Advances in research on the roles of tannins in plant-soil nitrogen cycling

doi:10.11686/cyxb2019445

Abstract

Abstract: Tannins are secondary metabolites produced by higher plants. Tannins and tannin-linked organic nitrogen complexes play an important role in the nitrogen cycling at the plant-soil interface. The mechanisms by which tannins participate in the nitrogen cycling mainly include complexing organic nitrogen, affecting soil microbial activities and soil enzyme activities. Previous studies have not explored the complexation capacity of tannins to various organic nitrogen compounds, and the degradation mechanism of mycorrhizal fungi and saprophytic fungi on tannin-linked organic nitrogen complexes. Therefore, this review focuses on the complexation capacity of tannins to bind with various organic nitrogen compounds, the degradation mechanism of the complexes, the inhibition of soil enzyme activities by tannins and the influences of tannins on activities of soil microorganisms. Roles such as slowing of litter decomposition, inhibition of net nitrogen mineralization, and effects of tannins on net nitrification and nitrogen fixation in the nitrogen cycle is summarized. The findings of this review indicate that tannins can complex most of the organic nitrogen compounds; the structure and concentration of the tannins present can significantly affect the inhibitory actions of tannins on soil enzyme activities and net nitrogen mineralization, and soil microbial activity and diversity. These conclusions lay a foundation for further understanding of the role of tannins in nitrogen cycling at the plant-soil interface.

Key words: tannins, tannin-organic nitrogen complexes, nitrogen cycling, soil enzyme activity

ZONG Wen-zhen, GUO Jia-hao, JIA Yun-long, ZHENG Yong-xing, YANG Xu, HU Fang-di, WANG Jing. Advances in research on the roles of tannins in plant-soil nitrogen cycling[J]. Acta Prataculturae Sinica, 2020, 29(7): 174-183.

