Research progress on cambial activity of trees and the influencing factors

doi:10.13287/j.1001-9332.202110.022

Abstract

Abstract: Tree growth is the main way of carbon sequestration in forest ecosystems, which is influenced by climatic and non-climatic factors. The long-term location monitoring of cambial phenology and wood formation dynamics (xylogenesis) is an important method to clarify the responses of radial growth to climate change. Here, we reviewed studies on cambial phenology and xylogenesis by microcoring method. Firstly, we reviewed the effects of climatic factors on cambial phenology. The onset and cessation of xylogenesis were determined by temperature in cold and humid conditions. Temperature and water availability collectively modulated the onset of xylogenesis under dry conditions, and the later determined the end of xylogenesis. The radial increment was regulated by rate and duration of cell production, with the maximum of growth rate occurring around the summer solstice. Short-term N addition did not affect wood formation dynamics. Secondly, we reviewed the roles of biological factors in regulating xylogenesis. The onset of xylogenesis differred among species, ages, and inter-specific competition. Seasonal dynamics of non-structural carbohydrates were coupled with wood formation. Finally, we reviewed the response mechanisms of xylogenesis to the interaction of climatic and biological factors. In conclusion, we put forward problems in current studies and prospected future development to provide reference for further scientific research.

Key words: microcoring, cambium, radial growth, climatic factor, biological factor

WANG Ling-ling, GOU Xiao-hua, XIA Jing-qing, WANG Fang, ZHANG Fen, ZHANG Jun-zhou. Research progress on cambial activity of trees and the influencing factors[J]. Chinese Journal of Applied Ecology, 2021, 32(10): 3761-3770.

References

[1] Cook-Patton SC, Leavitt SM, Gibbs D, et al. Mapping carbon accumulation potential from global natural forest regrowth. Nature, 2020, 585: 545-550
[2] Fu YH, Zhao H, Piao S, et al. Declining global warming effects on the phenology of spring leaf unfolding. Nature, 2015, 526: 104-107
[3] Prislan P, čufar K, Koch G, et al. Review of cellular and subcellular changes in the cambium. IAWA Journal, 2013, 34: 391-407
[4] Abreu IN, Johansson AI, Sokolowska K, et al. A metabolite roadmap of the wood-forming tissue in Populus tremula. New Phytologist, 2020, 228: 1559-1572
[5] Cuny HE, Fonti P, Rathgeber CBK, et al. Couplings in cell differentiation kinetics mitigate air temperature influence on conifer wood anatomy. Plant, Cell & Environment, 2018, 42: 1222-1232
[6] Drew DM, Downes GM. The use of precision dendrometers in research on daily stem size and wood property variation: A review. Dendrochronologia, 2009, 27: 159-172
[7] Wolter KE. A new method for marking xylem growth. Forest Science, 1968, 14: 102-104
[8] Rossi S, Menardi R, Anfodillo T. Trephor: A new tool for sampling microcores from tree stems. IAWA Journal, 2006, 27: 89-97
[9] Rossi S, Anfodillo T, čufar K, et al. Pattern of xylem phenology in conifers of cold ecosystems at the Northern Hemisphere. Global Change Biology, 2016, 22: 3804-3813
[10] Gričar 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, doi: 10.3390/f11101104
[11] 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
[12] Rossi S, Deslauriers A, Anfodillo T, et al. Evidence of threshold temperatures for xylogenesis in conifers at high altitudes. Oecologia, 2007, 152: 1-12
[13] Rossi S, Deslauriers A, Griçar J, et al. Critical tempe-ratures for xylogenesis in conifers of cold climates. Global Ecology and Biogeography, 2008, 17: 696-707
