Ecosystem Consequences of Changing Inputs of Terrestrial Dissolved Organic Matter to Lakes: Current Knowledge and Future Challenges

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• 作者：Christopher T. Solomon (1)
  Stuart E. Jones (2)
  Brian C. Weidel (3)
  Ishi Buffam (4)
  Megan L. Fork (5)
  Jan Karlsson (6)
  S酶ren Larsen (7)
  Jay T. Lennon (8)
  Jordan S. Read (9)
  Steven Sadro (10)
  Jasmine E. Saros (11)
  
  1. Department of Natural Resource Sciences ; McGill University ; Montreal ; Quebec ; Canada
  2. Department of Biological Sciences ; University of Notre Dame ; South Bend ; Indiana ; USA
  3. Lake Ontario Biological Station ; U.S. Geological Survey ; Oswego ; New York ; USA
  4. Departments of Biological Sciences and Geography ; University of Cincinnati ; Cincinnati ; Ohio ; USA
  5. Nicholas School of the Environment ; Duke University ; Durham ; North Carolina ; USA
  6. Department of Ecology and Environmental Science ; Ume氓 University ; Ume氓 ; Sweden
  7. Centre for Ecological and Evolutionary Synthesis ; Department of Bioscience ; University of Oslo ; Oslo ; Norway
  8. Department of Biology ; Indiana University ; Bloomington ; Indiana ; USA
  9. Center for Integrated Data Analytics ; U.S. Geological Survey ; Middleton ; Wisconsin ; USA
  10. Marine Science Institute ; University of California ; Santa Barbara ; California ; USA
  11. Climate Change Institute ; School of Biology & Ecology ; University of Maine ; Orono ; Maine ; USA
  
• 关键词：lake ; ecosystem ; dissolved organic matter ; dissolved organic carbon ; terrestrial inputs ; allochthonous ; environmental change ; review
• 刊名：Ecosystems
• 出版年：2015
• 出版时间：April 2015
• 年：2015
• 卷：18
• 期：3
• 页码：376-389
• 全文大小：771 KB
• 参考文献：1. Adin, A, Katzhendler, J, Alkaslassy, D, Rav-Acha, D (1991) Trihalomethane formation in chlorinated drinking water: a kinetic model. Water Res 25: pp. 797-805
  2. Aitkenhead-Peterson, J, McDowell, W, Neff, J, Stuart, E, Robert, L (2003) Sources, production, and regulation of allochthonous dissolved organic matter inputs to surface waters. Academic Press, San Diego
  3. Ask, J, Karlsson, J, Persson, L, Ask, P, Bystrom, P, Jansson, M (2009) Terrestrial organic matter and light penetration: effects on bacterial and primary production in lakes. Limnol Oceanogr 54: pp. 2034-2040
  4. Barichivich, J, Briffa, KR, Myneni, RB, Osborn, TJ, Melvin, TM, Ciais, P, Piao, SL, Tucker, C (2013) Large-scale variations in the vegetation growing season and annual cycle of atmospheric CO2 at high northern latitudes from 1950 to 2011. Global Change Biol 19: pp. 3167-3183
  5. Battin, TJ, Luyssaert, S, Kaplan, LA, Aufdenkampe, AK, Richter, A, Tranvik, LJ (2009) The boundless carbon cycle. Nat Geosci 2: pp. 598-600
  6. Belyea, LR, Malmer, N (2004) Carbon sequestration in peatland: patterns and mechanisms of response to climate change. Global Change Biol 10: pp. 1043-1052
  7. Berggren, M, Strom, L, Laudon, H, Karlsson, J, Jonsson, A, Giesler, R, Bergstrom, AK, Jansson, M (2010) Lake secondary production fueled by rapid transfer of low molecular weight organic carbon from terrestrial sources to aquatic consumers. Ecol Lett 13: pp. 870-880
  8. Brag茅e, P, Mazier, F, Ros茅n, P, Fredh, D, Brostr枚m, A, Gran茅li, W, Hammarlund, D (2013) Forcing mechanisms behind variations in total organic carbon (TOC) concentration of lake waters during the past eight centuries; palaeolimnological evidence from southern Sweden. Biogeosci Discuss 10: pp. 19969-20003
  9. Brett, MT, Kainz, MJ, Taipale, SJ, Seshan, H (2009) Phytoplankton, not allochthonous carbon, sustains herbivorous zooplankton production. Proc Natl Acad Sci USA 106: pp. 21197-21201
