Abstract
Plant-produced phenolic compounds inhibit soil microbial activity and are suspected to be involved in the failure of natural regeneration of French subalpine Norway spruce (Picea abies) forests. This work evaluated relationships between phenolic compounds and soil microorganisms in humus collected in spruce forest during winter and summer seasons. After having identified and quantified different phenolics from humus samples, we incubated another set of humus samples with 10 times the concentration of naturally occurring phenolics, and effects on the density of microorganisms were compared to humus with no addition of phenolic compounds. Furthermore, in order to follow the degradation of phenolic compounds by microbes, the concentration of phenolics in the incubated humus samples was determined by HPLC after three and six days of incubation. The results indicate that humus microorganisms use phenolics as a carbon source, since almost all phenolic compounds had disappeared after six days of incubation. Addition of phenolic compounds to the humus samples also affected the soil microbial populations so that bacteria were inhibited in the humus collected both in the winter and in the summer. However, there were differences between the experiments. Fungi and cellulose hydrolyzers were stimulated in the winter humus experiment, while fungi were unaffected and cellulose hydrolyzers were inhibited in the summer experiment. The addition of phenolic compounds stimulated ammonifiers in the summer experiment. We anticipate that the role of soil microorganisms in the problem of natural regeneration failure is probably more important than previously thought.
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REFERENCES
Alexander, M. 1982. Most probable number method for microbial populations, pp. 815–820, in A. L. Page, R. H. Miller, and D. R. Keeney (eds.). Methods of Soil Analysis, Part 2. Chemical and Microbiological Properties. 2nd ed. American Society of Agronomy Monograph 9, Madison, Wisconsin.
Alexander, M., and Clark, F. E. 1965. Nitrifying bacteria, pp. 1477–1483, in C. A. Black, D. D. Evans, J. L. White, L. E. Ensminger, and F. E. Clark (eds.). Methods of Soil Analysis, Part 2. American Society of Agronomy, Madison, Wisconsin.
AndrÉ, J., Gensac, P., Pellissier, F., and Trosset, L. 1987. Régénération des peuplements d'épicéa en altitude: Recherches préliminaires sur le rôle de l'allélopathie et de la mycorhization dans les premiers stades du développement. Rev. Ecol. Biol. Sol 24:301–310.
Barz, W., and Weltring, K.-M. 1981. Biodegradation of aromatic extractives of wood, pp. 608–666, in P. K. Stampf and E. E. Conn (eds.). The Biochemistry of Plants. A Comprehensive Treatise, Academic Press, New York.
Blum, U. 1995. The value of model plant-microbe-soil systems for understanding processes associated with allelopathic interaction. One example. ACS Symposium Series 582, Washington, D.C., pp. 127–131.
Blum, U. 1998. Effects of microbial utilization of phenolic acids and their phenolic acid breakdown products on allelopathic interactions. J. Chem. Ecol. 24:685–708.
Blum, U., and Shafer, S. R. 1988. Microbial populations and phenolic acids in soil. Soil Biol. Biochem. 20:793–800.
Boufalis, A., and Pellissier, F. 1994. Allelopathic effects of phenolic mixtures on respiration of two spruce mycorrhizal fungi. J. Chem. Ecol. 20:2283–2289.
Boufalis, A., Pellissier, F., and Trosset, L. 1994. Responses of mycorrhizal fungi to allelopathy: Cenococcum geophilum and Laccaria laccata growth with phenolic acids. Acta Bot. Gall. 141:547–550.
Brossier, J. 1977. Evolution des idées en matière forestière et conséquences sur la gestion des forêts alpines, Rev. For. Fr. Nancy 29:153–161.
Cheng, H. H. 1992. A conceptual framework for assessing allelochemicals in the soil environment, pp. 21–29, in S. J. H. Rizvi and V. Rizvi (eds.). Allelopathy: Basic and Applied Aspects, Chapman & Hall, London.
Clark, F. E. 1965. Agar-plate method for total microbial count, pp. 1460–1466, in C. A. Black, D. D. Evans, J. L. White, L. E. Ensminger, and F. E. Clark (eds.). Methods of Soil Analysis, Part 2. American Society of Agronomy, Madison, Wisconsin.
Duchaufour, P. 1953. Régénération de l'épicéa et pédologie. Rev. For. Fr. Nancy 4:257–268.
Eggins, H. O. W., and Pugh, G. J. F. 1962. Isolation of cellulose decomposing fungi from the soil. Nature 193:94–95.
Fisher, R. F. 1987. Allelopathy: A potential cause of forest regeneration failure, pp. 176–184, in G. R. Waller (ed.). Allelochemicals: Role in Agriculture and Forestry. American Chemical Society, Washington D.C.
Focht, D. D., and Joseph, H. 1973. An improved method for the enumeration of denitrifying bacteria. Soil Sci. Soc. Am. Proc. 37:698–699.
Gallet, C. 1994. Allelopathic potential in bilberry-spruce forests: Influence of phenolic compounds on spruce seedlings. J. Chem. Ecol. 20:1009–1024.
Gallet, C., and Pellissier, F. 1997. Phenolic compounds in natural solutions of a coniferous forest. J. Chem. Ecol. 23:2401–2412.
Inderjit and Dakshini, K. M. M. 1995. On laboratory bioassays in allelopathy. Bot. Rev. 61:28–44.
Kuiters, A. T. 1990. Role of phenolic substances from decomposing forest litter in plant-soil interactions. Acta Bot. Neerl. 39:329–348.
Kuiters, L. 1987. Phenolic Acids and Plant Growth in Forest Ecosystems. PhD dissertation. Free University, Amsterdam.