[14] Ziaco E, Biondi F, Rossi S, et al. Environmental dri-vers of cambial phenology in Great Basin bristlecone pine. Tree Physiology, 2016, 36: 818-831
[15] Saderi S, Rathgeber CBK, Rozenberg P, et al. Pheno-logy 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: doi: 10.1007/s13595-019-0866-3
[16] 李明明, 李刚. 贺兰山地区植被冠层物候与树干形成层物候的关系. 应用生态学报, 2021, 32(2): 495-502 [Li M-M, Li G. Relationship between phenology of vegetation canopy and phenology of tree cambium in Helan Mountains, China. Chinese Journal of Applied Ecology, 2021, 32(2): 495-502]
[17] Li XX, Liang EY, Gricar J, et al. Age dependence of xylogenesis and its climatic sensitivity in Smith fir on the south-eastern Tibetan Plateau. Tree Physiology, 2013, 33: 48-56
[18] Guada G, Vázquez-Ruiz RA, García-González I. Response patterns of xylem and leaf phenology to temperature at the southwestern distribution boundary of Quercus robur: A multi-spatial study. Agricultural and Forest Meteorology, 2019, 269-270: 46-56
[19] Sanmiguel-Vallelado A, Camarero JJ, Morán-Tejeda E, et al. Snow dynamics influence tree growth by controlling soil temperature in mountain pine forests. Agricultural and Forest Meteorology, 2021, 296: 108205, doi: 10.1016/j.agrformet.2020.108205
[20] Miller TW, Stangler DF, Larysch E, et al. Plasticity of seasonal xylem and phloem production of Norway spruce along an elevational gradient. Trees, 2020, 34: 1281-1297
[21] Malik R, Rossi S, Sukumar R. Variations in the timing of different phenological stages of cambial activity in Abies pindrow (Royle) along an elevation gradient in the north-western Himalaya. Dendrochronologia, 2020, 59: 125660, doi: 10.1016/j.dendro.2019.125660
[22] Cocozza C, Palombo C, Tognetti R, et al. Monitoring intra-annual dynamics of wood formation with microcores and dendrometers in Picea abies at two different altitudes. Tree Physiology, 2016, 36: 832-846
[23] Zhang JZ, Gou XH, Pederson N, et al. Cambial pheno-logy in Juniperus przewalskii along different altitudinal gradients in a cold and arid region. Tree Physiology, 2018, 38: 840-852
[24] Moser L, Fonti P, Buntgen U, et al. Timing and duration of European larch growing season along altitudinal gradients in the Swiss Alps. Tree Physiology, 2010, 30: 225-233
[25] Deslauriers A, Rossi S, Anfodillo T, et al. Cambial phenology, wood formation and temperature thresholds in two contrasting years at high altitude in southern Italy. Tree Physiology, 2008, 28: 863-871
[26] Zhang JZ, Gou XH, Alexander MR, et al. Drought limits wood production of Juniperus przewalskii even as growing seasons lengthens in a cold and arid environment. Catena, 2021, 196: 104936, doi: 10.1016/j.catena.2020.104936
[27] Li XX, Rossi S, Liang EY, et al. Temperature thre-sholds for the onset of xylogenesis in alpine shrubs on the Tibetan Plateau. Trees, 2016, 30: 2091-2099
[28] Antonucci S, Rossi S, Lombardi F, et al. Influence of climatic factors on silver fir xylogenesis along the Italian Peninsula. IAWA Journal, 2019, 40: 253-259
[29] Vieira J, Carvalho A, Campelo F. Xylogenesis in the early life stages of maritime pine. Forest Ecology and Management, 2018, 424: 71-77
[30] Ziaco E, Truettner C, Biondi F, et al. Moisture-driven xylogenesis in Pinus ponderosa from a Mojave Desert mountain reveals high phenological plasticity. Plant, Cell & Environment, 2018, 41: 823-836
[31] Pumijumnong N, Danpradit S, Tadang N, et al. Cam-bial activity and radial growth dynamics of three tropical tree species at Chang Island, Thailand. Journal of Tropical Forest Science, 2019, 31: 404-414