  10. Brothers, S, K枚hler, J, Attermeyer, K, Grossart, HP, Mehner, T, Meyer, N, Scharnweber, K, Hilt, S (2014) A feedback loop links brownification and anoxia in a temperate, shallow lake. Limnol Oceanogr 59: pp. 1388-1398
  11. Canham, CD, Pace, ML, Papaik, MJ, Primack, AGB, Roy, KM, Maranger, RJ, Curran, RP, Spada, DM (2004) A spatially explicit watershed-scale analysis of dissolved organic carbon in Adirondack lakes. Ecol Appl 14: pp. 839-854
  12. Carpenter, SR, Cole, JJ, Kitchell, JF, Pace, ML (1998) Impact of dissolved organic carbon, phosphorus, and grazing on phytoplankton biomass and production in experimental lakes. Limnol Oceanogr 43: pp. 73-80
  13. Clark, JM, Ashley, D, Wagner, M, Chapman, PJ, Lane, SN, Evans, CD, Heathwaite, AL (2009) Increased temperature sensitivity of net DOC production from ombrotrophic peat due to water table draw-down. Global Change Biol 15: pp. 794-807
  14. Clark, JM, Bottrell, SH, Evans, CD, Monteith, DT, Bartlett, R, Rose, R, Newton, RJ, Chapman, PJ (2010) The importance of the relationship between scale and process in understanding long-term DOC dynamics. Sci Total Environ 408: pp. 2768-2775
  15. Clark, JM, Chapman, PJ, Adamson, JK, Lane, SN (2005) Influence of drought-induced acidification on the mobility of dissolved organic carbon in peat soils. Global Change Biol 11: pp. 791-809
  16. Cole, JJ, Carpenter, SR, Kitchell, JF, Pace, ML, Solomon, CT, Weidel, BC (2011) Strong evidence for terrestrial support of zooplankton in small lakes based on stable isotopes of carbon, nitrogen, and hydrogen. Proc Natl Acad Sci USA 108: pp. 1975-1980
  17. Cole, JJ, Prairie, YT, Caraco, NF, McDowell, WH, Tranvik, LJ, Striegl, RG, Duarte, CM, Kortelainen, P, Downing, JA, Middelburg, JJ, Melack, J (2007) Plumbing the global carbon cycle: Integrating inland waters into the terrestrial carbon budget. Ecosystems 10: pp. 171-184
  18. Cole, L, Bardgett, RD, Ineson, P, Adamson, JK (2002) Relationships between enchytraeid worms (Oligochaeta), climate change, and the release of dissolved organic carbon from blanket peat in northern England. Soil Biol Biochem 34: pp. 599-607
  19. Davidson, EA, Janssens, IA (2006) Temperature sensitivity of soil carbon decomposition and feedbacks to climate change. Nature 440: pp. 165-173
  20. Wit, HA, Mulder, J, Hindar, A, Hole, L (2007) Long-term increase in dissolved organic carbon in streamwaters in Norway is response to reduced acid deposition. Environ Sci Technol 41: pp. 7706-7713
  21. Giorgio, PA, Peters, RH (1994) Patterns in planktonic P: R ratios in lakes: influence of lake trophy and dissolved organic carbon. Limnol Oceanogr 39: pp. 772-787
  22. Erlandsson, M, Buffam, I, Folster, J, Laudon, H, Temnerud, J, Weyhenmeyer, GA, Bishop, K (2008) Thirty-five years of synchrony in the organic matter concentrations of Swedish rivers explained by variation in flow and sulphate. Global Change Biol 14: pp. 1191-1198
  23. Estlander, S, Nurminen, L, Olin, M, Vinni, M, Immonen, S, Rask, M, Ruuhijarvi, J, Horppila, J, Lehtonen, H (2010) Diet shifts and food selection of perch Perca fluviatilis and roach Rutilus rutilus in humic lakes of varying water colour. J Fish Biol 77: pp. 241-256
  24. Evans, CD, Chapman, PJ, Clark, JM, Monteith, DT, Cresser, MS (2006) Alternative explanations for rising dissolved organic carbon export from organic soils. Global Change Biol 12: pp. 2044-2053
  25. Evans, CD, Monteith, DT, Cooper, DM (2005) Long-term increases in surface water dissolved organic carbon: observations, possible causes and environmental impacts. Environ Pollut 137: pp. 55-71
