Pinus densiflora is the most widely distributed tree species in South Korea. Its ecological and socio-cultural attributes makes it one of the most important tree species in S. Korea. In recent times however, the distribution of P. densiflora has been affected by dieback. This phenomenon has largely been attributed to climate change. This study was conducted to investigate the responses of growth and physiology of P. densiflora to drought and nitrogen fertilization according to the RCP 8.5 scenario. A Temperature Gradient Chamber (TGC) and CO2⋅Temperature Gradient Chamber (CTGC) were used to simulate climate change conditions. The treatments were established with temperature (control versus +3 and +5℃; aCeT) and CO2 (control: aCaT versus x1.6 and x2.2; eCeT), watering(control versus drought), fertilization(control versus fertilized). Net photosynthesis (Pn), stomatal conductance (gs), biomass and relative soil volumetric water content (VWC) were measured to examine physiological responses and growth. Relative soil VWC in aCeT significantly decreased after the onset of drought. Pn and gs in both aCeT and eCeT with fertilization were high before drought but decreased rapidly after 7 days under drought because nitrogen fertilization effect did not last long. The fastest mortality was 46 days in aCeT and the longest survival was 56 days in eCeT after the onset of drought. Total and partial biomass (leaf, stem and root) in both aCeT and e CeT with fertilization were significantly high, but significantly low in aCeT. The results of the study are helpful in addressing P. densiflora vulnerability to climate change by highlighting physiological responses related to carbon allocation under differing simulated environmental stressors.

본 연구는 최근 기후변화로 인해 피해가 증가하고 있는 소나무를 대상으로 고온 및 고농도 CO2 환경에 인위적으로 건조 스트레스를 주어 질소 시비에 따른 생리적 반응과 생물량 변화 특성을 구명하고자 수행되었다. 토양수분은 고온처리에서 가장 빨리 감소하여 수목의 건조 스트레스를 제공하는 것으로 나타났다. 결과적으로 토양수분이 가장 빨리 감소한 고온처리에서 순광합성율과 기공전도도 모두 감소하였다. 생리적반응의 경우, 무관수 초기에는 질소가 시비되는 모든 처리구에서 대조구 보다 높은 경향을 보였으나 건조 스트레스 기간이 길어짐에 따라 질소 시비 효과는 나타나지 않았다. 고사율은 고온처리에서 빠르게 진행되었으며 고농도 CO2 농도 환경에서는 평균적으로 21.5% 오래 생존하였다. 생물량의 경우 질소 시비와 CO2 시비효과가 뿌리에서 무관수로 인한 건조 스트레스가 주는 억제 효과를 완화시켜 부위별⋅총 생물량 증가에 영향을 준 것으로 판단된다. 본 연구결과를 통해 기후변화가 산림생태계에 끼칠 수 있는 영향을 정량적으로 구명함으로서 기후변화에 대응하여 산림을 효율적으로 관리하는데 필수적인 자료를 활용하고, 향후 미기상 조건에 다른 산림생태 예측모델 활용에 중요한 역할을 할 것으로 기대된다.

1 한승현, "인위적 온난화 및 강수 조절에 따른 소나무 묘목 세근 생산량과 고사율의 계절적 변화" 한국산림과학회 107 (107): 43-49, 2018

2 장한나, "실외 실험적 온난화 및 강수 조절 하에서 토양 수분과 소나무 묘목의 생리 및 생장 반응 간의 관계" 한국기후변화학회 10 (10): 145-152, 2019

3 Goldstein, G., "Why do trees adjust water relations and hydraulic architecture in response to nutrient availability?" 33 (33): 238-240, 2013

4 Tardieu, F., "Variability among species of stomatal control under fluctuating soil water status and evaporative demand : modelling isohydric and anisohydric behaviours" 419-432, 1998

5 King, J. S., "Tropospheric O3 compromises net primary production in young stands of trembling aspen, paper birch and sugar maple in response to elevated atmospheric CO2" (168) : 623-636, 2005

6 Matyssek, R., "Trees in a Changing Environment" 117-163, 2014

7 Kumarathunge, D. P, "The temperature optima for tree seedling photosynthesis and growth depend on water inputs" 2019

8 Gessler, A., "The role of nutrients in drought‐induced tree mortality and recovery" 214 (214): 513-520, 2017

9 Ainsworth, E. A., "The response of photosynthesis and stomatal conductance to rising [CO2] : mechanisms and environmental interactions" 30 (30): 258-270, 2007

10 Song, J., "The influence of nitrogen availability on anatomical and physiological responses of Populus alba× P. glandulosa to drought stress" 19 (19): 63-, 2019

11 Adams, H. D., "Temperature sensitivity of drought-induced tree mortality portends increased regional die-off under global-change-type drought" 106 (106): 7063-7066, 2009

12 Farquhar, G. D., "Stomatal conductance and photosynthesis" 33 (33): 317-345, 1982

13 Oren, R., "Soil fertility limits carbon sequestration by forest ecosystems in a CO2-enriched atmosphere" 411 (411): 469-, 2001

