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Plant and Soil

, Volume 344, Issue 1–2, pp 361–376 | Cite as

Soil properties associated with net nitrification following watershed conversion from Appalachian hardwoods to Norway spruce

  • Charlene N. Kelly
  • Stephen H. Schoenholtz
  • Mary Beth Adams
Regular Article

Abstract

Nitrate (NO3-N) in soil solution and streamwater can be an important vector of nitrogen (N) loss from forested watersheds, and nitrification is associated with negative consequences of soil acidification and eutrophication of aquatic ecosystems. The purpose of this study was to identify vegetation-mediated soil properties that may control potential net nitrification dynamics and to determine if net nitrification is a function of abiotic retention or biotic inhibition. We performed a soil inoculation and incubation study and analyzed a suite of soil chemical and biological properties in soils from a 40-year-old Appalachian hardwood forest and an adjacent 37-year-old Norway spruce forest converted from Appalachian hardwoods. Our results indicate that net NO3-N production was nine times higher in hardwood soil (mean = 183.51 mg N/kg/28 days) than in the spruce soil (mean = 18.97 mg N/kg/28 days) and differences in net NO3-N production were attributed to differences in soil substrate quality. Soil properties that were most strongly correlated with NO3-N production across vegetation types included total soil N, soil C:N ratio, oxalate concentration, and sulfate concentration. Establishment of a spruce monoculture in the central Appalachian hardwood ecoregion significantly altered N cycling, likely depleted soil N stores, increased soil acidity, and altered soil organic matter dynamics, thus leading to low net nitrification rates.

Keywords

Nitrification Norway spruce Appalachian hardwoods Fernow Experimental Forest Forest conversion Soil organic matter 

