Research progresses on the effects of light, temperature and water conditions on primary and secondary growth of trees

doi:10.13287/j.1001-9332.202409.008

Abstract

Abstract: Tree growth includes primary growth and secondary growth. The growth activity and dormancy cycle of trees can affect forest productivity and carbon sequestration capacity. Therefore, it is of great significance to examine the effects of environmental conditions (e.g., photoperiod, temperature and water) on tree growth for understanding the responses of trees to climate change and predicting forest productivity and carbon sequestration capacity under the background of global climate change. We reviewed the effects of photoperiod, temperature and water conditions on the primary and secondary growth of trees, and revealed the physiological mechanisms underlying their impacts on the synchronization or asynchronization between primary and secondary growth of trees. The shortcomings of the existing research were pointed out. For example, less attention had been paid to the enrionmental response and adaptation of root growth, as well as the physiological mechanism of the effect of light, temperature and water on tree growth. Research on the growth of underground roots should be strengthened in the future, and more attention should be paid to the physiological changes in the process of tree growth affected by environmental factors. Furthermore, the source and sink limitation theory and the process-based prediction model should be improved, aiming to provide a scientific basis for predicting forest productivity and carbon sequestration capacity and putting forward scientific policies of forest management.

Key words: temperature, water, photoperiod, primary growth, secondary growth, productivity, carbon sequestration capacity

ZHOU Minghui, ZHANG Ting, LI Rongping, YAN Qiaoling. Research progresses on the effects of light, temperature and water conditions on primary and secondary growth of trees[J]. Chinese Journal of Applied Ecology, 2024, 35(9): 2455-2462.

