, K., Sajedi, T. and Pourhashemi, M. (2014). Forests of Iran. Springer Netherlands, Dordrecht: Netherlands, 152 P.
Schaffer, B. and Ploetz, R.C. (1989). Gas exchange characteristics as indicators of damage thresholds for phytophthora root rot in flooded and nonflooded avocado trees. Horticulture Science. 14(4): 653-655.
Schaffer, B., Davies, F.S. and Crane, J.H. (2006). Responses of subtropical and tropical fruit trees to flooding in calcareous soil. Horticulture Science. 41(3): 549-555.
Striker, G.G. (2008). Visiting the methodological aspects of flooding experiments: quantitative evidence from agricultural and ecophysiological studies. Journal of Agronomy and Crop Science. 194(4): 249-255.
Striker, G.G. (2012). Time is on our side: the importance of considering a recovery period when assessing flooding tolerance in plants. Ecological Research. 27(5): 983-987.
Striker, G.G., Insausti, P. and Grimoldi, A.A. (2008). Flooding effects on plants recovering from defoliation in Paspalum dilatatum and Lotus tenuis. Annals of Botany. 102(2): 247-254.
Striker, G.G., Insausti, P., Grimoldi, A.A., Ploschuk, E.L. and Vasellati, V. (2005). Physiological and anatomical basis of differential tolerance to soil flooding of Lotus corniculatus L. and Lotus glaber Mill. Plant and Soil. 276(1): 301-311.
Striker, G.G., Izaguirre, R., Manzur, M. and Grimoldi, A.A. (2012). Different strategies of Lotus japonicus L. and corniculatus tenuis L.to deal with complete submergence at seedling stage. Plant Biology. 14(1):50-55.
Xiaoling, L., Ning, L., Jin, Y., Fuzhou, Y., Faju, C., and Fangqing, C., (2011). Morphological and photosynthetic responses of riparian plant "Distylium chinense" seedlings to simulated autumn and winter flooding in three gorges reservoir region of the Yangtze River, China. Acta Ecologica Sinica, 31: 31-39.