References

  1. Aber JD (1992) Nitrogen cycling and nitrogen saturation in temperate forest ecosystems. Trends Ecol Evol 7:220–223PubMedCrossRefGoogle Scholar
  2. Adams MB, Edwards PJ, Kochenderfer JN, Wood F (2003) Fifty years of watershed research on the Fernow Experimental Forest, WV: effects of forest management and air pollution in hardwood forests. In: Renard KG, McElroy SA, Gburek WJ, Canfield HE, Scott RL (eds) First interagency conference on research in the watersheds. USDA-ARS, Benson, pp 391–396Google Scholar
  3. Anderson JPE, Domsch KE (1978) Mineralization of bacteria and fungi in chloroform-fumigated soils. Soil Biol Biochem 10(3):207–213CrossRefGoogle Scholar
  4. Anderson JEP, Domsch KE (1985) Determination of ecophysiological maintenance carbon requirements of soil microorganisms in a dormant state. Biol Fertil Soils 1:81–89CrossRefGoogle Scholar
  5. Bengtsson G, Bengtson P, Mansson KF (2003) Gross nitrogen mineralization-, immobilization-, and nitrification rates as a function of soil C/N ratio and microbial activity. Soil Biol Biochem 35(1):143–154CrossRefGoogle Scholar
  6. Blum U, Worsham AD, King LD, Gerig TM (1994) Use of water and EDTA extractions to estimate available (free and reversibly bound) phenolic acids in Cecil soils. J Chem Ecol 20:341–359CrossRefGoogle Scholar
  7. Bohlen PJ, Groffman PM, Driscoll CT, Fahey TJ, Siccama TG (2001) Plant-soil-microbial interactions in a northern hardwood forest. Ecology 82(4):965–978Google Scholar
  8. Bradbury NJ, Whitmore AP, Hart PBS, Jenkinson DS (1993) Modelling the fate of nitrogen in crop and soil in the years following application of 15N-labelled fertilizer to winter wheat. J Agric Sci 121:363–379CrossRefGoogle Scholar
  9. Brar SS, Giddens J (1968) Inhibition of nitrification in Bladen Grassland soil. Soil Sci Soc Am J 32:821–823CrossRefGoogle Scholar
  10. Carlyle JC, Lowther JR, Smethurst PJ, Nambiar EKS (1990) Influence of chemical properties on nitrogen mineralization and nitrification in podzolized sands. Implications for forest management. Aust J Soil Res 28:981–1000CrossRefGoogle Scholar
  11. Carter MR (1993) Soil sampling and methods of analysis. Canadian Society of Soil Science. LewisGoogle Scholar
  12. Chao TT, Harward ME, Fang SC (1964) Iron or aluminum coatings in relation to sulfate adsorption characteristics of soils. Soil Sci Soc Am Proc 28:632–635CrossRefGoogle Scholar
  13. Chapela IH, Osher LJ, Horton TR, Henn MR (2001) Ectomycorrhizal fungi introduced with exotic pine plantations induce soil carbon depletion. Soil Biol Biochem 33:1733–1740CrossRefGoogle Scholar
  14. Christ MJ, Peterjohn WT, Cumming JR, Adams MB (2002) Nitrification potentials and landscape, soil and vegetation characteristics in two Central Appalachian watersheds differing in NO3 export. For Ecol Manag 159:145–158CrossRefGoogle Scholar
  15. Christenson LM, Lovett GM, Weathers KC, Arthur MA (2009) The influence of tree species, nitrogen fertilization, and soil C to N ratio on gross soil nitrogen transformations. Soil Sci Soc Am J 73(2):638–646CrossRefGoogle Scholar
  16. Christopher SF, Mitchell MJ, McHale MR, Boyer EW, Burns DA, Kendall C (2008) Factors controlling nitrogen release from two forested catchments with contrasting hydrochemical responses. Hydrol Process 22:46–62CrossRefGoogle Scholar
  17. Cooper BA (1990) Nitrate depletion in the riparian zone and stream channel of a small headwater catchment. Hydrobiol 202(1–2):13–26Google Scholar
  18. Curiale M (2009) MPN Calculator; Build 23. <http://members.ync.net/mcuriale/mpn/>
  19. Davidson EA, Janssens IA (2006) Temperature sensitivity of soil carbon decomposition and feedbacks to climate change. Nature 440:165–174PubMedCrossRefGoogle Scholar
  20. De Boer W, Kowalchuk GA (2001) Nitrification in acid soils: micro-organisms and mechanisms. Soil Biol Biochem 33(7–8):853–866CrossRefGoogle Scholar