  26. Fee, EJ, Hecky, RE, Kasian, SEM, Cruikshank, DR (1996) Effects of lake size, water clarity, and climatic variability on mixing depths in Canadian Shield lakes. Limnol Oceanogr 41: pp. 912-920
  27. Finstad, AG, Helland, IP, Ugedal, O, Hesthagen, T, Hessen, DO (2014) Unimodal response of fish yield to dissolved organic carbon. Ecol Lett 17: pp. 36-43
  28. Fork, ML, Heffernan, JB (2013) Direct and indirect effects of dissolved organic matter source and concentration on denitrification in northern Florida rivers. Ecosystems 17: pp. 14-28
  29. Freeman, C, Evans, CD, Monteith, DT, Reynolds, B, Fenner, N (2001) Export of organic carbon from peat soils. Nature 412: pp. 785
  30. Freeman, C, Ostle, N, Kang, H (2001) An enzymic 鈥榣atch鈥?on a global carbon store鈥攁 shortage of oxygen locks up carbon in peatlands by restraining a single enzyme. Nature 409: pp. 149
  31. Frey, KE, McClelland, JW (2009) Impacts of permafrost degradation on arctic river biogeochemistry. Hydrol Process 23: pp. 169-182
  32. Futter, MN, Butterfield, D, Cosby, BJ, Dillon, PJ, Wade, AJ, Whitehead, PG (2007) Modeling the mechanisms that control in-stream dissolved organic carbon dynamics in upland and forested catchments. Water Res 43: pp. W02424
  33. Geller, A (1986) Comparison of mechanisms enhancing biodegradbility of refractory lake water constituents. Limnol Oceanogr 31: pp. 755-764
  34. Gergel, SE, Turner, MG, Kratz, TK (1999) Dissolved organic carbon as an indicator of the scale of watershed influence on lakes and rivers. Ecol Appl 9: pp. 1377-1390
  35. Grey, J, Jones, RI, Sleep, D (2001) Seasonal changes in the importance of the source of organic matter to the diet of zooplankton in Loch Ness, as indicated by stable isotope analysis. Limnol Oceanogr 46: pp. 505-513
  36. Haaland, S, Hongve, D, Laudon, H, Riise, G, Vogt, RD (2010) Quantifying the drivers of the increasing colored organic matter in boreal surface waters. Environ Sci Technol 44: pp. 2975-2980
  37. Haei, M, Oquist, MG, Buffam, I, Agren, A, Blomkvist, P, Bishop, K, Lofvenius, MO, Laudon, H (2010) Cold winter soils enhance dissolved organic carbon concentrations in soil and stream water. Geophys Res Lett 37: pp. L08501
  38. Hanson, PC, Bade, DL, Carpenter, SR, Kratz, TK (2003) Lake metabolism: relationships with dissolved organic carbon and phosphorus. Limnol Oceanogr 48: pp. 1112-1119
  39. Hanson, PC, Carpenter, SR, Cardille, JA, Coe, MT, Winslow, LA (2007) Small lakes dominate a random sample of regional lake characteristics. Freshw Biol 52: pp. 814-822
  40. Hessen, DO Food webs and carbon cycling in humic lakes. In: Tranvik, LJ, Hessen, DO eds. (1998) Aquatic humic substances: ecology and biochemistry. Springer, Berlin, pp. 285-315
  41. Hongve, D, Riise, G, Kristiansen, JF (2004) Increased colour and organic acid concentrations in Norwegian forest lakes and drinking water鈥攁 result of increased precipitation?. Aquat Sci 66: pp. 231-238
  42. Hope, D, Kratz, TK, Riera, JL (1996) Relationship between P-CO2 and dissolved organic carbon in northern Wisconsin lakes. J Environ Qual 25: pp. 1442-1445
  43. Houser, JN (2006) Water color affects the stratification, surface temperature, heat content, and mean epilimnetic irradiance of small lakes. Can J Fish Aquat Sci 63: pp. 2447-2455
  44. Hughes S, Freeman C, Reynolds B, Hudson JA. 1998. The effects of increased drought frequency on sulphate and dissolved organic carbon in peatland dominated ecosystems. Proceedings of the 2nd international conference on climate and water. Helsinki: Edita Limited. pp 311鈥?19.
