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Plant Ecology

, Volume 220, Issue 4–5, pp 441–456 | Cite as

Soluble phenolics extracted from Larrea divaricata leaves modulate soil microbial activity and perennial grass establishment in arid ecosystems of the Patagonian Monte, Argentina

  • L. Segesso
  • A. L. CarreraEmail author
  • M. B. Bertiller
  • H. Saraví Cisneros
Article
  • 31 Downloads

Abstract

Sheep grazing induces the reduction of perennial grass cover and the increase of shrub cover with high concentration of chemical defences. We analysed the effects of secondary metabolites released from green and senesced leaves of the shrub Larrea divaricata on soil microbial activity and the establishment of perennial grasses in arid ecosystems of the Patagonian Monte. We carried out microcosm experiments with soil from plant patches without and with L. divaricata and inert substrate seeded with the perennial grasses Poa ligularis and Nassella tenuis, which are characteristic of the Patagonian Monte. Microcosms were subjected to three watering treatments: distilled water and aqueous extracts of green and senesced leaves of L. divaricata with high concentration of soluble phenolics. We assessed the microbial N-flush and net-N mineralization in soil, and seed germination, survival, and biomass of both perennial grass species. Aqueous leaf extracts led to a 29% increase in microbial N-flush and a 20% reduction in the net-N mineralization. Seed germination was less negatively affected by aqueous leaf extracts in P. ligularis ( < 18% reduction) than in N. tenuis (2–69% reduction). Survival of P. ligularis was not affected by aqueous leaf extracts while that of N. tenuis was 21–45% reduced only in the soil from plant patches without L. divaricata. Biomass accumulation of both perennial grass species was negatively affected by aqueous extracts of senesced leaves. We concluded that soluble metabolites extracted from L. divaricata may have positive or negative effects on microbial activity and potential allelopathic effects on perennial grass regeneration depending on species.

Keywords

Nassella tenuis Plant–plant interaction Plant–soil interaction Poa ligularis Shrubs 

Notes

Acknowledgements

We thank the editor Christina Birnbaum and two anonymous reviewers of this manuscript for their valuable comments. This work was supported by the National Agency for Scientific, Technological Promotion (PICTs 1349, 1368, 2074) and the National Research Council of Argentina (PIPs 112–200801-01664 and 112–201301-00449- CONICET). This paper was written within the framework of PUE-IPEEC-2016 22920160100044. Samples processing and chemical analyses were performed in the Laboratorio de Ecología de Pastizales (LAEPA-IPEEC-CONICET).

Supplementary material

11258_2019_926_MOESM1_ESM.doc (109 kb)
Supplementary file1 (DOC 109 kb)