  21. De Boer W, Laanbroek HJ (1989) Ureolytic nitrification at low pH by Nitrospira spec. Arch Microbiol 152:178–181CrossRefGoogle Scholar
  22. Drury CF, Beauchamp EG (1991) Ammonium fixation, release, nitrification, and immobilization in high- and low-fixing soils. Soil Sci Soc Am J 55(1):125–129CrossRefGoogle Scholar
  23. Fenn ME, Poth MA, Aber JD, Baron JS, Bormann BT, Lemly AD, McNulty SG, Ryan DF, Stottlemyer R (1998) Nitrogen excess in North American ecosystems: predisposing factors, ecosystem responses, and management strategies. Ecol Applic 8(3):706–733Google Scholar
  24. Fitzhugh RD, Lovett GM, Venterea RT (2003) Biotic and abiotic immobilization of ammonium, nitrite, and nitrate in soils developed under different tree species in the Catskill Mountains, New York, USA. Glob Chang Biol 9:1591–1601CrossRefGoogle Scholar
  25. Frey SD, Knorr M, Parrent JL, Simpson RT (2004) Chronic nitrogen enrichment affects the structure and function of the soil microbial community in temperate hardwood and pine forests. For Ecol Manag 196(1):159–171CrossRefGoogle Scholar
  26. Gilliam FS, Yurish BM, Adams MB (2001) Temporal and spatial variation of nitrogen transformations in nitrogen-saturated soils of a central Appalachian hardwood forest. Can J For Res 31:1768–1785CrossRefGoogle Scholar
  27. Goodale CL, Aber JD (2001) The long-term effects of land-use history on nitrogen cycling in northern hardwood forests. Ecol Appl 11(1):253–267CrossRefGoogle Scholar
  28. Gundersen P, Callesen I, de Vries W (1998) Nitrate leaching in forest ecosystems is related to forest floor C/N ratios. Environ Pollut 102(1,1):402–407Google Scholar
  29. Gundersen P, Schmidt IK, Raulund-Rasumssen K (2006) Leaching of nitrate from temperate forests- effects of air pollution and forest management. Environ Rev 14:1–57CrossRefGoogle Scholar
  30. Guo LB, Gifford RM (2002) Soil carbon stocks and land use change: a meta analysis. Glob Chang Biol 8(4):345–360CrossRefGoogle Scholar
  31. Hendershot WH, Lalande H, Duquette M (1984) Soil reaction and exchangeable acidity: In: Carter (ed) Soil sampling and methods of analysis. Canadian Society of Soil Science, pp 142–145Google Scholar
  32. Hill AR (1996) Nitrate removal in stream riparian zones. J Environ Qual 25:743–755CrossRefGoogle Scholar
  33. Huang Y, Zou J, Zheng X, Wang Y, Xu X (2004) Nitrous oxide emissions as influenced by amendment of plant residues with different C:N ratios. Soil Biol Biochem 36(6):973–981CrossRefGoogle Scholar
  34. Hurley MA, Roscoe ME (1983) Automated statistical analysis of microbial enumeration by dilution series. J Appl Bacteriol 55:159–164Google Scholar
  35. Janssen BH (1996) Nitrogen mineralization in relation to C/N ratio and decomposability of organic materials. Plant Soil 181:39–45CrossRefGoogle Scholar
  36. Johansson MB (1995) The chemical composition of needle and leaf litter from Scots pine, Norway spruce and white birch in Scandinavian forests. Forestry 68(1):49–62CrossRefGoogle Scholar
  37. Johnson DW, Cole DW (1980) Anion mobility in soils: relevance to nutrient transport from forest ecosystems. Environ Int 3(1):79–90CrossRefGoogle Scholar
  38. Jones DL (1998) Organic acids in the rhizosphere—a critical review. Plant Soil 205(1):25–44CrossRefGoogle Scholar
  39. Joye SB, Hollibaugh JT (1995) Influence of sulfide inhibition of nitrification of nitrogen regeneration in sediments. Science 270(5236):623–625CrossRefGoogle Scholar
  40. Kasel S, Bennett LT (2007) Land-use history, forest conversion, and soil organic carbon in pine plantations and native forests of south eastern Australia. Geoderma 137(3–4):401–413CrossRefGoogle Scholar
  41. Kelly CN (2010) Carbon and nitrogen cycling in watersheds of contrasting vegetation types in the Fernow Experimental Forest, West Virginia. Dissertation, Virginia Polytechnic Institute and State UniversityGoogle Scholar