  45. Imberger, J (1998) Flux paths in a stratified lake. Coast Estuar Stud 54: pp. 1-18
  46. Jackson, TA, Hecky, RE (1980) Depression of primary productivity by humic matter in lake and reservoir waters of the boreal forest zone. Can J Fish Aquat Sci 37: pp. 2300-2317
  47. Jansson, M, Hickler, T, Jonsson, A, Karlsson, J (2008) Links between terrestrial primary production and bacterial production and respiration in lakes in a climate gradient in subarctic Sweden. Ecosystems 11: pp. 367-376
  48. Jansson, M, Karlsson, J, Jonsson, A (2012) Carbon dioxide supersaturation promotes primary production in lakes. Ecol Lett 15: pp. 527-532
  49. Jones, RI (1992) The influence of humic substances on lacustrine planktonic food-chains. Hydrobiologia 229: pp. 73-91
  50. Jones, SE, Solomon, CT, Weidel, BC (2012) Subsidy or subtraction: how do terrestrial inputs influence consumer production in lakes?. Freshw Rev 5: pp. 37-49
  51. Jonsson, M, Hedstr枚m, P, Stenroth, K, Hotchkiss, ER, Vasconcelos, FR, Karlsson, J, Bystrom, P (2015) Climate change modifies the size structure of assemblages of emerging aquatic insects. Freshw Biol 60: pp. 78-88
  52. Karlsson, J, Bystrom, P, Ask, J, Ask, P, Persson, L, Jansson, M (2009) Light limitation of nutrient-poor lake ecosystems. Nature 460: pp. 506-509
  53. Karlsson, J, Jonsson, A, Meili, M, Jansson, M (2003) Control of zooplankton dependence on allochthonous organic carbon in humic and clear-water lakes in northern Sweden. Limnol Oceanogr 48: pp. 269-276
  54. Kelly, PT, Solomon, CT, Weidel, BC, Jones, SE (2014) Terrestrial carbon is a resource, but not a subsidy, for lake zooplankton. Ecology 95: pp. 1236-1242
  55. Kenny JF, Barber NL, Huston SS, Linsey KS, Lovelace JK, Maupin, MA. 2009. Estimated use of water in the United States in 2005. U.S.G. Survey, editor. p 52.
  56. Kirk, JTO (1994) Light and photosynthesis in aquatic ecosystems. Cambridge University Press, Cambridge
  57. Kirschbaum, MUF (2006) The temperature dependence of organic-matter decomposition鈥攕till a topic of debate. Soil Biol Biochem 38: pp. 2510-2518
  58. Kling, GW (1988) Comparative transparency, depth of mixing, and stability of stratification in lakes of Cameroon, West Africa. Limnol Oceanogr 33: pp. 27-40
  59. Kohler, SJ, Kothawala, D, Futter, MN, Liungman, O, Tranvik, L (2013) In-lake processes offset increased terrestrial inputs of dissolved organic carbon and color to lakes. PLoS ONE 8: pp. e70598
  60. Krasner, SW, Sclimenti, MJ, Means, EG (1994) Quality degradation: implications for DBP formation. J Am Water Works Assoc 86: pp. 34-47
  61. Kritzberg, ES, Ekstrom, SM (2012) Increasing iron concentrations in surface waters鈥攁 factor behind brownification?. Biogeosciences 9: pp. 1465-1478
  62. Kritzberg, ES, Gran茅li, W, Bj枚rk, J, Br枚nmark, C, Hallgren, P, Nicolle, A, Persson, A, Hansson, LA (2014) Warming and browning of lakes: consequences for pelagic carbon metabolism and sediment delivery. Freshw Biol 59: pp. 325-336
  63. Kullberg, A, Bishop, KH, Hargeby, A, Jansson, M, Petersen, RC (1993) The ecological significance of dissolved organic carbon in acidified waters. Ambio 22: pp. 331-337
  64. Lapierre, J-F, Guillemette, F, Berggren, M, Giorgio, PA (2013) Increases in terrestrially derived carbon stimulate organic carbon processing and CO2 emissions in boreal aquatic ecosystems. Nat Commun 4: pp. 2972