[32] Abe H, Nakai T, Utsumi Y, et al. Temporal water deficit and wood formation in Cryptomeria japonica. Tree Physiology, 2003, 23: 859-863
[33] Zhang JZ, Gou XH, Manzanedo RD, et al. Cambial phenology and xylogenesis of Juniperus przewalskii over a climatic gradient is influenced by both temperature and drought. Agricultural and Forest Meteorology, 2018, 260-261: 165-175
[34] Zeng Q, Rossi S, Yang B, et al. Environmental drivers for cambial reactivation of Qilian Junipers (Juniperus przewalskii) in a semi-arid region of northwestern China. Atmosphere, 2020, 11: 232, doi: 10.3390/atmos-11030232
[35] Ren P, Rossi S, Camarero JJ, et al. Critical temperature and precipitation thresholds for the onset of xyloge-nesis of Juniperus przewalskii in a semi-arid area of the north-eastern Tibetan Plateau. Annals of Botany, 2018, 121: 617-624
[36] Huang JG, Ma QQ, 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
[37] Guada G, Vázquez-Ruiz RA, García-González I. Meteo-rological conditions control the cessation rather than the beginning of wood formation in a sub-Mediterranean ring-porous oak. Agricultural and Forest Meteorology, 2020, 281: 107833. 10.1016/j.agrformet.2019.107833
[38] Fernández-De-Uña L, Aranda I, Rossi S, et al. Divergent phenological and leaf gas exchange strategies of two competing tree species drive contrasting responses to drought at their altitudinal boundary. Tree Physiology, 2018, 38: 1152-1165
[39] Rossi S, Girard M, Morin H. Lengthening of the duration of xylogenesis engenders disproportionate increases in xylem production. Global Change Biology, 2014, 20: 2261-2271
[40] Rossi S, Morin H, Deslauriers A, et al. Predicting xylem phenology in black spruce under climate warming. Global Change Biology, 2011, 17: 614-625
[41] Nanayakkara B, Dickson AR, Meason DF. Xylogenesis of Pinus radiata D. Don growing in New Zealand. Annals of Forest Science, 2019, 76: 74, doi: 10.1007/s13595-019-0859-2
[42] He MH, Yang B, Wang ZY, et al. Climatic forcing of xylem formation in Qilian juniper on the northeastern Tibetan Plateau. Trees, 2016, 30: 923-933
[43] Vieira J, Carvalho A, Campelo F. Tree growth under climate change: Evidence from xylogenesis timings and kinetics. Frontiers in Plant Science, 2020, 11, doi: 10.3389/fpls.2020.00090
[44] Zhang YP, Xu JL, Su W, et al. Spring precipitation effects on formation of first row of earlywood vessels in Quercus variabilis at Qinling Mountain (China). Trees, 2019, 33: 457-468
[45] Mäkinen H, Jyske T, Nöjd P. Dynamics of diameter and height increment of Norway spruce and Scots pine in southern Finland. Annals of Forest Science, 2018, 75, doi: 10.1007/s13595-018-0710-1
[46] Zhang YP, Jiang Y, Wang B, et al. Seasonal water use by Larix principis-rupprechtii in an alpine habitat. Forest Ecology and Management, 2018, 409: 47-55
[47] Battipaglia G, Campelo F, Vieira J, et al. Structure and function of intra-annual density fluctuations: Mind the gaps. Frontiers in Plant Science, 2016, 7, 10.3389/fpls.2016.00595
[48] Fajstavr M, Bednárˇová E, Nezval O, et al. How needle phenology indicates the changes of xylem cell formation during drought stress in Pinus sylvestris L. Dendrochronologia, 2019, 56: 125600, doi: 10.1016/j.dendro.2019.05.004
[49] Balzano A, čufar K, Battipaglia G, et al. Xylogenesis reveals the genesis and ecological signal of IADFs in Pinus pinea L. and Arbutus unedo L. Annals of Botany, 2018, 121: 1231-1242
[50] Pacheco A, Camarero JJ, Carrer M. Linking wood ana-tomy and xylogenesis allows pinpointing of climate and drought influences on growth of coexisting conifers in continental Mediterranean climate. Tree Physiology, 2016, 36: 502-512