References

  1. Adamczyk B, Adamczyk S, Smolander A, Kitunen V (2011) Tannic acid and Norway spruce condensed tannins can precipitate various organic nitrogen compounds. Soil Biol Biochem 43:628–637.  https://doi.org/10.1016/j.soilbio.2010.11.034 CrossRefGoogle Scholar
  2. Adler PB, Raff DA, Lauenroth WK (2001) The effect of grazing on the spatial heterogeneity of vegetation. Oecologia 128:465–479.  https://doi.org/10.1007/s004420100737 CrossRefGoogle Scholar
  3. Aerts R, Chapin FS (2000) The mineral nutrition of wild plants revisited: a re-evaluation of processes and patterns. Adv Ecol Res 30:1–67.  https://doi.org/10.1016/S0065-2504(08)60016-1 Google Scholar
  4. Alonso J, Desmarchelier C (2015) Plantas Medicinales Autóctonas de la Argentina. Bases Científicas para su Aplicación en Atención Primaria de la Salud, CABA, Corpus Libros Médicos y CientíficosGoogle Scholar
  5. Alvarez LJ, Epstein HE, Li J, Okin GS (2011) Spatial patterns of grasses and shrubs in an arid grassland environment. Ecosphere 2:103.  https://doi.org/10.1890/ES11-00104.1 CrossRefGoogle Scholar
  6. Anesini C, Ferraro G, Borda E (1997) A phytochemical bioguided study of an aqueous extract of Larrea divaricata. WOC-MAP II Acta p372. Mendoza, ArgentinaGoogle Scholar
  7. Aniszewski T (2015) Alkaloids: chemistry, biology, ecology, and applications. Elsevier, AmsterdamGoogle Scholar
  8. Appel HM (1993) Phenolics in ecological interactions: the importance of oxidation. J Chem Ecol 19:521–552CrossRefGoogle Scholar
  9. Austin AT, Ballaré CL (2014) Plant interactions with other organisms: molecules, ecology and evolution. New Phytol 204:257–260.  https://doi.org/10.1111/nph.13062 CrossRefGoogle Scholar
  10. Baker NR, Allison SD (2015) Ultraviolet photodegradation facilitates microbial litter decomposition in a Mediterranean climate. Ecology 96:1994–2003.  https://doi.org/10.1890/14-1482.1 CrossRefGoogle Scholar
  11. Bär Lamas MI, Larreguy C, Carrera AL, Bertiller MB (2013) Changes in plant cover and functional traits induced by grazing disturbance in arid rangelands. Acta Oecol 51:66–73.  https://doi.org/10.1016/j.actao.2013.06.002 CrossRefGoogle Scholar
  12. Bär Lamas MI, Carrera AL, Bertiller MB (2016) Meaningful traits for grouping plant species across arid ecosystems. J Plant Res 129:449–461.  https://doi.org/10.1007/s10265-016-0803-6 CrossRefGoogle Scholar
  13. Bertiller MB, Bisigato AJ (1998) Vegetation dynamics under grazing disturbance. The state -and- transition model for the Patagonian steppes. Ecol Aust 8:191–199Google Scholar
  14. Bertiller MB, Sain CL, Bisigato AJ, Coronato FR, Ares JO, Graff P (2002) Spatial sex segregation in the dioecious grass Poa ligularis in northern Patagonia: the role of environmental patchiness. Biodivers Conserv 11:69–84.  https://doi.org/10.1023/A:1014084024145 CrossRefGoogle Scholar
  15. Bertiller MB, Mazzarino MJ, Carrera AL, Diehl P, Satti P, Gobbi M, Sain CL (2006) Leaf strategies and soil N across a regional humidity gradient in Patagonia. Oecologia 148:612–624.  https://doi.org/10.1007/s00442-006-0401-8 CrossRefGoogle Scholar
  16. Bhark EW, Small EE (2003) Association between plant canopies and the spatial patterns of infiltration in shrubland and grassland of the Chihuahuan desert, New Mexico. Ecosystems 6:185–196.  https://doi.org/10.1007/s10021-002-0210-9 CrossRefGoogle Scholar
  17. Bisigato AJ, Bertiller MB (1997) Grazing effects on patchy dryland vegetation in northern Patagonia. J Arid Environ 36:639–653.  https://doi.org/10.1006/jare.1996.0247 CrossRefGoogle Scholar
  18. Bosco T, Bertiller MB, Carrera AL (2016) Combined effects of litter features, UV radiation, and soil water on litter decomposition in denuded areas of the arid Patagonian Monte. Plant Soil 406:71–82.  https://doi.org/10.1007/s11104-016-2864-7 CrossRefGoogle Scholar