  65. Larsen, S, Andersen, T, Hessen, DO (2011) Climate change predicted to cause severe increase of organic carbon in lakes. Global Change Biol 17: pp. 1186-1192
  66. Larsen, S, Andersen, T, Hessen, DO (2011) The pCO2 in boreal lakes: organic carbon as a universal predictor?. Global Biogeochem Cycles 25: pp. 1-8
  67. Ledesma, JLJ, Kohler, SJ, Futter, MN (2012) Long-term dynamics of dissolved organic carbon: implications for drinking water supply. Sci Total Environ 432: pp. 1-11
  68. MacIntyre, S, Sickman, JO, Goldthwait, SA, Kling, GW (2006) Physical pathways of nutrient supply in a small, ultraoligotrophic arctic lake during summer stratification. Limnol Oceanogr 51: pp. 1107-1124
  69. Matilainen, A, Sillanpaa, M (2010) Removal of natural organic matter from drinking water by advanced oxidation processes. Chemosphere 80: pp. 351-365
  70. Matilainen, A, Vepsalainen, M, Sillanpaa, M (2010) Natural organic matter removal by coagulation during drinking water treatment: a review. Adv Colloid Interface Sci 159: pp. 189-197
  71. Matthews, B, Mazumder, A (2006) Habitat specialization and the exploitation of allochthonous carbon by zooplankton. Ecology 87: pp. 2800-2812
  72. Mattsson, T, Kortelainen, P, Raike, A (2005) Export of DOM from boreal catchments: impacts of land use cover and climate. Biogeochemistry 76: pp. 373-394
  73. McDonald AT, Mitchell GN, Naden PS, Martin DSJ. 1991. Discoloured water investigations. Report to Yorkshire Water.
  74. McDonald, S, Bishop, AG, Prenzler, PD, Robards, K (2004) Analytical chemistry of freshwater humic substances. Anal Chim Acta 527: pp. 105-124
  75. McKnight, DM, Aiken, GR Sources and age of aquatic humus. In: Hessen, DO, Tranvik, LJ eds. (1998) Aquatic humic substances. Springer, Berlin
  76. Minor, EC, Swenson, MM, Mattson, BM, Oyler, AR (2014) Structural characterization of dissolved organic matter: a review of current techniques for isolation and analysis. Environ Sci Process Impacts 16: pp. 2064-2079
  77. Mitchell, G, McDonald, AT (1992) Discoloration of water by peat following induced drought and rainfall simulation. Water Res 26: pp. 321-326
  78. Monteith, DT, Stoddard, JL, Evans, CD, Wit, HA, Forsius, M, Hogasen, T, Wilander, A, Skjelkvale, BL, Jeffries, DS, Vuorenmaa, J, Keller, B, Kopacek, J, Vesely, J (2007) Dissolved organic carbon trends resulting from changes in atmospheric deposition chemistry. Nature 450: pp. U537-U539
  79. Moran, MA, Hodson, RE (1990) Bacterial production on humic and nonhumic components of dissolved organic carbon. Limnol Oceanogr 35: pp. 1744-1756
  80. Morris, DP, Zagarese, H, Williamson, CE, Balseiro, EG, Hargreaves, BR, Modenutti, B, Moeller, R, Queimalinos, C (1995) The attenuation of solar UV radiation in lakes and the role of dissolved organic carbon. Limnol Oceanogr 40: pp. 1381-1391
  81. Mulholland, PJ Large-scale patterns in dissolved organic carbon concentration, flux, and sources. In: Findlay, S, Sinsabaugh, RL eds. (2003) Aquatic ecosystems: interactivity of dissolved organic matter. Elsevier, Amsterdam
  82. Neff, JC, Asner, GP (2001) Dissolved organic carbon in terrestrial ecosystems: synthesis and a model. Ecosystems 4: pp. 29-48
  83. Olin, M, Vinni, M, Lehtonen, H, Rask, M, Ruuhij盲rvi, J, Saulamo, K, Ala-Opas, P (2010) Environmental factors regulate the effects of roach Rutilus rutilus and pike Esox lucius on perch Perca fluviatilis populations in small boreal forest lakes. J Fish Biol 76: pp. 1277-1293