  42. Klugh KR, Cumming JR (2007) Variations in organic acid exudation and aluminum resistance among arbuscular mycorrhizal species colonizing Liriodendron tulipifera. Tree Physiol 27:1103–1112PubMedGoogle Scholar
  43. Klugh-Stewart KR, Cumming JR (2009) Organic acid exudation by mycorhhizal Andropogon virinicus L. (broomsedge) roots in response to aluminum. Soil Biol Biochem 41(2):367–373CrossRefGoogle Scholar
  44. Kochian LV, Hoekenga OA, Pineros MA (2004) How do crop plants tolerate acid soils? Mechanisms of aluminum tolerance and phosphorus efficiency. Annu Rev Plant Biol 55:459–493PubMedCrossRefGoogle Scholar
  45. Lovett GM, Weathers KC, Arthur MA (2002) Control of nitrogen losses from forested watersheds by soil carbon:nitrogen ratio and tree species composition. Ecosystems 5(7):712–718CrossRefGoogle Scholar
  46. Lugo AE, Brown S (1993) Management of tropical soils as sinks or sources of atmospheric carbon. Plant Soil 149(1):27–41CrossRefGoogle Scholar
  47. Ma JF (2000) Role of organic acids in detoxification of aluminum in higher plants. Plant Cell Physiol 41(4):383–390PubMedGoogle Scholar
  48. Melillo JM, Naimen RJ, Aber JD, Eschleman KN (1983) The influence of substrate quality and stream size on wood decomposition dynamics. Oecologia 58(3):281–285CrossRefGoogle Scholar
  49. Nodvin SC, Driscoll CT, Likens GE (1986) The effect of pH on sulfate adsorption by a forest soil. Soil Sci 142(2):69–75CrossRefGoogle Scholar
  50. Nodvin SC, Driscoll CT, Likens GE (1988) Soil processes and sulfate loss at the Hubbard Brook Experimental Forest. Biogeochem 5(2):185–199CrossRefGoogle Scholar
  51. Ombodi A, Miyoshi S, Saigusa M (1999) Effects of band applications of polyolefin-coated fertilizers on the nitrate and oxalate content in spinach. Tohoku J Agric Res 49(3–4):101–109Google Scholar
  52. Paavolainen L, Kitunen V, Smolander A (1998) Inhibition of nitrification in forest soil by monoterpenes. Plant Soil 205:147–154CrossRefGoogle Scholar
  53. Papen H, von Berg R (1998) A Most Probable Number method (MPN) for the estimation of cell numbers of heterotrophic nitrifying bacteria in soil. Plant Soil 199(1):123–130CrossRefGoogle Scholar
  54. Pella E, Colombo B (1973) Study of carbon, hydrogen and nitrogen determination by combustion-gas chromatography. Mikrochim Acta (Wein) 61(5):697–719Google Scholar
  55. Peterjohn WP, Foster CJ, Christ MJ, Adams MB (1999) Patterns of nitrogen availability within a forested watershed exhibiting symptoms of nitrogen saturation. For Ecol Manag 119:247–257CrossRefGoogle Scholar
  56. Pineros MA, Magalhaes JV, Carvalho Alves VM, Kochian LV (2002) The physiology and biophysics of an aluminum tolerance mechanism based on root citrate exudation in maize. Plant Physiol 129:1194–1206PubMedCrossRefGoogle Scholar
  57. Read DJ, Perez-Moreno J (2003) Mycorrhizas and nutrient cycling in ecosystems—a journey towards relevance. New Phytol 157:475–492CrossRefGoogle Scholar
  58. Robertson GP (1982) Nitrification in forested ecosystems. Philos Trans R Soc Lond 296(1082):445–457CrossRefGoogle Scholar
  59. Robertson GP, Vitousek PM (1981) Nitrification potentials and secondary succession. Ecology 62(2):376–386CrossRefGoogle Scholar
  60. Ross DS, Lawrence GB, Fredriksen F (2004) Mineralization and nitrification patterns at eight northeastern USA forested research sites. For Ecol Manag 188(1–3):317–335CrossRefGoogle Scholar
  61. Sahrawat KL (1980) Nitrogen mineralization in acid sulfate soils. Plant Soil 57(1):143–146CrossRefGoogle Scholar
  62. Schmidt EL, Belser LW (1994) Autotrophic nitrifying bacteria. Methods of soil analysis, part 2. Microbiological and biochemical properties. Soil Sci Soc Am, MadisonGoogle Scholar
  63. Schmidt SK, Lipson DA, Ley RE, Fisk MC, West AE (2004) Impacts of chronic nitrogen additions vary seasonally and by microbial functional group in tundra soils. Biogeochem 69(1):1–17CrossRefGoogle Scholar