References

[1] White AC, Rogers A, Rees M, et al. How can we make plants grow faster? A source-sink perspective on growth rate. Journal of Experimental Botany, 2016, 67: 31-45
[2] 赵桂仿. 植物学. 北京: 科学出版社, 2022: 96-113
[3] da Silva AL, Carvalho Ellen CD, de Souza GC, et al. The dynamics of cambial activity related to photoperiod, temperature, and precipitation in two Cordia species of the Brazilian semiarid. Flora, 2023, 301: 152246
[4] Huang JG, Ma Q, Rossi S, et al. Photoperiod and temperature as dominant environmental drivers triggering secondary growth resumption in Northern Hemisphere conifers. Proceedings of the National Academy of Sciences of the United States of America, 2020, 117: 20645-20652
[5] Estiarte M, Peñuelas J. Alteration of the phenology of leaf senescence and fall in winter deciduous species by climate change: Effects on nutrient proficiency. Global Change Biology, 2015, 21: 1005-1017
[6] Körner C, Basler D. Phenology under global warming. Science, 2010, 327: 1461-1462
[7] Yu HY, Zhou GS, Lv XM, et al. Stomatal limitation is able to modulate leaf coloration onset of temperate deciduous tree. Forests, 2022, 13: 1099
[8] Hamilton JA, El Kayal W, Hart AT, et al. The joint influence of photoperiod and temperature during growth cessation and development of dormancy in white spruce (Picea glauca). Tree Physiology, 2016, 36: 1432-1448
[9] Colombo SJ, Man RZ. Daylength effects on black spruce bud dormancy release change during endo- and ecodormancy. Frontiers in Forests and Global Change, 2023, 6: 1261112
[10] 胡明新, 周广胜, 吕晓敏, 等. 温度和光周期协同作用对蒙古栎幼苗春季物候的影响. 生态学报, 2021, 41(7): 2816-2825
[11] Fu YS, Campioli M, Deckmyn G, et al. Sensitivity of leaf unfolding to experimental warming in three temperate tree species. Agricultural and Forest Meteorology, 2013, 181: 125-132
[12] Montgomery RA, Rice KE, Stefanskia A, et al. Phenological responses of temperate and boreal trees to warming depend on ambient spring temperatures, leaf habit, and geographic range. Proceedings of the National Academy of Sciences of the United States of America, 2020, 117: 10397-10405
[13] Morin X, Roy J, Sonié L, et al. Changes in leaf phenology of three European oak species in response to experimental climate change. New Phytologist, 2010, 186: 900-910
[14] 林少植, 葛全胜, 王焕炯. 欧洲典型树种展叶始期的时空变化及其气候变化的响应. 应用生态学报, 2021, 32(3): 788-789
[15] Zhang YP, Jiang Y, Wen Y, et al. Comparing primary and secondary growth of co-occurring deciduous and evergreen conifers in an alpine habitat. Forests, 2019, 10: 574
[16] Bessonova VP, Chonhova AS. Influence of soil moisture level on metabolism of non-structural carbohydrates in Quercus robur leaves. Regulatory Mechanisms in Biosystems, 2021, 12: 628-634
[17] Zawaski C, Busov VB. Roles of gibberellin catabolism and signaling in growth and physiological response to drought and short-day photoperiods in Populus trees. PLoS ONE, 2014, 9: e86217
[18] Fu YS, Piao SL, Zhou XC, et al. Short photoperiod reduces the temperature sensitivity of leaf-out in saplings of Fagus sylvatica but not in horse chestnut. Global Change Biology, 2019, 25: 1696-1703
[19] 马成祥, 周广胜, 宋兴阳, 等. 增温、光照时间和氮添加对蒙古栎主要物候期的影响. 应用生态学报, 2022, 33(12): 3220-3228
[20] Seyednasrollah B, Young AM, Li XL, et al. Sensitivity of deciduous forest phenology to environmental drivers: Implications for climate change impacts across North America. Geophysical Research Letters, 2020, 47: e2019GL086788
[21] Fløistad IS, Eldhuset TD. Effect of photoperiod and fertilization on shoot and fine root growth in Picea abies seedlings. Silva Fennica, 2017, 51: 1704
[22] Zawaski C, Ma C, Strauss SH, et al. Photoperiod response 1 (PHOR1)-like genes regulate shoot/root growth, starch accumulation, and wood formation in Populus. Journal of Experimental Botany, 2012, 63: 5623-5634
[23] Lahti M, Aphalo PJ, Finér L, et al. Effects of soil temperature on shoot and root growth and nutrient uptake of 5-year-old Norway spruce seedlings. Tree Physiology, 2005, 25: 115-122
[24] Jiang Q, Jia LQ, Wang XH, et al. Soil warming alters fine root lifespan, phenology, and architecture in a Cunninghamia lanceolata plantation. Agricultural and Forest Meteorology, 2022, 327: 109201
[25] Heinzle J, Liu XF, Tian Y, et al. Increase in fine root biomass enhances root exudation by long-term soil warming in a temperate forest. Frontiers in Forests and Global Change, 2023, 6: 1152142
[26] Montagnoli A, Di Iorio A, Terzaghi M, et al. Influence of soil temperature and water content on fine-root seasonal growth of European beech natural forest in Southern Alps, Italy. European Journal of Forest Research, 2014, 133: 957-968
[27] Mohamed A, Monnier Y, Mao Z, et al. Asynchrony in shoot and root phenological relationships in hybrid walnut. New Forests, 2020, 51: 41-60
[28] Saderi S, Rathgeber CBK, Rozenberg P, et al. Phenology of wood formation in larch (Larix decidua Mill.) trees growing along a 1000-m elevation gradient in the French Southern Alps. Annals of Forest Science, 2019, 76: 89
[29] Takahashi K, Hirai T. Seasonal change in xylem growth of Pinus densiflora in central Japan. Landscape and Ecological Engineering, 2016, 12: 231-237