  84. Pace, ML, Cole, JJ, Carpenter, SR, Kitchell, JF, Hodgson, JR, Bogert, MC, Bade, DL, Kritzberg, ES, Bastviken, D (2004) Whole-lake carbon-13 additions reveal terrestrial support of aquatic food webs. Nature 427: pp. 240-243
  85. Palmer, ME, Yan, ND, Somers, KM (2014) Climate change drives coherent trends in physics and oxygen content in North American lakes. Clim Change 124: pp. 285-299
  86. Pastor, J, Solin, J, Bridgham, SD, Updegraff, K, Harth, C, Weishampel, P, Dewey, B (2003) Global warming and the export of dissolved organic carbon from boreal peatlands. Oikos 100: pp. 380-386
  87. P茅rez-Fuentetaja, A, Dillon, P, Yan, N, McQueen, D (1999) Significance of dissolved organic carbon in the prediction of thermocline depth in small Canadian shield lakes. Aquat Ecol 33: pp. 127-133
  88. Prairie, YT (2008) Carbocentric limnology: Looking back, looking forward. Can J Fish Aquat Sci 65: pp. 543-548
  89. Pregitzer, KS, Zak, DR, Burton, AJ, Ashby, JA, MacDonald, NW (2004) Chronic nitrate additions dramatically increase the export of carbon and nitrogen from northern hardwood ecosystems. Biogeochemistry 68: pp. 179-197
  90. Read, JS, Hamilton, DP, Desai, AR, Rose, KC, MacIntyre, S, Lenters, JD, Smyth, RL, Hanson, PC, Cole, JJ, Staehr, PA, Rusak, JA, Pierson, DC, Brookes, JD, Laas, A, Wu, CH (2012) Lake-size dependency of wind shear and convection as controls on gas exchange. Geophys Res Lett 39: pp. L09405
  91. Read, JS, Rose, KC (2013) Physical responses of small temperate lakes to variation in dissolved organic carbon concentrations. Limnol Oceanogr 58: pp. 921-931
  92. Rouillard, A, Rosen, P, Douglas, MSV, Pienitz, R, Smol, JP (2011) A model for inferring dissolved organic carbon (DOC) in lakewater from visible-near-infrared spectroscopy (VNIRS) measures in lake sediment. J Paleolimnol 46: pp. 187-202
  93. Roulet, N, Moore, TR (2006) Environmental chemistry鈥攂rowning the waters. Nature 444: pp. 283-284
  94. SanClements, MD, Oelsner, GP, McKnight, DM, Stoddard, JL, Nelson, SJ (2012) New insights into the source of decadal increases of dissolved organic matter in acid-sensitive lakes of the Northeastern United States. Environ Sci Technol 46: pp. 3212-3219
  95. Schindler, DW, Curtis, PJ, Bayley, SE, Parker, BR, Beaty, KG, Stainton, MP (1997) Climate-induced changes in the dissolved organic carbon budgets of boreal lakes. Biogeochemistry 36: pp. 9-28
  96. Skjelkvale, BL, Stoddard, JL, Jeffries, DS, Torseth, K, Hogasen, T, Bowman, J, Mannio, J, Monteith, DT, Mosello, R, Rogora, M, Rzychon, D, Vesely, J, Wieting, J, Wilander, A, Worsztynowicz, A (2005) Regional scale evidence for improvements in surface water chemistry 1990鈥?001. Environ Pollut 137: pp. 165-176
  97. Sleighter, RL, Hatcher, PG (2007) The application of electrospray ionization coupled to ultrahigh resolution mass spectrometry for the molecular characterization of natural organic matter. J Mass Spectrom 42: pp. 559-574
  98. Snucins, E, Gunn, J (2000) Interannual variation in the thermal structure of clear and colored lakes. Limnol Oceanogr 45: pp. 1639-1646
  99. Sobek, S, Algesten, G, Bergstrom, AK, Jansson, M, Tranvik, LJ (2003) The catchment and climate regulation of pCO(2) in boreal lakes. Global Change Biol 9: pp. 630-641
  100. Sobek S, Tranvik LJ, Cole JJ. 2005. Temperature independence of carbon dioxide supersaturation in global lakes. Global Biogeochem Cycles 19:GB2003.