  64. Soil Survey Staff, Natural Resources Conservation Service, United States Department of Agriculture (2010) Web Soil Survey. Available online at http://websoilsurvey.nrcs.usda.gov/accessed [2/10/2010]
  65. Spaccini R, Piccolo A, Conte P, Haberhauer G, Gerzabek MH (2002) Increased soil organic carbon sequestration through hydrophobic protection by humic substances. Soil Biol Biochem 34:1839–1851CrossRefGoogle Scholar
  66. Ste-Marie C, Pare D (1999) Soil, pH and N availability effects on net nitrification in the forest floors of a range of boreal forest stands. Soil Biol Biochem 31:1579–1589CrossRefGoogle Scholar
  67. Straker CJ (1996) Ericoid mycorrhiza: ecological and host specificity. Mycorrhiza 6:215–225CrossRefGoogle Scholar
  68. Strobel BW (2001) Influence of vegetation on low-molecular-weight carboxylic acids in soil solution-a review. Geoderma 99(3–4):169–198CrossRefGoogle Scholar
  69. Thomas GW (1982) Exchangeable cations. In: Page AL et al (eds) Methods of soil analysis. Agronomy no. 9, 2nd edn. Am Soc Agron, MadisonGoogle Scholar
  70. Thurman EM, Malcolm RL (1981) Preparative isolation of aquatic humic substances. Environ Sci Technol 15(4):463–466CrossRefGoogle Scholar
  71. Tietema A, Emmett BA, Gundersen P, Kjonaas OJ, Koopmans CJ (1998) The fate of 15N-labelled nitrogen deposition in coniferous forest ecosystems. For Ecol Manag 101(1–3):19–27CrossRefGoogle Scholar
  72. Tran TS, Simard RR (1993) Mehlich III-extractable elements. In: Carter MR (ed) Soil sampling and methods of analysis. Can Soc Soil Sci LewisGoogle Scholar
  73. van Veen JA, Ladd JN, Frissel MJ (1984) Modeling C and N turnover through the microbial biomass in soil. Plant Soil 76:257–274CrossRefGoogle Scholar
  74. Vitousek PM, Matson PA (1985) Disturbance, nitrogen availability, and nitrogen losses in an intensively managed loblolly pine plantation. Ecology 66(4):1360–1376CrossRefGoogle Scholar
  75. Vitousek PM, Gosz JR, Grier CC, Melillo JM, Reiners WA (1982) A comparative analysis of potential nitrification and nitrate mobility in forest ecosystems. Ecol Monogr 52(2):155–177CrossRefGoogle Scholar
  76. Warby RA, Johnson CE, Driscoll CT (2007) Continuing acidification of organic soils across the northeastern USA: 1984–2001. Soil Sci Soc Am J 73(1):274–284CrossRefGoogle Scholar
  77. Wardle DA (1992) A comparative assessment of factors which influence microbial biomass carbon and nitrogen levels in soil. Biol Rev 67(3):321–358CrossRefGoogle Scholar
  78. Whalen JK, Bottomley PJ, Myrold DD (2000) Carbon and nitrogen mineralization from light- and heavy-fraction additions to soil. Soil Biol Biochem 32:1345–1352CrossRefGoogle Scholar
  79. Woomer PL (1994) Most probable number counts. In: Methods of soil analysis, part 2. Microbiological and biochemical properties. Soil Sci Soc Am, Madison, pp 59–79Google Scholar
  80. Yu Z, Zhang Q, Kraus TEC, Dahlgren RA, Anastasio C, Zasoski RJ (2002) Contribution of amino compounds to dissolved organic nitrogen in forest soils. Biogeochemistry 61:173–198CrossRefGoogle Scholar
  81. Zak DR, Groffman PM, Pregitzer KS, Christensen S, Tiedje JM (1990) The vernal dam: plant-microbe competition for nitrogen in northern hardwood forests. Ecology 71(2):651–656CrossRefGoogle Scholar

Copyright information

© Springer Science+Business Media B.V. 2011

Authors and Affiliations

  • Charlene N. Kelly
    • 1
  • Stephen H. Schoenholtz
    • 2
  • Mary Beth Adams
    • 3
  1. 1.Department of Forest Resources and Environmental ConservationVirginia Polytechnic Institute and State UniversityBlacksburgUSA
  2. 2.Virginia Water Resources and Research CenterVirginia Polytechnic Institute and State UniversityBlacksburgUSA
  3. 3.Timber and Watershed LaboratoryUSDA Forest ServiceParsonsUSA

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