[51] Vieira J, Nabais C, Rossi S, et al. Rain exclusion affects cambial activity in adult maritime pines. Agricultural and Forest Meteorology, 2017, 237-238: 303-310
[52] De Micco V, Balzano A, čufar K, et al. Timing of false ring formation in Pinus halepensis and Arbutus unedo in Southern Italy: Outlook from an analysis of xylogenesis and tree-ring chronologies. Frontiers in Plant Science, 2016, 7, doi: 10.3389/fpls.2016.00705
[53] Jyske T, Mäkinen H, Kalliokoski T, et al. Intra-annual tracheid production of Norway spruce and Scots pine across a latitudinal gradient in Finland. Agricultural and Forest Meteorology, 2014, 194: 241-254
[54] Dufour B, Morin H. Tracheid production phenology of Picea mariana and its relationship with climatic fluctuations and bud development using multivariate analysis. Tree Physiology, 2010, 30: 853-865
[55] Rossi S, Morin H, Deslauriers A. Causes and correlations in cambium phenology: Towards an integrated framework of xylogenesis. Journal of Experimental Botany, 2012, 63: 2117-2126
[56] Cuny HE, Rathgeber CBK, Lebourgeois F, et al. Life strategies in intra-annual dynamics of wood formation: Example of three conifer species in a temperate forest in north-east France. Tree Physiology, 2012, 32: 612-625
[57] Ren P, Rossi S, Gricar J, et al. Is precipitation a trigger for the onset of xylogenesis in Juniperus przewalskii on the north-eastern Tibetan Plateau? Annals of Botany, 2015, 115: 629-639
[58] Perez-De-Lis G, Olano JM, Rozas V, et al. Environmental conditions and vascular cambium regulate carbon allocation to xylem growth in deciduous oaks. Functional Ecology, 2017, 31: 592-603
[59] Malik R, Rossi S, Sukumar R. Cambial phenology in Abies pindrow (Pinaceae) along an altitudinal gradient in northwestern Himalaya. IAWA Journal, 2020, 41: 186-201
[60] Ren P, Ziaco E, Rossi S, et al. Growth rate rather than growing season length determines wood biomass in dry environments. Agricultural and Forest Meteorology, 2019, 271: 46-53
[61] 王亚蕊, 刘泽彬, 王彦辉, 等. 六盘山半湿润区华北落叶松树干半径变化特征及其影响因素. 应用生态学报, 2020, 31(10): 3313-3321 [Wang Y-R, Liu Z-B, Wang Y-H, et al. Variation of stem radius of Larix principis-rupprechtii and its influencing factors in the semi-humid Liupan Mountains, China. Chinese Journal of Applied Ecology, 2020, 31(10): 3313-3321]
[62] Zhang SK, Rossi S, Huang JG, et al. Intra-annual dynamics of xylem formation in Liquidambar formosana subjected to canopy and understory N addition. Frontiers in Plant Science, 2018, 9: 79, doi: 10.3389/fpls.2018.00079
[63] Zhang SK, Huang JG, Rossi S, et al. Intra-annual dyna-mics of xylem growth in Pinus massoniana submitted to an experimental nitrogen addition in Central China. Tree Physiology, 2017, 37: 1546-1553
[64] Yu BY, Huang JG, Ma QQ, et al. Comparison of the effects of canopy and understory nitrogen addition on xylem growth of two dominant species in a warm temperate forest, China. Dendrochronologia, 2019, 56: 125604, doi: 10.1016/j.dendro.2019.125604
[65] García-Cervigón AI, Camarero JJ, Espinosa CI. Intra-annual stem increment patterns and climatic responses in five tree species from an Ecuadorian tropical dry forest. Trees, 2017, 31: 1057-1067
[66] Simard S, Giovannelli A, Treydte K, et al. Intra-annual dynamics of non-structural carbohydrates in the cambium of mature conifer trees reflects radial growth demands. Tree Physiology, 2013, 33: 913-923
[67] 韩艳刚, 周旺明, 齐麟, 等. 长白山树木径向生长对气候因子的响应. 应用生态学报, 2019, 30(5): 1513-1520 [Han Y-G, Zhou W-M, Qi L, et al. Tree radial growth-climate relationship in Changbai Mountain, Northeast China. Chinese Journal of Applied Eco-logy, 2019, 30(5): 1513-1520]
