Significance of senescence study on tree roots and its advances

Abstract

Abstract: Root system is one of the important components of trees,and has some important physiological functions such as nutrient and water absorption,transport and storage,anchoring,and supporting.After tree root systems formed,roots often suffer from nutrient- and water-deficient stress,and thus,their absorption of nutrients and water appears more important.Soil nutrient and water have a great spatiotemporal heterogeneity.As the heterogeneity occurs,trees regulate carbon partitioning to roots,resulting in the senescence or death of some roots of the whole root system.In forestry,the senescence of tree roots is closely related to tree productivity,because there is a close relationship between the senescence of tree roots and the absorption of soil nutrient and water.At ecosystem and global scale,the senescence of tree roots influences the cycling of carbon and nutrients,because roots exhaust a great deal of carbon fixed by source leaves through photosynthesis,and there are great amounts of nutrients in tree roots.The senescence of tree roots is influenced by many environmental factors,biotic (e.g.,fungi,bacteria,viruses,small edaphic animals) and abiotic (e.g.,water,temperature,soil nutrients,heavy metals).These factors affect the senescence of tree roots by different mechanisms.Although we have much knowledge on the senescence of tree roots and some hypotheses have been proposed,some problems still remain to be resolved,and further experiments are needed to test these hypotheses.Interdisciplinary studies integrating cytology,biochemistry,soil science,and genetics are the prerequisite for rapid advances in understanding the essence of tree root senescence.

Key words: Tree roots, Senescence, Environmental factors

CLC Number:

WU Chu, WANG Zhengquan, FAN Zhiqiang. Significance of senescence study on tree roots and its advances[J]. Chinese Journal of Applied Ecology, 2004, (7): 1276-1280.