  19. Bradley RL, Fyles JW, Titus B (1997) Interactions between Kalmia humus quality and chronic low C inputs in controlling microbial and soil nutrient dynamics. Soil Biol Biochem 29:1275–1283.  https://doi.org/10.1016/S0038-0717(97)00018-7 CrossRefGoogle Scholar
  20. Burke IC, Lauenroth WK, Riggle R, Brannen P, Medigan B, Beard S (1999) Spatial variability of soil properties in the Shortgrass steppe: the relative importance of topography, grazing, microsite, and plant species in controlling spatial patterns. Ecosystems 2:422–438.  https://doi.org/10.1007/s100219900091 CrossRefGoogle Scholar
  21. Campanella MV, Bertiller MB (2008) Plant phenology, leaf traits, and leaf litterfall of contrasting life forms in arid Patagonian Monte, Argentina. J Veg Sci 19:75–85.  https://doi.org/10.3170/2007-8-18333 CrossRefGoogle Scholar
  22. Carrera AL, Sain CL, Bertiller MB (2000) Patterns of nitrogen conservation in shrubs and grasses in the Patagonian Monte, Argentina. Plant Soil 224:185–193.  https://doi.org/10.1023/A:1004841917272 CrossRefGoogle Scholar
  23. Carrera AL, Bertiller MB, Sain CL, Mazzarino MJ (2003) Relationship between plant nitrogen conservation strategies and the dynamics of soil nitrogen in the arid Patagonian Monte, Argentina. Plant Soil 255:595–604.  https://doi.org/10.1023/A:1026087419155 CrossRefGoogle Scholar
  24. Carrera AL, Vargas DN, Campanella MV, Bertiller MB, Sain CL, Mazzarino MJ (2005) Soil nitrogen in relation to quality and decomposability of plant litter in the Patagonian Monte, Argentina. Plant Ecol 181:139–151.  https://doi.org/10.1007/s11258-005-5322-9 CrossRefGoogle Scholar
  25. Carrera AL, Bertiller MB, Larreguy C (2008) Leaf litterfall, fine-root production, and decomposition in shrublands with different canopy structure induced by grazing in the Patagonian Monte, Argentina. Plant Soil 311:39–50.  https://doi.org/10.1007/s11104-008-9655-8 CrossRefGoogle Scholar
  26. Carrera AL, Mazzarino MJ, Bertiller MB, del Valle HF, Carretero EM (2009) Plant impacts on nitrogen and carbon cycling in the Monte Phytogeographical Province. Argentina. J. Arid Environ. 73:192–201.  https://doi.org/10.1016/j.jaridenv.2008.09.016 CrossRefGoogle Scholar
  27. Castaldi S, Carfora A, Fiorentino A, Natale A, Messere A, Miglietta F, Cotrufo MF (2009) Inhibition of net nitrification activity in a Mediterranean woodland: possible role of chemicals produced by Arbutus unedo. Plant Soil 315:273–283.  https://doi.org/10.1007/s11104-008-9750-x CrossRefGoogle Scholar
  28. Castells E (2008) Indirect effects of phenolics on plant performance by altering nitrogen cycling: another example of plant-plant negative interactions. In: Zeng R, Mallik AU, Luo SM (eds) Allelopathy in sustainable agriculture and forestry. Springer, New York, pp 137–156CrossRefGoogle Scholar
  29. Castells E, Peñuelas J, Valentine DW (2003) Influence of the phenolic compound bearing species Ledum palustre on soil N cycling in a boreal hardwood forest. Plant Soil 251:155–166.  https://doi.org/10.1023/A:1022923114577 CrossRefGoogle Scholar
  30. Castells E, Peñuelas J, Valentine DW (2004) Are phenolic compounds released from the Mediterranean shrub Cistus albidus responsible for changes in N cycling in siliceous and calcareous soils? New Phytol 162:187–195.  https://doi.org/10.1111/j.1469-8137.2004.01021.x CrossRefGoogle Scholar
  31. Castells E, Peñuelas J, Valentine DW (2005) Effects of plant leachates from four Boreal understory species on soil N cycling mineralization, and white spruce (Picea glauca) germination and seedling growth. Ann Bot 95:1247–1252.  https://doi.org/10.1093/aob/mci139 CrossRefGoogle Scholar
  32. Centro Nacional Patagónico (2009) Unidad de Investigación de Oceanografía y Meteorología http://www.cenpat.edu.ar. Accessed 23 Oct 2012Google Scholar
  33. Chesson P, Gebauer RL, Schwinning S, Huntly N, Wiegand K, Ernest MSK, Sher A, Novoplansky A, Weltzin JF (2004) Resource pulses, species interactions, and diversity maintenance in arid and semiarid environments. Oecologia 141:236–253.  https://doi.org/10.1007/s00442-004-1551-1 CrossRefGoogle Scholar