14 Comas, L., "Root traits contributing to plant productivity under drought" 4 : 442-, 2013

15 Huang, J. -G., "Response of forest trees to increased atmospheric CO2" 26 (26): 265-283, 2007

16 Woodward, F. I., "Potential impacts of global elevated CO2 concentrations on plants" 5 (5): 207-211, 2002

17 Leuzinger, S., "Poor methodology for predicting large-scale tree die-off" 106 (106): E106-E106, 2009

18 Taiz, L., "Plant Physiology" Sinauer Associates Inc 2006

19 Collatz, G. J., "Physiological and environmental regulation of stomatal conductance, photosynthesis and transpiration : a model that includes a laminar boundary layer" 54 (54): 107-136, 1991

20 Girardin, M. P., "No growth stimulation of Canada’s boreal forest under half-century of combined warming and CO2fertilization" 113 (113): E8406-E8414, 2016

21 Luo, J., "Nitrogen metabolism of two contrasting poplar species during acclimation to limiting nitrogen availability" 64 (64): 4207-4224, 2013

22 Tran, T. T., "Nitrogen application enhanced the expression of developmental plasticity of root systems triggered by mild drought stress in rice" 378 (378): 139-152, 2014

23 Zheng, H., "Morphological and physiological responses to cyclic drought in two contrasting genotypes of Catalpa bungei" 138 : 77-87, 2017

24 Nunes-Nesi, A., "Metabolic and signaling aspects underpinning the regulation of plant carbon nitrogen interactions" 3 (3): 973-996, 2010

25 McDowell, N., "Mechanisms of plant survival and mortality during drought:Why do some plants survive while others succumb to drought?" 178 (178): 719-739, 2008

26 Hopkins, W., "Introduction to Plant Physiology" The University of Western Ontario 2008

27 Hopkins, W. G., "Introduction to Plant Physiology" John Wiley and Sons 1999

28 Will, R. E., "Increased vapor pressure deficit due to higher temperature leads to greater transpiration and faster mortality during drought for tree seedlings common to the forest–grassland ecotone" 200 (200): 366-374, 2013

29 El Kohen, A., "Growth and Photosynthesis of two deciduous forest species at elevated carbon dioxide" 7 (7): 480-488, 1993

30 IPCC, "Global warming of 1.5℃ An IPCC Special Report on the impacts of global warming of 1.5℃ above pre-industrial levels and related global greenhouse gas emission pathways, in the context of strengthening the global response to the threat of climate change, sustainable development, and efforts to eradicate poverty" Cambridge University Press 2018

31 Lim, J. -H., "Forest vegetation shift and plant phenological changes according to global warming" 120 : 8-17, 2005

32 Korea Forest Service, "Forest Resources Creation and Management Act"

33 Warren, J. M., "Elevated CO2 enhances leaf senescence during extreme drought in a temperate forest" 31 (31): 117-130, 2011

34 Stirling, C., "Effects of elevated CO2 and temperature on growth and allometry of five native fast-growing annual species" 140 (140): 343-354, 1998

35 Yang, Y., "Effects of drought and nitrogen addition on photosynthetic characteristics and resource allocation of Abies fabri seedlings in eastern Tibetan Plateau" 43 (43): 505-518, 2012

36 Reich, P. B., "Effects of climate warming on photosynthesis in boreal tree species depend on soil moisture" 562 (562): 263-267, 2018

37 Kim, P. G., "Ecophysiology of Photosynthesis 1 : Effects of Light Intensity and Intercellular CO2 Pressure on Photosynthesis" 3 (3): 126-133, 2001

38 Brodribb, T., "Dynamics of Changing Intercellular CO2 Concentration(ci)during Drought and Determination of Minimum Functional ci" 111 : 179-185, 1996

39 Duan, H., "Drought responses of two gymnosperm species with contrasting stomatal regulation strategies under elevated [CO2] and temperature" 35 (35): 756-770, 2015

40 Mitchell, P. J., "Drought response strategies define the relative contributions of hydraulic dysfunction and carbohydrate depletion during tree mortality" 197 (197): 862-872, 2013

41 Zhang, H., "Divergent responses to water and nitrogen addition of three perennial bunchgrass species from variously degraded typical steppe in Inner Mongolia" 647 : 1344-1350, 2019

42 Anderegg, W. R., "Consequences of widespread tree mortality triggered by drought and temperature stress" 3 (3): 30-36, 2013

43 IPCC, "Climate change 2013: The physical science basis" Cambridge University Press 25-, 2013

44 Solomon, S., "Climate change 2007-the physical science basis: Working group I contribution to the fourth assessment report of the IPCC" Cambridge University Press 2007

45 NOAA, "Climate at a Glance: Global Mapping" National Centers for Environmental information

46 Tarvainen, L., "Can adjustments in foliar nitrogen-use efficiency reduce drought stress impacts on boreal trees?" 37 (37): 415-417, 2017

47 Prior, L. D., "Big eucalypts grow more slowly in a warm climate : Evidence of an interaction between tree size and temperature" 20 : 2793-2799, 2014

48 Korea Meteorological Administration, "Annual Climatological Report" Korea Meteorological Administration 2019

49 Cao, X., "Anatomical, physiological and transcriptional responses of two contrasting poplar genotypes to drought and re‐watering" 151 (151): 480-494, 2014

50 Allen, C. D., "A global overview of drought and heat-induced tree mortality reveals emerging climate change risks for forests" 259 (259): 660-684, 2010

51 임종환, "2017년 우박에 의한 산림피해의 기상, 수종 및 지형 특성 분석" 한국농림기상학회 19 (19): 280-292, 2017