References

[1] Aerts R, Bakker C, de Caluwe H. 1992. Root turnover as tederminant of the cycling of C, N and P in a dry heathland ecosystem. Biochemistry, 15:175～ 190
[2] Bakker MR, 1999. Fine-root parameters as indicators of sustainability of forest ecosystems. For Ecol Man, 122:7～16
[3] Bloomfield J, Vogt K, Wargo PM. 1996. Tree root turnover and senescence. In:Waisel Y, Eshel A, Kafkaf U, eds. Plant Roots: the Hidden Half. 2nd ed. New York: Naarcel Dekker. 363～ 381
[4] Brown DA, Scott HD. 1984. Dependence of crop growth and yield on root development and activity. In: Nutrient and Water Influx,and Plant Growth, Publication No. 49. American Society of Agronomy, Madison, WI, 101 ～ 136
[5] Caldwell MM, Dawson TE, Richards JH. 1998. Hydraulic lift: consequences of water efflux from the roots of plants. Oecologia, 113:151～161
[6] Ceulemans R, Janssens IA, Jach ME. 1999. Effects of CO₂ enrichment on trees and forests: Lessons to be learned in view of future ecosystem studies. Annals Bot, 84: 577～ 590
[7] Chapin Ⅲ FS, Matson PA, Mooney HA. 2002. Principles of Terrestrial Ecosystem Ecology. New York:Springer-Verlag.
[8] Chiou T-J, Bush DR, 1998. Sucrose is a signal molecule in assimilate partitioning. Proc Natl Acad Sci USA, 95: 4784 ～ 4788
[9] Comas LH, Eissenstat DM, Lakso AN. 2000. Assessing root death and root system dynamics in a study of grape canopy pining. New Phytol, 147:171 ～ 178
[10] Eissenstat DM, Wells CE, Yanai RD, Whitbeck JL. 2000. Building roots in a changing environment: implications for root longevity.New Phytol, 147: 33 ～ 42
[11] Eissenstat DM, Yanai RD. 1997. The ecology of root lifespan. Adv Eco Res, 27:1 ～60
[12] Farrar JF, Jones DL. 2000. The control of carbon acquisition by roots. New Phytol, 147:43～53
[13] Fisher MCT, Eissenstat DM, Lynch JP. 2002. Lack of evidence for programmed root senescence in common bean (Phaseolus vulgaris)grown at different levels of phosphorus supply. New Phytol, 153:63 ～ 71
[14] Fitter AH. 1982. Morphometric analysis of root systems: application of the technique and influence of soil fertility on root system development in two herbaceous species. Plant Cell Environ, 5:313 ～322
[15] Fitter AH. 1994. Architecture and biomass allocation as components of the plastic response of root systems to soil heterogeneity. In: Caldwell MM, Pearcy RW, eds. Exploitation of Environmental Heterogeneity by Plants: Ecophysiological Processes Above-and Belowground. San Diego. Academic Press. 305 ～323
[16] Fitter AH, Graves JD, Wolfenden J, et al. 1997. Root production and turnover and carbon budgets of two contrasting grasslands under ambient and elevated atmospheric carbon dioxide concentrations. New Phytol, 137:247～255
[17] Friend AL, Eide MR, Hinckley TM. 1990. Nitrogen stress alters root proliferation in Douglas-fir seedlings. Can J For Res, 20:1524～ 1529
[18] Haynes BE, Gower ST. 1995. Belowground carbon allocation in unfertilized and fertilized red pine plantations in northern Wisconsin.Tree Physiol, 15:317～325
[19] Hendrick RL, Pregitzer KS. 1993. Parterns of fine root mortality in two sugar maple forests. Nature, 361: 59～ 61
[20] Hendrick RL, Pregitzer KS. 1996. Temporal and depth-related patterns of fine-root dynamics in northern hardwood forests. J Ecol,84:167～ 176
[21] Hendricks JJ, Nadelhoffer KJ, Aber JD. 1993. Assessing the role of fine roots in carbon and nutrient cycling. Tends Ecol Evol, 8:174～178
[22] Hogberg P, Nordgren A, Buchmann N, et al. 2001. Large-scale forest girdling shows that current photosynthesis drives soil respiration. Nature, 411: 789～ 792
[23] Kasurinen A, Helmisaari H-L, Holopainen T. 1999. The influence of elevated CO₂ and O3 on fine roots and mycorrhizas of naturally growing young Scots pine trees during tree exposure years. Global Change Biol, 5: 771 ～ 780
[24] King JS, Albaugh TJ, Allen HL, et al. 2002. Below-ground carbon input to soil is controlled by nutrient availability and fine root dynamics in loblolly pine. New Phytol, 154: 389 ～ 398
[25] Kosola KR, Eissenstat DM, Graham JH. 1995. Root demography of mature citrus trees: the influence of Phytophtyhora nicotianae.Plant Soil, 171:283～288
[26] Krasny M. 1986. Establishment of four Salicacease species on river bars along the Tanana River, Alaska. Ph. D. dissertation, University of Washington, Seattle, WA.
[27] Kytoviita M-M, Thiec DL, Dizengremel P. 2001. Elevated CO₂ and ozone reduce nitrogen acquisition by Pinus halepensis from its mycorrhizal symbiont. Physiol Plant, 111: 305 ～ 312
[28] Lalongde S, Boles E, Hellmann H, et al. 1999. A dual function of sugar carriers: Transport and sugar sensing. Plant Cell, 11: 707 ～726
[29] Lambers H, Chapin Ⅲ FS, Pons T. 1998. Plant Physiological Ecology. Berlin: Springer-Verlag.
[30] Lascaris D, Deacon JW. 1991. Relationship between root cortical senescence and growth of wheat as influenced by mineral nutrition, Idriella bolleyi (Sprague) von Arx and pruning of leaves. New Phytol, 118:391～396
[31] Leuschner C, Backes K, Hertel D, et al. 2001. Drought responses at leaf, stem and fine root levels of competitive Fagus sylvatica L, and Quercus petraea ( Matt. ) Liebl. trees in dry and wet years. For Ecol Man, 149: 33～46
[32] Li L-H(李凌浩),Lin P(林鹏),Xing X-R(邢雪荣).1998.Fine root biomass and production of Castanopsis eyrei forests in Wuyi Mountains.Chin J Appl Ecol(应用生态学报),9(4):337～340(in Chinese)