  34. Chou CH (2006) Introduction to allelopathy. In: Reigosa MJ, Pedrol N, González L (eds) Allelopathy: a physiological process with ecological implications. Springer, New York, pp 1–9Google Scholar
  35. Coombs J, Hind G, Leegood RC, Tienszen LL, Vonshsk A (1985) Analytical techniques. In: Coombs J, Hall DO, Long SP, Scurlock JMO (eds) Techniques in bioproductivity and photosyntesis. Pergamon Press, Oxford, pp 219–228CrossRefGoogle Scholar
  36. Coronato FR, Bertiller MB (1997) Climatic controls of soil moisture dynamics in an arid steppe of northern Patagonia. Argentina. Arid. Soil Res. Rehabil. 11:277–288.  https://doi.org/10.1080/15324989709381479 CrossRefGoogle Scholar
  37. da Silva DM, Batalha MB (2011) Defense syndromes against herbivory in a cerrado plant community. Plant Ecol 212:181–193.  https://doi.org/10.1007/s11258-010-9813-y CrossRefGoogle Scholar
  38. del Valle HF (1998) Patagonian soils: a regional synthesis. Ecol Aust 8:103–123Google Scholar
  39. Díaz S, Hodgson JG, Thompson K et al (2004) The plant traits that drive ecosystems: evidence from three continents. J Veg Sci 15:295–304.  https://doi.org/10.1658/1100-9233 CrossRefGoogle Scholar
  40. Díaz S, Lavorel S, de Bello F, Quétier F, Grigulis K, Robson TM (2007) Incorporating plant functional diversity effects in ecosystem service assessments. PNAS 104:20684–20689.  https://doi.org/10.1073/pnas.0704716104 CrossRefGoogle Scholar
  41. Gallo ME, Porras-Alfaro A, Odenbach KJ, Sinsabaugh RL (2009) Photoacceleration of plant litter decomposition in an arid environment. Soil Biol Biochem 41:1433–1441.  https://doi.org/10.1016/j.soilbio.2009.03.025 CrossRefGoogle Scholar
  42. Harborne JB (1984) Phytochemical methods. A guide to modern techniques of plant analysis, Chapman and Hall, LondonCrossRefGoogle Scholar
  43. Hashoum H, Santonja M, Gauquelin T, Saatkamp A, Gavinet J, Greff S, Lecareux C, Fernandez C, Bousquet-Mélou A (2017) Biotic interactions in a Mediterranean oak forest: role of allelopathy along phenological development of woody species. Eur J Forest Res 136:699–710.  https://doi.org/10.1007/s10342-017-1066-z CrossRefGoogle Scholar
  44. Hättenschwiler S, Vitousek PM (2000) The role of polyphenols in terrestrial ecosystem nutrient cycling. Trends Ecol Ev 15:238–243.  https://doi.org/10.1016/S0169-5347(00)01861-9 CrossRefGoogle Scholar
  45. Holzapfel C, Tielbörger K, Parag HA, Kigel J, Sternberg M (2006) Annual plant–shrub interactions along an aridity gradient. Basic Appl Ecol 7:268–279.  https://doi.org/10.1016/j.baae.2005.08.003 CrossRefGoogle Scholar
  46. Horwarth WR, Paul EA (1994) Microbial biomass. In: Weaver RA, Angle S, Bottomley P et al (eds) Methods of Soil Analysis 2. Soil Science Society of America, Madison, Wisc, Microbiological and Biochemical Properties, pp 753–773Google Scholar
  47. Inderjit (2005) Soil microorganisms: an important determinant of allelopathic activity. Plant Soil 274:227–236.  https://doi.org/10.1007/s11104-004-0159-x CrossRefGoogle Scholar
  48. Inderjit, Weiner J (2001) Plant allelochemical interference or soil chemical ecology? PPEES 4:3–12.  https://doi.org/10.1078/1433-8319-00011 Google Scholar
  49. Inderjit, van der Putten WH (2010) Impacts of soil microbial communities on exotic plant invasions. Trends Ecol Ev 25:512–519.  https://doi.org/10.1016/j.tree.2010.06.006 CrossRefGoogle Scholar
  50. Lambers H, Chapin FS, Pons TL (2000) Plant physiological ecology. Springer, New YorkGoogle Scholar
  51. Larreguy C, Carrera AL, Bertiller MB (2014) Effects of long-term grazing disturbance on the belowground storage of organic carbon in the Patagonian Monte, Argentina. J Environ Manage 134:47–55.  https://doi.org/10.1016/j.jenvman.2013.12.024 CrossRefGoogle Scholar
  52. Leather GR, Einhellig FA (1988) Bioassay of naturally occurring allelochemicals for toxicity. J Chem Ecol 14:1821–1828.  https://doi.org/10.1007/BF01013479 CrossRefGoogle Scholar