  101. Solomon, CT, Bruesewitz, DA, Richardson, DC, Rose, KC, Bogert, MC, Hanson, PC, Kratz, TK, Larget, B, Adrian, R, Babin, BL, Chiu, CY, Hamilton, DP, Gaiser, EE, Hendricks, S, Istv谩novics, V, Laas, A, O鈥橠onnell, DM, Pace, ML, Ryder, E, Staehr, PA, Torgersen, T, Vanni, MJ, Weathers, KC, Zhu, G (2013) Ecosystem respiration: drivers of daily variability and background respiration in lakes around the globe. Limnol Oceanogr 58: pp. 849-866
  102. Solomon, CT, Carpenter, SR, Clayton, MK, Cole, JJ, Coloso, JJ, Pace, ML, Vander Zanden, MJ, Weidel, BC (2011) Terrestrial, benthic, and pelagic resource use in lakes: results from a three-isotope Bayesian mixing model. Ecology 92: pp. 1115-1125
  103. Sondergaard, M, Phillips, G, Hellsten, S, Kolada, A, Ecke, F, Maemets, H, Mjelde, M, Azzella, MM, Oggioni, A (2013) Maximum growing depth of submerged macrophytes in European lakes. Hydrobiologia 704: pp. 165-177
  104. Stanley, EH, Powers, SM, Lottig, NR, Buffam, I, Crawford, JT (2012) Contemporary changes in dissolved organic carbon (DOC) in human-dominated rivers: is there a role for DOC management?. Freshw Biol 57: pp. 26-42
  105. Stasko, AD, Gunn, JM, Johnston, TA (2012) Role of ambient light in structuring north-temperate fish communities: potential effects of increasing dissolved organic carbon concentration with a changing climate. Environ Rev 20: pp. 173-190
  106. Steinberg, CEW, Kamara, S, Prokhotskaya, VY, Manusadzianas, L, Karasyova, TA, Timofeyev, MA, Jie, Z, Paul, A, Meinelt, T, Farjalla, VF, Matsuo, AYO, Burnison, BK, Menzel, R (2006) Dissolved humic substances鈥攅cological driving forces from the individual to the ecosystem level?. Freshw Biol 51: pp. 1189-1210
  107. Striegl, RG, Aiken, GR, Dornblaser, MM, Raymond, PA, Wickland, KP (2005) A decrease in discharge-normalized DOC export by the Yukon River during summer through autumn. Geophys Res Lett 32: pp. L21413
  108. Taipale, S, Kankaala, P, Tiirola, M, Jones, RI (2008) Whole-lake dissolved inorganic C-13 additions reveal seasonal shifts in zooplankton diet. Ecology 89: pp. 463-474
  109. Tanentzap, AJ, Szkokan-Emilson, EJ, Kielstra, BW, Arts, MT, Yan, ND, Gunn, JM (2014) Forests fuel fish growth in freshwater deltas. Nat Commun 5: pp. 9
  110. Tanentzap, AJ, Yan, ND, Keller, B, Girard, R, Heneberry, J, Gunn, JM, Hamilton, DP, Taylor, PA (2008) Cooling lakes while the world warms: effects of forest regrowth and increased dissolved organic matter on the thermal regime of a temperate, urban lake. Limnol Oceanogr 53: pp. 404-410