References

[1] Kraus T E C, Dahlgren R A, Zasoski R J. Tannins in nutrient dynamics of forest ecosystems-A review. Plant and Soil, 2003, 256(1): 41-66.
[2] Barbehenn R V, Constabel C P. Tannins in plant-herbivore interactions. Phytochemistry, 2011, 72(13): 1551-1565.
[3] Hernes P J, Hedges J I. Determination of condensed tannin monomers in environmental samples by capillary gas chromatography of acid depolymerization extracts. Analytical Chemistry, 2000, 72(20): 5115-5124.
[4] Olivoto T, Nardino M, Carvalho I R, et al. Plant secondary metabolites and its dynamical systems of induction in response to environmental factors: A review. African Journal of Agricultural Research, 2017, 12(2): 71-84.
[5] Herms D A, Mattson W J. The dilemma of plants: To grow or defend. Quarterly Review of Biology, 1992, 67(3): 283-335.
[6] Close D C, McArthur C. Rethinking the role of many plant phenolics-protection from photodamage not herbivores? Oikos, 2002, 99(1): 166-172.
[7] Schofield P, Mbugua D M, Pell A N. Analysis of condensed tannins: A review. Animal Feed Science and Technology, 2001, 91(1/2): 21-40.
[8] Kanerva S, Kitunen V, Kiikkila O, et al. Response of soil C and N transformations to tannin fractions originating from Scots pine and Norway spruce needles. Soil Biology and Biochemistry, 2006, 38(6): 1364-1374.
[9] Hättenschwiler S, Vitousek P M. The role of polyphenols in terrestrial ecosystem nutrient cycling. Trends in Ecology and Evolution, 2000, 15(6): 238-243.
[10] Mohamed A S A, Mori T, Islam S Q, et al. Lethal activity of gallo- and condensed tannins against the free-living soil-inhabiting nematode, Caenorhabditis elegans. Journal of Pesticide Science, 2000, 25(4): 410-415.
[11] Talbot J M, Allison S D, Treseder K K. Decomposers in disguise: Mycorrhizal fungi as regulators of soil C dynamics in ecosystems under global change. Functional Ecology, 2008, 22(6): 955-963.
[12] Ushio M, Balser T C, Kitayama K. Effects of condensed tannins in conifer leaves on the composition and activity of the soil microbial community in a tropical montane forest. Plant and Soil, 2013, 365(1/2): 157-170.
[13] Scalbert A. Antimicrobial properties of tannins. Phytochemistry, 1991, 30(12): 3875-3883.
[14] Joanisse G D, Bradley R L, Preston C M, et al. Soil enzyme inhibition by condensed litter tannins may drive ecosystem structure and processes: The case of Kalmia angustifolia. New Phytologist, 2007, 175(3): 535-546.
[15] Adamczyk B, Simon J, Kitunen V, et al. Tannins and their complex interaction with different organic nitrogen compounds and enzymes: Old paradigms versus recent advances. Chemistryopen, 2017, 6(5): 610-614.
[16] Serrano J, Puupponen-Pimia R, Dauer A, et al. Tannins: Current knowledge of food sources, intake, bioavailability and biological effects. Molecular Nutrition and Food Research, 2009, 53: 310-329.
[17] Bate-Smith E C, Swain T. Flavonoid compounds. New York: Academic Press, 1962: 755-809.
[18] Hernes P J, Benner R, Cowie G L, et al. Tannin diagenesis in mangrove leaves from a tropical estuary: A novel molecular approach. Geochimica Et Cosmochimica Acta, 2001, 65(18): 3109-3122.
[19] Galvez J M G, Riedl B, Conner A H. Analytical studies on tara tannins. Holzforschung, 1997, 51(3): 235-243.
[20] Ren F P, Gong Y Z, Wang Q J. The extraction method of vegetable tannin. West Leather, 2011, 33(20): 21-24.
任方萍, 宫云芝, 王全杰. 植物单宁的提取方法. 西部皮革, 2011, 33(20): 21-24.
[21] Smolander A, Kanerva S, Adamczyk B, et al. Nitrogen transformations in boreal forest soils-does composition of plant secondary compounds give any explanations? Plant and Soil, 2012, 350(1/2): 1-26.
[22] Cui G, Wei X, Degen A A, et al. Trolox-equivalent antioxidant capacity and composition of five alpine plant species growing at different elevations on the Qinghai-Tibetan Plateau. Plant Ecology and Diversity, 2016, 9(4): 387-396.
[23] Gonzalez-Hernandez M P, Karchesy J, Starkey E E. Research observation: Hydrolyzable and condensed tannins in plants of northwest Spain forests. Journal of Range Management, 2003, 56(5): 461-465.
[24] Keinanen M, Julkunen-Tiitto R, Mutikainen P, et al. Trade-offs in phenolic metabolism of silver birch: Effects of fertilization, defoliation, and genotype. Ecology, 1999, 80(6): 1970-1986.
[25] Kraus T E C, Zasoski R J, Dahlgren R A. Fertility and pH effects on polyphenol and condensed tannin concentrations in foliage and roots. Plant and Soil, 2004, 262(1/2): 95-109.
[26] Northup R R, Dahlgren R A, Yu Z S. Intraspecific variation of conifer phenolic concentration on a marine terrace soil acidity gradient-a new interpretation. Plant and Soil, 1995, 171(2): 255-262.
[27] Johnson J D, Tognetti R, Michelozzi M, et al. Ecophysiological responses of Fagus sylvatica seedlings to changing light conditions. Ⅱ. The interaction of light environment and soil fertility on seedling physiology. Physiologia Plantarum, 1997, 101(1): 124-134.
[28] Hagerman A E. The tannin handbook. (2011)[2019.10.11]. http://www.users.miamioh.edu/hagermae/.