[33] Li P-Z(李培芝),Fan S-H(范世华),Wang L-H(王力华),Xu SM(许思明).2001.Productivity andturnover of fine roots in poplar tree and grass roots.Chin J Appl Ecol(应用生态学报),12(6):829～832(in Chinese)
[34] Liao L-P(廖利平),Chen C-Y(陈楚莹),Zhang J-w(张家武),et al. 1995. Turnover of fine roots in pure and mixed Cunninghamia lanceolata and Michelia macclurei forests. Chin J Appl Ecol ( 应用生态学报), 6(1):7～ 10(in Chinese)
[35] Lijeroth E, Bryngelsson T. 2001. DNA fragmentation in cereal roots indicative of programmed root cortical cell death. Physiol Plant,111 :365～372
[36] Liljeroth E. 1995. Comparison of early root cortical senescence among barley cultivars. Triticum species and other cereals. New Phytol, 130:495～501
[37] Liljeroth E, Franzon-Almgren I, Gustafsson M. 1996. Root colonization by Bipolaris sorokiniana in different cereals and relations to lesion development and natural root cortical cell death. J Phytopathol, 144:301～307
[38] López B, Sabaté S, Gracis CA. 2001. Fine-root longevity of Quercus ilex. New Phytol, 151:437～441
[39] Majdi H. 2001. Changes in fine root production and longevity in relation to water and nutrient availability in a Norway spruce stand in northern Sweden. Tree Physiol, 21:1057～ 1061
[40] Marshall JD, Waring RH. 1985. Predicting fine root production turnover by monitoring root starch and soil temperature. Can J For Res, 15:791～ 800
[41] Martin PH, Nabuurs GJ, Aubinet M, et al. 2001. Carbon sinks in temperate forests. Annu Rev Energy Environ, 26:435 ～465
[42] Nadelhoffer KJ, Emmett BA, Gunderson P, et al. 1999. Nitrogen deposition makes a minor contribution to carbon sequestration in temperate forests. Nature, 398:145～ 148
[43] Nadelhoffer NJ. 2000. The potential effects of nitrogen deposition on fine-root production in forest ecosystem. New Phytol, 147:131～139
[44] Ostertag R. 2001. Effects of nitrogen and phosphorus availability on fine-root dynamics in Hawaiian montane forests. Ecology, 82:485～ 499
[45] Parry MAJ, Loveland JE, Andralojc PJ. 1999. Regulation of Rubisco. In:Bryant JA, Burrell MM, Kruger NJ eds. Plant Carbohydrate Biochemistry. Oxford: BIOS Scientific Publishers. 127 ～ 145
[46] Pregitzer KS, DeForest JL, Burton A, et al. 2002. Fine root architecture of nine American trees. Ecol Monogr, 72: 293 ～ 309
[47] Pregitzer KS, Hendrick RL, Fogel R. 1993. The demography of fine roots in response to patches of water and nitrogen. New Phytol,125: 575～ 580
[48] Pregitzer KS, King JS, Burton AJ, Brown SE. 2000. Responses of tree fine roots to temperature. New Phytol, 147:105 ～ 115
[49] Pregitzer KS, Kubiske ME, Yu CK, Hendrick RL. 1997. Relationships among root branch order, carbon, and nitrogen in four temperate species. Oecologia, 111:302～308
[50] Pregitzer KS, Laskowski MJ, Burton AJ, et al. 1998. Variation in sugar maple root respiration with root diameter and soil depth. Tree Physiol, 18:665～ 670
[51] Pregitzer KS, Zak DR, Curtis PS, et al. 1995. Atmospheric CO₂,soil nitrogen and turnover of fine roots. New Phytol, 129:579 ～585
[52] Raich JW, Nadelhoffer KJ. 1989. Belowground carbon allocation in forest ecosystems: global trends. Ecology, 70:1346 ～ 1354
[53] Raynal DJ, Joslin JD, Thornton FC, et al. 1990. Sensitivity of tree seedlings to aluminum Ⅲ. Red spruce and loblolly pine. J Environ Qual, 19:180～ 187
[54] Rook F, Grrits N, Kortstee A, et al. 1998.Sucrose-specific signaling represses translation of the Arabidopsis ATB2 Hzip TRANSCRIPTION FACTOR GENE. Plant J, 15: 253～ 263
[55] Ruess RW, van Cleve K, Yarie J, Uiereck LA. 1996. Contributions of fine root production and turnover to the carbon and nitrogen cycling in taiga forests of the Alaskan interior. Can J For Res, 26:1326～ 1336
[56] Santantonio D, Hermann RK. 1985. Standing crop, production, and turnover of fine roots on dry, moderate, and wet sites of mature Douglas-fir in western Oregon. Ann Sci For, 42:113 ～ 142
[57] Saxe H, Cannell MGR, Johnsen φ, et al. 2001. Tree and forest functioning in response to global warming. New Phytol, 149:369～400
[58] Schlesinger WH. 1997. Carbon balance in terrestrial detritus. Annu Rev Ecol System, 8: 51 ～ 81
[59] Shan J-P(单建平), Tao D-L(陶大立), Wang M(王淼), Zhao SD(赵世洞). 1993. Fine root turnover in a broad-leaved Korean pine forest of Changbai mountain. Chin J Appl Ecol (应用生态学报), 4(3) :241～245(in Chinese)
[60] Sitt M, Scheible W-R. 1999. Nitrate acts as a signal to control gene expression, metabolism and biomass allocation. In: Kruger NJ. eds.Regulation of Primary Metabolic Pathways in Plants. Netherlands Kluwer: Academic Publishers. 275 ～ 306
[61] Smeekens S, Rook F. 1997. Sugar sensing and sugar-mediated signal transduction in plants. Plant Physiol, 115: 7～ 13
[62] Stark JM. 1994. Causes of soil nutrient heterogeneity at different scales. In:Caldwell MM, Pearcy RW, eds. Exploitation of Environmental Heterogeneity by Plants: Ecophysiologi1cal Processes Aboveand Belowground. San Diego:Academic Press. 255 ～ 284
[63] Takei K, Takahashi T, Sugiyama T, et al. 2002. Multiple routes communicating nitrogen availability from roots to shoots: a signal transduction pathway mediated by cytokinin. J Exp Bot, 53: 971 ～977
[64] Tingey DT, Phillips D, Johnson MG. 2000. Elevated CO₂ and conifer roots:effects on growth, life span and turnover. New Phytol, 147:87～103