  111. Thurman, E. M. 1985. Organic geochemistry of natural waters. Springer.
  112. Tranvik, LJ (1990) Bacterioplankton growth on fractions of dissolved organic carbon of different molecular weights from humic and clear waters. Appl Environ Microbiol 56: pp. 1672-1677
  113. Tranvik, LJ (1998) Degradation of dissolved organic matter in humic waters by bacteria. Aquatic humic substances. Springer, Berlin
  114. Tranvik, LJ, Bertilsson, S (2001) Contrasting effects of solar UV radiation on dissolved organic sources for bacterial growth. Ecol Lett 4: pp. 458-463
  115. Tranvik, LJ, Downing, JA, Cotner, JB, Loiselle, SA, Striegl, RG, Ballatore, TJ, Dillon, P, Finlay, K, Fortino, K, Knoll, LB, Kortelainen, PL, Kutser, T, Larsen, S, Laurion, I, Leech, DM, McCallister, SL, McKnight, DM, Melack, JM, Overholt, E, Porter, JA, Prairie, Y, Renwick, WH, Roland, F, Sherman, BS, Schindler, DW, Sobek, S, Tremblay, A, Vanni, MJ, Verschoor, AM, Wachenfeldt, E, Weyhenmeyer, GA (2009) Lakes and reservoirs as regulators of carbon cycling and climate. Limnol Oceanogr 54: pp. 2298-2314
  116. Tranvik, LJ, Jansson, M (2002) Climate change - Terrestrial export of organic carbon. Nature 415: pp. 861-862
  117. Volk, CJ, Volk, CB, Kaplan, LA (1997) Chemical composition of biodegradable dissolved organic matter in streamwater. Limnol Oceanogr 42: pp. 39-44
  118. Lutzow, M, Kogel-Knabner, I (2009) Temperature sensitivity of soil organic matter decomposition-what do we know?. Biol Fertil Soils 46: pp. 1-15
  119. Weidman, PR, Schindler, DW, Thompson, PL, Vinebrooke, RD (2014) Interactive effects of higher temperature and dissolved organic carbon on planktonic communities in fishless mountain lakes. Freshw Biol 59: pp. 889-904
  120. Weyhenmeyer, GA, Prairie, YT, Tranvik, LJ (2014) Browning of boreal freshwaters coupled to carbon-iron interactions along the aquatic continuum. PLoS ONE 9: pp. e88104
  121. Williamson, CE, Morris, DP, Pace, ML, Olson, AG (1999) Dissolved organic carbon and nutrients as regulators of lake ecosystems: resurrection of a more integrated paradigm. Limnol Oceanogr 44: pp. 795-803
  122. Williamson, CE, Stemberger, RS, Morris, DP, Frost, TM, Paulsen, SG (1996) Ultraviolet radiation in North American lakes: attenuation estimates from DOC measurements and implications for plankton communities. Limnol Oceanogr 41: pp. 1024-1034
  123. Winterdahl, M, Erlandsson, M, Futter, MN, Weyhenmeyer, GA, Bishop, K (2014) Intra-annual variability of organic carbon concentrations in running waters: drivers along a climatic gradient. Global Biogeochem Cycles 28: pp. 451-464
  124. Wu, ZT, Dijkstra, P, Koch, GW, Penuelas, J, Hungate, BA (2011) Responses of terrestrial ecosystems to temperature and precipitation change: a meta-analysis of experimental manipulation. Global Change Biol 17: pp. 927-942
  125. W眉est, A, Lorke, A (2003) Small-scale hydrodynamics in lakes. Ann Rev Fluid Mech 35: pp. 373-412
  126. Young, KC, Docherty, KM, Maurice, PA, Bridgham, SD (2005) Degradation of surface-water dissolved organic matter: influences of DOM chemical characteristics and microbial populations. Hydrobiologia 539: pp. 1-11
  
• 刊物类别：Biomedical and Life Sciences
• 刊物主题：Life Sciences
  Ecology
  Plant Sciences
  Zoology
  Environmental Management
  Geoecology and Natural Processes
  Nature Conservation
  
• 出版者：Springer New York
• ISSN：1435-0629

文摘

Lake ecosystems and the services that they provide to people are profoundly influenced by dissolved organic matter derived from terrestrial plant tissues. These terrestrial dissolved organic matter (tDOM) inputs to lakes have changed substantially in recent decades, and will likely continue to change. In this paper, we first briefly review the substantial literature describing tDOM effects on lakes and ongoing changes in tDOM inputs. We then identify and provide examples of four major challenges which limit predictions about the implications of tDOM change for lakes, as follows: First, it is currently difficult to forecast future tDOM inputs for particular lakes or lake regions. Second, tDOM influences ecosystems via complex, interacting, physical-chemical-biological effects and our holistic understanding of those effects is still rudimentary. Third, non-linearities and thresholds in relationships between tDOM inputs and ecosystem processes have not been well described. Fourth, much understanding of tDOM effects is built on comparative studies across space that may not capture likely responses through time. We conclude by identifying research approaches that may be important for overcoming those challenges in order to provide policy- and management-relevant predictions about the implications of changing tDOM inputs for lakes.