  53. León RJC, Bran D, Collantes M, Paruelo JM, Soriano A (1998) Grandes unidades de vegetación de la Patagonia extra andina. Ecol Aust 8:125–144Google Scholar
  54. Li ZH, Wang Q, Ruan X, Pan CD, Jiang DA (2010) Phenolics and plant allelopathy. Molecules 15:8933–8952.  https://doi.org/10.3390/molecules15128933 CrossRefGoogle Scholar
  55. Lin Y, King JY (2014) Effects of UV exposure and litter position on decomposition in a California grassland. Ecosystems 17:158–168.  https://doi.org/10.1007/s10021-013-9712-x CrossRefGoogle Scholar
  56. Loydi A, Donath TW, Eckstein RL, Otte A (2015) Non-native species litter reduces germination and growth of resident forbs and grasses: allelopathic, osmotic or mechanical effects? Biol Invasions 17:581–595.  https://doi.org/10.1007/s10530-014-0750-x CrossRefGoogle Scholar
  57. López RP, Larrea-Alcázar DM, Ortuño T (2009) Positive effects of shrubs on herbaceous species richness across several spatial scales: evidence from the semiarid Andean subtropics. J Veg Sci 20:728–734.  https://doi.org/10.1111/j.1654-1103.2009.01067.x CrossRefGoogle Scholar
  58. Lorenzo P, Pereira CF, Rodríguez-Echeverría S (2013) Differential impact on soil microbes of allelopathic compounds released by the invasive Acacia dealbata Link. Soil Biol Biochem 57:156–163.  https://doi.org/10.1016/j.soilbio.2012.08.018 CrossRefGoogle Scholar
  59. Mazzarino MJ, Bertiller MB, Sain CL, Laos F, Coronato FR (1996) Spatial patterns of nitrogen availability, mineralization and immobilization in northern Patagonia, Argentina. Arid Soil Res Rehab 10:295–309.  https://doi.org/10.1080/15324989609381445 CrossRefGoogle Scholar
  60. McCullagh P, Nelder JA (1989) Generalized Linear Models. Chapman and Hall, LondonCrossRefGoogle Scholar
  61. Moreno L, Bertiller MB, Carrera AL (2010) Changes in traits of shrub canopies across an aridity gradient in northern Patagonia, Argentina. Basic Appl Ecol 11:693–701.  https://doi.org/10.1016/j.baae.2010.09.002 CrossRefGoogle Scholar
  62. Muscolo A, Sidari M (2006) Seasonal fluctuations in soil phenolics of a coniferous forest: effects on seed germination of different coniferous species. Plant Soil 284:305–318.  https://doi.org/10.1007/s11104-006-0040-1 CrossRefGoogle Scholar
  63. Muscolo A, Panuccio MR, Sidari M (2001) Respiratory enzyme activities during germination of Pinus laricio seeds treated with phenols extracted from different forest soils. Plant Growth Regul 35:31–35.  https://doi.org/10.1023/A:1013897321852 CrossRefGoogle Scholar
  64. Noy Meir I (1973) Desert ecosystems: environment and producers. Ann Rev Ecol Sys 4:25–52.  https://doi.org/10.1146/annurev.es.04.110173.000325 CrossRefGoogle Scholar
  65. Page AL, Niller RH, Keeney DR (1982) Methods of soil analysis. Chemical and microbiological properties, Madison, USAGoogle Scholar
  66. Pazos GE, Bisigato AJ, Bertiller MB (2007) Abundance and spatial patterning of coexisting perennial grasses in grazed shrublands of the Patagonian Monte. J Arid Environ 70:316–328.  https://doi.org/10.1016/j.jaridenv.2006.12.025 CrossRefGoogle Scholar
  67. Prieto LH, Bertiller MB, Carrera AL, Olivera NL (2011) Soil enzyme and microbial activities in a grazing ecosystem of Patagonian Monte, Argentina. Geoderma 162:281–287.  https://doi.org/10.1016/j.geoderma.2011.02.011 CrossRefGoogle Scholar
  68. Pugnaire FI, Luque MT (2001) Changes in plant interactions along a gradient of environmental stress. Oikos 93:42–49.  https://doi.org/10.1034/j.1600-0706.2001.930104.x CrossRefGoogle Scholar
  69. Reigosa MJ, Pedrol N, González L (2006) Allelopathy: a physiological process with ecological implications. Springer, New YorkCrossRefGoogle Scholar
  70. Riginos C, Milton SJ, Wiegand T (2005) Context-dependent interactions between adult shrubs and seedlings in a semi-arid shrubland. J Veg Sci 16:331–340.  https://doi.org/10.1111/j.1654-1103.2005.tb02371.x CrossRefGoogle Scholar
