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Plant-soil feedbacks in community ecology
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- 1College of Forestry, Hainan University, Haikou 570228, China
2Ministry of Education Key Laboratory for Biodiversity Science and Ecological Engineering, Beijing 100875, China
3Key Laboratory of the Ministry of Education for Coastal and Wetland Ecosystems, College of the Environment and Ecology, Xiamen University, Xiamen, Fujian 361102, China
Received date: 2009-01-12
Accepted date: 2009-06-03
Online published: 2022-08-14
Supported by
National Natural Science Foundation of China(31600342)
Abstract
Plant species change soil abiotic and biotic properties which in turn influence the performance of plants, leading to so-called “plant-soil feedbacks” (PSF). It is the prerequisite of plant-soil feedbacks that plant species can cause specific changes in soil microbial communities which are characterized by specialized soil pathogens and mutualists. Specialized microbes can have substantial effects on host plants, but likely do not influence the performance of non-host plants. PSF have been used to interpret ecological processes of different scales since the concept was proposed in the 1990s, such as succession, interspecific competition, biological invasion and effects of global changes on terrestrial ecosystems. In recent years, community ecologists and theoretical ecologists have started to integrate the research of PSF and community ecology, resulting in fundamental progress. In this review paper, we introduce soil microbe-mediated PSF and its implications for plant species coexistence, community structure and ecosystem functions. Classical PSF theory assumes that soil microbes can generate stabilizing process which promotes plant coexistence. However, recent studies show that soil microbes can also cause fitness difference between plant species which can influence species coexistence through equalizing process. Community ecologists predict that rare species have less negative or more positive PSF than abundant species, thereby leading to negative correlations between plant landscape abundance and PSF. However, empirical evidence demonstrates inconsistent patterns such as negative, positive and neutral correlations, and coevolution of plants and soil pathogens is key to reconcile these patterns. Soil microbes are also considered as a fundamental factor regulating succession. Dilution of soil microbial effects is a mechanism of positive plant diversity-productivity relationships. Specialist pathogens and mutualists accumulate in the soil of monocultures, but their negative and positive effects are diluted in multi-species mixtures, thereby increasing and decreasing biodiversity effects on productivity, respectively. We suggest three directions for future studies: empirical testing for specialization of plants and soil microbes, multi-dimensional species coexistence and eco-evolutionary dynamics in plant-soil feedbacks.
Cite this article
XI Nian-Xun, ZHANG Yuan-Ye, ZHOU Shu-Rong . Plant-soil feedbacks in community ecology[J]. Chinese Journal of Plant Ecology, 2023 , 47(2) : 170 -182 . DOI: 10.17521/cjpe.2022.0180
References
| [1] | Abbott KC, Eppinga MB, Umbanhowar J, Baudena M, Bever JD (2021). Microbiome influence on host community dynamics: conceptual integration of microbiome feedback with classical host-microbe theory. Ecology Letters, 24, 2796-2811. |
| [2] | Adler PB, HilleRisLambers J, Levine JM (2007). A niche for neutrality. Ecology Letters, 10, 95-104. |
| [3] | Aldorfová A, Knobová P, Münzbergová Z (2020). Plant-soil feedback contributes to predicting plant invasiveness of 68 alien plant species differing in invasive status. Oikos, 129, 1257-1270. |
| [4] | Bagchi R, Gallery RE, Gripenberg S, Gurr SJ, Narayan L, Addis CE, Freckleton RP, Lewis OT (2014). Pathogens and insect herbivores drive rainforest plant diversity and composition. Nature, 506, 85-88. |
| [5] | Bardgett RD, Manning P, Morri?n E, de Vries FT (2013). Hierarchical responses of plant-soil interactions to climate change: consequences for the global carbon cycle. Journal of Ecology, 101, 334-343. |
| [6] | Bauer JT, Mack KML, Bever JD (2015). Plant-soil feedbacks as drivers of succession: evidence from remnant and restored tallgrass prairies. Ecosphere, 6, art158. DOI: 10.1890/ES14-00480.1. |
| [7] | Bennett JA, Klironomos J (2019). Mechanisms of plant-soil feedback: interactions among biotic and abiotic drivers. New Phytologist, 222, 91-96. |