Lehman, M. E., Blum, U., and Gerig, T. M. 1994. Simultaneous effects of ferulic and p-coumaric acids on cucumber leaf expansion in split-root experiments. J. Chem. Ecol. 20:1773–1782.
LI, H. H., INOUE, M., NISHIMURA, H., MIZUTANI, J., and TSUZUKI, E. 1993. Interactions of transcinnamic acid, its related phenolic allelochemicals, and abscisic acid in seedling growth and seed germination of lettuce. J. Chem. Ecol. 19:1775–1787.
Lodhi, M. A. K., and Killingbeck, K. T. 1980. Allelopathic inhibition of nitrification and nitrifying bacteria in a ponderosa pine (Pinus ponderosa Dougl.) community. Am. J. Bot. 67:1423–1429.
Mallik, A. U. 1992. Possible role of allelopathy in growth inhibition of softwood seedlings in Newfoundland, pp. 321–340, in S. J. H. Rizvi and V. Rizvi (eds.). Allelopathy: Basic and Applied Aspects. Chapman & Hall, London.
Mccarty, G. W., and Bremner, J. M. 1986. Effects of phenolic compounds on nitrification in soil. Soil Sci. Soc. Am. J. 50:920–923.
Olson, R. A., and Reiners, W. A. 1983. Nitrification in subalpine balsam fir soils: Tests for inhibitory factors. Soil Biol. Biochem. 15:413–418.
Paquin, R., Margolis, H., and Doucet, R. 1998. Nutrient status and growth of black spruce layers and planted seedlings in response to nutrient addition in the boreal forest of Quebec. Can. J. For. Res. 28(5):729–736.
Parkinson, D., Gray, T. R. G., and Williams, S. T. 1971. Methods for Studying the Ecology of Soil Microorganisms, IBP Handbook 19. Blackwell Sci. Publ., Oxford.
Pellissier, F. 1993. Allelopathic effect of phenolic acids from humic solutions on two spruce mycorrhizal fungi: Cenococcum graniforme and Laccaria laccata. J. Chem. Ecol. 19:2105–2114.
Pellissier, F. 1994. Effects of phenolic compounds in humus on the natural regeneration of spruce. Phytochemistry 36:865–867.
Pochon, J., and Tardieux, P. 1962. Techniques d'analyse en microbiologie du sol. La Tourelle, St. Mandé.
Pue, K. J., Blum, U., Gerig, T. M., and Shafer, S. R. 1995. Mechanisms by which noninhibitory concentrations of glucose increase inhibitory activity of p-coumaric acid on morning-glory seedling biomass accumulation. J. Chem. Ecol. 21:833–847.
Reigosa, M. J., Souto, X. C., and GonzÁlez, L. 1996. Allelopathic research: Methodological, ecological and evolutionary aspects, pp. 213–231, in S. S. Narwal and P. Tauro (eds.). Allelopathy: Field Observations and Methodology, Scientific Publishers, Jodhpur, India.
Rice, E. L. 1984. Allelopathy. Academic Press, Orlando, Florida.
Rice, E. L., and Pancholy, S. K. 1972. Inhibition of nitrification by climax ecosystems. Am. J. Bot. 59:1033–1040.
Roques, A., and Trosset, L. 1986. Analyse de la distribution altitudinale des insectes ravageurs des cônes d'épicéa (Picea abies (L.) Karst.) dans les Alpes françaises du Nord, pp. 83–90, in Proceedings of the Second Conference on the Cone and Seed Insects, Besançon.
Schaeffer, A. 1911. Régénération de l'épicéa dans les forêts des Hautes Régions, Bull. Trimest. Soc. For. Franche-Comté et Belfort 11:292–300.
Schimel, J. P., Van Cleve, K., Cates, R. G., Clausen, T. P., and Reichardt, P. B. 1996. 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. Can. J. Bot. 74:84–90.
Schimel, J. P., Cates, R., and Ruess, R. 1998. The role of balsam poplar secondary chemicals in controlling soil nutrient dynamics through succession in the Alaskan taiga. Biogeochemistry 42(1–2):221–234.
Souto, X. C. 1997. Fenómenos Alelopáticos de Especies Arbóreas sobre Plantas del Sotobosque. Un Estudio Comparativo. Ph.D. dissertation. University of Vigo, Pontevedra, Spain.
Statsoft France. 1996. Statistica pour Windows (Manuel de Programmation). StatSoft France. Immeuble Vénus. 2, Parc Ariane. 78284 Guyancourt Cedex, France.
Stienstra, A. W., Gunnewiek, P. K., and Laanbroek, H. J. 1994. Repression of nitrification in soils under a climax grassland vegetation. FEMS Microbiol. Ecol. 14:45–52.
Sugai, S. F., and Schimel, J. P. 1993. Decomposition and biomass incorporation of 14C-labeled glucose and phenolics in taiga forest floor: Effects of substrate quality, successional state, and season. Soil Biol. Biochem. 25:1379–1389.
Wollum, A. G. 1982. Cultural methods for soil microorganisms, pp. 781–802, in A. L. Page, R. H. Miller, and D. R. Keeney (eds.). Methods of Soil Analysis, Part 2. Chemical and Microbiological Properties, 2nd ed. American Society of Agronomy Monograph 9, Madison, Wisconsin.
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Souto, X.C., Chiapusio, G. & Pellissier, F. Relationships Between Phenolics and Soil Microorganisms in Spruce Forests: Significance for Natural Regeneration. J Chem Ecol 26, 2025–2034 (2000). https://doi.org/10.1023/A:1005504029243
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DOI: https://doi.org/10.1023/A:1005504029243