  71. Sala OE, Golluscio RA, Lauenroth WK, Soriano A (1989) Resource partitioning between shrubs and grasses in the Patagonian steppe. Oecologia 81:501–505.  https://doi.org/10.1007/BF00378959 CrossRefGoogle Scholar
  72. Saraví Cisneros H, Bertiller MB, Carrera AL, Larreguy C (2013) Diversity of phenolic compounds and plant traits in coexisting Patagonian desert shrub species of Argentina. Plant Ecol 214:1335–1343.  https://doi.org/10.1007/s11258-013-0255-1 CrossRefGoogle Scholar
  73. Segesso L. 2011. Efecto de los lixiviados de Larrea divaricata sobre la actividad de los microorganismos en el suelo y la germinación y crecimiento de pastos perennes del Monte austral. Tesis de Licenciatura en Ciencias Biológicas-UNPSJBGoogle Scholar
  74. Seigler DS (2006) Basic pathways for the origin of allelopathic compounds. In: Reigosa MJ, Pedrol N, González L (eds) Allelopathy: a physiological process with ecological implications. Springer, New York, pp 11–61CrossRefGoogle Scholar
  75. Soil Survey Staff (1998) Keys to soil taxonomy. USDA, Washington, DCGoogle Scholar
  76. Sugai SF, Schimel JP (1993) Decomposition and biomass incorporation of 14C-labeled glucose and phenolics in taiga forest floor: effect of substrate quality, successional state, and season. Soil Biol Biochem 25:1379–1389.  https://doi.org/10.1016/0038-0717(93)90052-D CrossRefGoogle Scholar
  77. Tielbörger K, Kadmon R (2000) Indirect effects in a desert plant community: is competition among annuals more intense under shrub canopies? Plant Ecol 150:53–63.  https://doi.org/10.1023/A:1026541428547 CrossRefGoogle Scholar
  78. Velásquez Barloa N (2007) Extractos acuosos de jarilla (Larrea cuneifolia) ¿Tienen propiedades alelopáticas?. Seminario de Licenciatura en Ciencias Biológicas. Fac, Química, Bioquímica y Farmacia-UNSLGoogle Scholar
  79. Vesk PA, Westoby M (2001) Predicting plant species’ responses to grazing. J Appl Ecol 38:897–909.  https://doi.org/10.1046/j.1365-2664.2001.00646.x CrossRefGoogle Scholar
  80. Violle C, Navas ML, Vile D, Kazakou E, Fortunel C, Hummel I, Garnier E (2007) Let the concept of trait be functional! Oikos 116:882–892.  https://doi.org/10.1111/j.0030-1299.2007.15559.x CrossRefGoogle Scholar
  81. Wardle DA, Nilsson MC (1997) Microbe-plant competition, allelopathy and arctic plants. Oecologia 109:291–293.  https://doi.org/10.1007/s004420050086 CrossRefGoogle Scholar
  82. Waterman PG, Mole S (1994) Methods in ecology. Analysis of phenolics plant metabolites, Blackwell, New YorkGoogle Scholar
  83. Whitford W (2002) Ecology of Desert Systems. Academic Press, San Diego, CAGoogle Scholar
  84. Wilby A, Sachak M (2004) Shrubs, granivores and annual plant community stability in an arid ecosystem. Oikos 106:209–216.  https://doi.org/10.1111/j.0030-1299.2004.13085.x CrossRefGoogle Scholar
  85. Wink M, Latz-Brüning B, Schmeller T (1999). Biochemical effects of allelopathic alkaloids. In: Inderjit, Dakshini KMM, Foy CL (eds) Principles and practices in plant ecology: allelochemical interactions Boca Raton, CRC Press. pp. 41–422Google Scholar
  86. Yu JQ, Matsui Y (1997) Effects of root exudates of cucumber (Cucumis sativus) and allelochemicals on ion uptake by cucumber seedling. J Chem Ecol 23:817–827.  https://doi.org/10.1023/B:JOEC.0000006413.98507.55 CrossRefGoogle Scholar
  87. Zhou YH, Yu JQ (2006) Allelochemicals and photosynthesis. In: Reigosa MJ, Pedrol N, González L (eds) Allelopathy: a physiological process with ecological implications. Springer, New York, pp 127–139CrossRefGoogle Scholar

Copyright information

© Springer Nature B.V. 2019

Authors and Affiliations

  • L. Segesso
    • 1
  • A. L. Carrera
    • 1
    • 2
    Email author
  • M. B. Bertiller
    • 1
    • 2
  • H. Saraví Cisneros
    • 2
  1. 1.Universidad Nacional de la Patagonia San Juan Bosco (UNPSJB)Puerto MadrynArgentina
  2. 2.Instituto Patagónico para el Estudio de los Ecosistemas Continentales (IPEEC)–CONICETPuerto MadrynArgentina

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