[29] Chomel M, Guittonny-Larcheveque M, Fernandez C, et al. Plant secondary metabolites: A key driver of litter decomposition and soil nutrient cycling. Journal of Ecology, 2016, 104(6): 1527-1541.
[30] Maie N, Pisani O, Jaffe R. Mangrove tannins in aquatic ecosystems: Their fate and possible influence on dissolved organic carbon and nitrogen cycling. Limnology and Oceanography, 2008, 53(1): 160-171.
[31] Kandil F E, Grace M H, Seigler D S, et al. Polyphenolics in Rhizophora mangle L. leaves and their changes during leaf development and senescence. Trees-Structure and Function, 2004, 18(5): 518-528.
[32] Zhou H C, Tam N F, Lin Y M, et al. Changes of condensed tannins during decomposition of leaves of Kandelia obovata in a subtropical mangrove swamp in China. Soil Biology and Biochemistry, 2012, 44(1): 113-121.
[33] Carballo S M, Haas L, Krueger C G, et al. Cranberry proanthocyanidins-protein complexes for macrophage activation. Food and Function, 2017, 8(9): 3374-3382.
[34] Stevenson F J. Humus chemistry. New York: John Wiley and Sons, 1994: 496.
[35] Hagerman A E. Tannin-protein interactions. Acs Symposium Series, 1992, 506: 236-247.
[36] Ozdal T, Capanoglu E, Altay F. A review on protein-phenolic interactions and associated changes. Food Research International, 2013, 51(2): 954-970.
[37] Horvarth P J. The nutritional and ecological significance of Acer-tannins and related polyphenols. New York: Cornell University, 1981.
[38] Hagerman A E. Fifty years of polyphenol-protein complexes. Recent Advances in Polyphenol Research, 2012, 3: 71-97.
[39] Kraus T E C, Yu Z, Preston C M, et al. Linking chemical reactivity and protein precipitation to structural characteristics of foliar tannins. Journal of Chemical Ecology, 2003, 29(3): 703-730.
[40] Adamczyk B, Kitunen V, Smolander A. Protein precipitation by tannins in soil organic horizon and vegetation in relation to tree species. Biology and Fertility of Soils, 2008, 45(1): 55-64.
[41] Hagerman A E, Butler L G. The specificity of proanthocyanidin-protein interactions. Journal of Biological Chemistry, 1981, 256(9): 4494-4497.
[42] Ulrih N P. Analytical techniques for the study of polyphenol-protein interactions. Critical Reviews in Food Science and Nutrition, 2017, 57(10): 2144-2161.
[43] Adamczyk B, Kitunen V, Smolander A. Polyphenol oxidase, tannase and proteolytic activity in relation to tannin concentration in the soil organic horizon under silver birch and Norway spruce. Soil Biology and Biochemistry, 2009, 41(10): 2085-2093.
[44] Bending G D, Read D J. Effects of the soluble polyphenol tannic acid on the activities of ericoid and ectomycorrhizal fungi. Soil Biology and Biochemistry, 1996, 28(12): 1595-1602.
[45] Bennett J N, Prescott C F. Organic and inorganic nitrogen nutrition of western red cedar, western hemlock and salal in mineral N-limited cedar-hemlock forests. Oecologia, 2004, 141(3): 468-476.
[46] Wurzburger N, Hendrick R L. Plant litter chemistry and mycorrhizal roots promote a nitrogen feedback in a temperate forest. Journal of Ecology, 2009, 97(3): 528-536.
[47] Pellitier P T, Zak D R. Ectomycorrhizal fungi and the enzymatic liberation of nitrogen from soil organic matter: Why evolutionary history matters. New Phytologist, 2018, 217(1): 68-73.
[48] Joanisse G D, Bradley R L, Preston C M, et al. Sequestration of soil nitrogen as tannin-protein complexes may improve the competitive ability of sheep laurel (Kalmia angustifolia) relative to black spruce (Picea mariana). New Phytologist, 2009, 181(1): 187-198.
[49] Wu T H, Sharda J N, Koide R T. Exploring interactions between saprotrophic microbes and ectomycorrhizal fungi using a protein-tannin complex as an N source by red pine (Pinus resinosa). New Phytologist, 2003, 159(1): 131-139.
[50] Wu T, Kabir Z, Koide R T. A possible role for saprotrophic microfungi in the N nutrition of ectomycorrhizal Pinus resinosa. Soil Biology and Biochemistry, 2005, 37(5): 965-975.
[51] Kohler A, Kuo A, Nagy L G, et al. Convergent losses of decay mechanisms and rapid turnover of symbiosis genes in mycorrhizal mutualists. Nature Genetics, 2015, 47(4): 410-416.
[52] Adamczyk B, Adamczyk S, Smolander A, et al. Tannic acid and Norway spruce condensed tannins can precipitate various organic nitrogen compounds. Soil Biology and Biochemistry, 2011, 43(3): 628-637.
[53] Wu T. Can ectomycorrhizal fungi circumvent the nitrogen mineralization for plant nutrition in temperate forest ecosystems? Soil Biology and Biochemistry, 2011, 43(6): 1109-1117.
[54] Northup R R, Yu Z S, Dahlgren R A, et al. Polyphenol control of nitrogen release from pine litter. Nature, 1995, 377: 227-229.
[55] Schimel J P, Bennett J. Nitrogen mineralization: Challenges of a changing paradigm. Ecology, 2004, 85(3): 591-602.
[56] Fierer N, Schimel J P, Cates R G, et al. Influence of balsam poplar tannin fractions on carbon and nitrogen dynamics in Alaskan taiga floodplain soils. Soil Biology and Biochemistry, 2001, 33(12/13): 1827-1839.