[30] Delpierre N, Lireux S, Hartig F, et al. Chilling and forcing temperatures interact to predict the onset of wood formation in Northern Hemisphere conifers. Global Change Biology, 2019, 25: 1089-1105
[31] Zhang XL, Manzanedo RD, Lv PC, et al. Reduced diurnal temperature range mitigates drought impacts on larch tree growth in North China. Science of the Total Environment, 2022, 848: 157808
[32] Cabon A, Peters RL, Fonti P, et al. Temperature and water potential co-limit stem cambial activity along a steep elevational gradient. New Phytologist, 2020, 226: 1325-1340
[33] Liu YC, Xie YH, Sun XM, et al. Effects of the most appropriate proportion of phytohormones on tree-ring growth in clones of hybrid larch. Sustainability, 2023, 15: 6508
[34] Alvarez-Uria P, Körner C. Low temperature limits of root growth in deciduous and evergreen temperate tree species. Functional Ecology, 2007, 21: 211-218
[35] Luo HX, Xu H, Chu CJ, et al. High temperature can change root system architecture and intensify root interactions of plant seedlings. Frontiers in Plant Science, 2020, 11: 160
[36] Babst F, Bouriaud O, Poulter B, et al. Twentieth century redistribution in climatic drivers of global tree growth. Science Advances, 2019, 5: eaat4313
[37] Bhusal N, Lee M, Han AR, et al. Responses to drought stress in Prunus sargentii and Larix kaempferi seedlings using morphological and physiological parameters. Forest Ecology and Management, 2020, 465: 118099
[38] Kim H, Jo H, Kim GJ, et al. Effects of spring warming and drought events on the autumn growth of Larix kaempferi seedlings. Water, 2022, 14: 1962
[39] Delpierre N, Berveiller D, Granda E, et al. Wood phenology, not carbon input, controls the interannual variability of wood growth in a temperate oak forest. New Phytologist, 2015, 210: 459-470
[40] Peters RL, Steppe K, Cuny HE, et al. Turgor: A limiting factor for radial growth in mature conifers along an elevational gradient. New Phytologist, 2020, 229: 213-229
[41] Zhang PP, Ding JX, Wang QT, et al. Contrasting coordination of non-structural carbohydrates with leaf and root economic strategies of alpine coniferous forests. New Phytologist, 2024, 243: 580-590
[42] Tomasella M, Häberle KH, Nardini A, et al. Post-drought hydraulic recovery is accompanied by non-structural carbohydrate depletion in the stem wood of Norway spruce saplings. Scientific Reports, 2017, 7: 14308
[43] 王恒, 王小雪, 贾建恒, 等. 华北落叶松径向生长对升温突变的响应. 应用生态学报, 2023, 34(10): 2629-2636
[44] Lempereur M, Martin-StPaul NK, Damesin C, et al. Growth duration is a better predictor of stem increment than carbon supply in a Mediterranean oak forest: Implications for assessing forest productivity under climate change. New Phytologist, 2015, 207: 579-590
[45] Buttò V, Rozenberg P, Deslauriers A, et al. Environmental and developmental factors driving xylem anatomy and micro-density in black spruce. New Phytologist, 2021, 230: 957-971
[46] del Río M, Vergarechea M, Hilmers T, et al. Effects of elevation-dependent climate warming on intra- and inter-specific growth synchrony in mixed mountain forests. Forest Ecology and Management, 2021, 479: 118587
[47] Perrin M, Rossi S, Isabel N. Synchronisms between bud and cambium phenology in black spruce: Early-flushing provenances exhibit early xylem formation. Tree Physiology, 2017, 37: 593-603
[48] Gricar J, Vedenik A, Skoberne G, et al. Timeline of leaf and cambial phenology in relation to development of initial conduits in xylem and phloem in three coexisting sub-Mediterranean deciduous tree species. Forests, 2020, 11: 1104
[49] Rossi S, Rathgeber CBK, Deslauriers A. Comparing needle and shoot phenology with xylem development on three conifer species in Italy. Annals of Forest Science, 2009, 66: 206
[50] Antonucci S, Rossi S, Deslauriers A, et al. Synchronisms and correlations of spring phenology between apical and lateral meristems in two boreal conifers. Tree Physiology, 2015, 35: 1086-1094
[51] Sanz-Pérez V, Castro-Díez P, Valladares F. Differential and interactive effects of temperature and photoperiod on budburst and carbon reserves in two co-occurring Mediterranean oaks. Plant Biology, 2009, 11: 142-151
[52] Barbaroux C, Bréda N. Contrasting distribution and seasonal dynamics of carbohydrate reserves in stem wood of adult ring-porous sessile oak and diffuse-porous beech trees. Tree Physiology, 2002, 22: 1201-1210
[53] Muller B, Pantin F, Génard M, et al. Water deficits uncouple growth from photosynthesis, increase C content, and modify the relationships between C and growth in sink organs. Journal of Experimental Botany, 2011, 62: 1715-1729
[54] Stinziano JR, Way DA. Autumn photosynthetic decline and growth cessation in seedlings of white spruce are decoupled under warming and photoperiod manipulations. Plant, Cell and Environment, 2017, 40: 1296-1316
[55] King JS, Thomas RB, Strain BR. Growth and carbon accumulation in root systems of Pinus taeda and Pinus ponderosa seedlings as affected by varying CO₂, temperature and nitrogen. Tree Physiology, 1996, 16: 635-642