[68] 蔡礼蓉, 匡旭, 房帅, 等. 长白山阔叶红松林3个常见树种径向生长的影响因素. 应用生态学报, 2017, 28(5): 1407-1413 [Cai L-R, Kuang X, Fang S, et al. Factors influencing tree radial growth of three common species in broad-leaved Korean pine mixed forests in Changbai Mountains, China. Chinese Journal of Applied Ecology, 2017, 28(5): 1407-1413]
[69] Chen L, Rossi S, Deslauriers A, et al. Contrasting stra-tegies of xylem formation between black spruce and balsam fir in Quebec, Canada. Tree Physiology, 2019, 39: 747-754
[70] 艾绍水, 李秧秧, 陈佳村, 等. 陕北沙地3种典型灌木根木质部解剖结构及水力特性. 应用生态学报, 2015, 26(11): 3277-3284 [Ai S-S, Li Y-Y, Chen J-C, et al. Root anatomical structure and hydraulic traits of three typical shrubs on the sandy lands of northern Shaanxi Province, China. Chinese Journal of Applied Ecology, 2015, 26(11): 3277-3284]
[71] 殷笑寒, 郝广友. 长白山阔叶树种木质部环孔和散孔结构特征的分化导致其水力学性状的显著差异. 应用生态学报, 2018, 29(2): 352-360 [Yin X-H, Hao G-Y. Divergence between ring- and diffuse-porous wood types in broadleaf trees of Changbai Mountains results in substantial differences in hydraulic traits. Chinese Journal of Applied Ecology, 2018, 29(2): 352-360]
[72] del Castillo EM, Prislan P, Gričar J, et al. Challenges for growth of beech and co-occurring conifers in a changing climate context. Dendrochronologia, 2018, 52: 1-10
[73] 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, doi: 10.3390/f10070574
[74] Zeng Q, Rossi S, Yang B. Effects of age and size on xylem phenology in two conifers of northwestern China. Frontiers in Plant Science, 2018, 8, doi: 10.3389/fpls.2017.02264
[75] Hacurova J, Hacura J, Gryc V, et al. Xylogenesis and phloemogenesis of Norway spruce in different ages stands at middle altitudinal zone. Wood Research, 2020, 65: 937-950
[76] Rossi S, Deslauriers A, Anfodillo T, et al. Age-depen-dent xylogenesis in timberline conifers. New Phytologist, 2008, 177: 199-208
[77] Vieira J, Campelo F, Rossi S, et al. Adjustment capa-city of Maritime pine cambial activity in drought-prone environments. PLoS One, 2015, 10(5): e126223
[78] Zhang J, Huang SM, He FL. Half-century evidence from western Canada shows forest dynamics are primarily driven by competition followed by climate. Proceedings of the National Academy of Sciences of the United States of America, 2015, 112: 4009-4014
[79] Liu SS, Li XX, Rossi S, et al. Differences in xylogenesis between dominant and suppressed trees. American Journal of Botany, 2018, 105: 950-956
[80] Tsai CC, Hung LF, Chung JD, et al. Radial growth of Cinnamomum kanehirae Hayata displays a larger tempe-rature sensitivity in dominant than codominant trees. Annals of Forest Science, 2018, 75, doi: 10.1007/s13595-018-0735-5
[81] Palacio S, Hoch G, Sala A, et al. Does carbon storage limit tree growth? New Phytologist, 2014, 201: 1096-1100
[82] Steppe K, Sterck F, Deslauriers A. Diel growth dyna-mics in tree stems: Linking anatomy and ecophysiology. Trends in Plant Science, 2015, 20: 335-343
[83] Klein T, Hoch G, Yakir D, et al. Drought stress, growth and nonstructural carbohydrate dynamics of pine trees in a semi-arid forest. Tree Physiology, 2014, 34: 981-992
[84] Michelot A, Simard S, Rathgeber C, et al. Comparing the intra-annual wood formation of three European species (Fagus sylvatica, Quercus petraea and Pinus sylvestris) as related to leaf phenology and non-structural carbohydrate dynamics. Tree Physiology, 2012, 32: 1033-1045
[85] Prislan P, čufar K, De Luis M, et al. Precipitation is not limiting for xylem formation dynamics and vessel development in European beech from two temperate forest sites. Tree Physiology, 2018, 38: 186-197
[86] Li XX, Rossi S, Liang EY. The onset of xylogenesis in Smith fir is not related to outer bark thickness. American Journal of Botany, 2019, 106, doi: 10.1002/ajb2.1360