[57] Schimel J P, Van Cleve K, Cates R G, et al. Effects of balsam poplar (Populus balsamifera) tannins and low molecular weight phenolics on microbial activity in taiga floodplain soil: Implications for changes in N cycling during succession. Canadian Journal of Botany-Revue Canadienne De Botanique, 1996, 74(1): 84-90.
[58] Kraus T E C, Zasoski R J, Dahlgren R A, et al. Carbon and nitrogen dynamics in a forest soil amended with purified tannins from different plant species. Soil Biology and Biochemistry, 2004, 36(2): 309-321.
[59] Hossain M Z, Okubo A, Sugiyama S. Effects of grassland species on decomposition of litter and soil microbial communities. Ecological Research, 2010, 25(2): 255-261.
[60] Bending G D, Read D J. Lignin and soluble phenolic degradation by ectomycorrhizal and ericoid mycorrhizal fungi. Mycological Research, 1997, 101: 1348-1354.
[61] Bhat T K, Singh B, Sharma O P. Microbial degradation of tannins-A current perspective. Biodegradation, 1998, 9(5): 343-357.
[62] Slapokas T, Granhall U. Decomposition of willow-leaf litter in a short-rotation forest in relation to fungal colonization and palatability for earthworms. Biology and Fertility of Soils, 1991, 10(4): 241-248.
[63] Tian G, Brussaard L, Kang B T. Breakdown of plant residues with contrasting chemical-compositions under humid tropical conditions-effects of earthworms and millipedes. Soil Biology and Biochemistry, 1995, 27(3): 277-280.
[64] Nannipieri P, Giagnoni L, Renella G, et al. Soil enzymology: Classical and molecular approaches. Biology and Fertility of Soils, 2012, 48(7): 743-762.
[65] Triebwasser D J, Tharayil N, Preston C M, et al. The susceptibility of soil enzymes to inhibition by leaf litter tannins is dependent on the tannin chemistry, enzyme class and vegetation history. New Phytologist, 2012, 196(4): 1122-1132.
[66] Zong W, Wang J, He Y, et al. Net nitrogen mineralization and enzyme activities in an alpine meadow soil amended with litter tannins. Journal of Plant Nutrition and Soil Science, 2018, 181(6): 954-965.
[67] Nierop K G J, Preston C M, Verstraten J M. Linking the B ring hydroxylation pattern of condensed tannins to C, N and P mineralization. A case study using four tannins. Soil Biology and Biochemistry, 2006, 38(9): 2794-2802.
[68] Adamczyk B, Karonen M, Adamczyk S, et al. Tannins can slow-down but also speed-up soil enzymatic activity in boreal forest. Soil Biology and Biochemistry, 2017, 107: 60-67.
[69] Juntheikki M R, Julkunen-Tiito R. Inhibition of β-glucosidase and esterase by tannins from Betula, Salix, and Pinus species. Journal of Chemical Ecology, 2000, 26(5): 1151-1165.
[70] Goldstein J L, Swain T. The inhibition of enzymes by tannins. Phytochemistry, 1965, 4(1): 185-192.
[71] Loranger G, Ponge J F, Imbert D, et al. Leaf decomposition in two semi-evergreen tropical forests: Influence of litter quality. Biology and Fertility of Soils, 2002, 35(4): 247-252.
[72] Hättenschwiler S, Jorgensen H B. Carbon quality rather than stoichiometry controls litter decomposition in a tropical rain forest. Journal of Ecology, 2010, 98(4): 754-763.
[73] Hättenschwiler S, Coq S, Barantal S, et al. Leaf traits and decomposition in tropical rainforests: Revisiting some commonly held views and towards a new hypothesis. New Phytologist, 2011, 189(4): 950-965.
[74] Bradley R L, Titus B D, Preston C P. Changes to mineral N cycling and microbial communities in black spruce humus after additions of (NH₄)₂SO₄ and condensed tannins extracted from Kalmia angustifolia and balsam fir. Soil Biology and Biochemistry, 2000, 32(8/9): 1227-1240.
[75] Baldwin I T, Olson R K, Reiners W A. Protien-binding phenolics and the inhibition of nitrification in subalpine balsam fir soils. Soil Biology and Biochemistry, 1983, 15(4): 419-423.
[76] Kraal P, Nierop K G J, Kaal J, et al. Carbon respiration and nitrogen dynamics in Corsican pine litter amended with aluminium and tannins. Soil Biology and Biochemistry, 2009, 41(11): 2318-2327.
[77] Schimel J P, Cates R G, Ruess R. The role of balsam poplar secondary chemicals in controlling soil nutrient dynamics through succession in the Alaskan Taiga. Biogeochemistry, 1998, 42(1/2): 221-234.
[78] Siqueira J O, Nair M G, Hammerschmidt R, et al. Significance of phenolic-compounds in plant-soil-microbial systems. Critical Reviews in Plant Sciences, 1991, 10(1): 63-121.
[79] Bending G D, Read D J. Nitrogen mobilization from protein-polyphenol complex by ericoid and ectomycorrhizal fungi. Soil Biology and Biochemistry, 1996, 28(12): 1603-1612.
[80] Holub S M, Lajtha K. The fate and retention of organic and inorganic ¹⁵N-nitrogen in an old-growth forest soil in western Oregon. Ecosystems, 2004, 7(4): 368-380.
[81] Mutabaruka R, Hairiah K, Cadisch G. Microbial degradation of hydrolysable and condensed tannin polyphenol-protein complexes in soils from different land-use histories. Soil Biology and Biochemistry, 2007, 39(7): 1479-1492.