| [8] | Bennett JA, Maherali H, Reinhart KO, Lekberg Y, Hart MM, Klironomos J (2017). Plant-soil feedbacks and mycorrhizal type influence temperate forest population dynamics. Science, 355, 181-184. |
| [9] | Bever JD (1994). Feeback between plants and their soil communities in an old field community. Ecology, 75, 1965-1977. |
| [10] | Bever JD (2003). Soil community feedback and the coexistence of competitors: conceptual frameworks and empirical tests. New Phytologist, 157, 465-473. |
| [11] | Bever JD, Dickie IA, Facelli E, Facelli JM, Klironomos J, Moora M, Rillig MC, Stock WD, Tibbett M, Zobel M (2010). Rooting theories of plant community ecology in microbial interactions. Trends in Ecology & Evolution, 25, 468-478. |
| [12] | Bever JD, Platt TG, Morton ER (2012). Microbial population and community dynamics on plant roots and their feedbacks on plant communities. Annual Review of Microbiology, 66, 265-283. |
| [13] | Bever JD, Westover KM, Antonovics J (1997). Incorporating the soil community into plant population dynamics: the utility of the feedback approach. Journal of Ecology, 85, 561-573. |
| [14] | Brinkman EP, van der Putten WH, Bakker E, Verhoeven KJF (2010). Plant-soil feedback: experimental approaches, statistical analyses and ecological interpretations. Journal of Ecology, 98, 1063-1073. |
| [15] | Butt JJ (2002). Daily Life in the Age of Charlemagne. Greenwood Press, Westport, USA. |
| [16] | Callaway RM, Thelen GC, Barth S, Ramsey PW, Gannon JE (2004). Soil fungi alter interactions between the invader Centaurea maculosa and North American natives. Ecology, 85, 1062-1071. |
| [17] | Chase JM, Leibold MA (2003). Ecological Niches: Linking Classical and Contemporary Approaches. University of Chicago Press, Chicago. |
| [18] | Cheeke TE, Zheng CY, Koziol L, Gurholt CR, Bever JD (2019). Sensitivity to AMF species is greater in late-successional than early-successional native or nonnative grassland plants. Ecology, 100, e02855. DOI: 10.1002/ecy.2855. |
| [19] | Chesson P (2000). Mechanisms of maintenance of species diversity. Annual Review of Ecology and Systematics, 31, 343-366. |
| [20] | Chesson P (2018). Updates on mechanisms of maintenance of species diversity. Journal of Ecology, 106, 1773-1794. |
| [21] | Comita LS, Queenborough SA, Murphy SJ, Eck JL, Xu KY, Krishnadas M, Beckman N, Zhu Y, Gómez-Aparicio L (2014). Testing predictions of the Janzen-Connell hypothesis: a meta-analysis of experimental evidence for distance- and density-dependent seed and seedling survival. Journal of Ecology, 102, 845-856. |
| [22] | Comita LS, Stump SM (2020). Natural enemies and the maintenance of tropical tree diversity: recent insights and implications for the future of biodiversity in a changing world. Annals of the Missouri Botanical Garden, 105, 377-392. |
| [23] | Crawford KM, Bauer JT, Comita LS, Eppinga MB, Johnson DJ, Mangan SA, Queenborough SA, Strand AE, Suding KN, Umbanhowar J, Bever JD (2019). When and where plant-soil feedback may promote plant coexistence: a meta-analysis. Ecology Letters, 22, 1274-1284. |
| [24] | De Long JR, Fry EL, Veen GF, Kardol P (2019). Why are plant-soil feedbacks so unpredictable, and what to do about it? Functional Ecology, 33, 118-128. |
| [25] | de Vries FT, Liiri ME, Bj?rnlund L, Bowker MA, Christensen S, Set?l? HM, Bardgett RD (2012). Land use alters the resistance and resilience of soil food webs to drought. Nature Climate Change, 2, 276-280. |
| [26] | Duran-Flores D, Heil M (2015). Growth inhibition by self-DNA: a phenomenon and its multiple explanations. New Phytologist, 207, 482-485. |
| [27] | Eppinga MB, Baudena M, Johnson DJ, Jiang J, Mack KML, Strand AE, Bever JD (2018). Frequency-dependent feedback constrains plant community coexistence. Nature Ecology & Evolution, 2, 1403-1407. |
| [28] | Fukami T, Mordecai EA, Ostling A (2016). A framework for priority effects. Journal of Vegetation Science, 27, 655-657. |
| [29] | Fussmann GF, Loreau M, Abrams PA (2007). Eco-evolutionary dynamics of communities and ecosystems. Functional Ecology, 21, 465-477. |
| [30] | Hannula SE, Heinen R, Huberty M, Steinauer K, De Long JR, Jongen R, Bezemer TM (2021). Persistence of plant- mediated microbial soil legacy effects in soil and inside roots. Nature Communications, 12, 5686. DOI: 10.1038/s41467-021-25971-z. |
| [31] | Hawkins AP, Crawford KM (2018). Interactions between plants and soil microbes may alter the relative importance of intraspecific and interspecific plant competition in a changing climate. AoB PLANTS, 10, ply039. DOI: 10.1093/aobpla/ply039. |
| [32] | Heinze J, Simons NK, Seibold S, Wacker A, Weithoff G, Gossner MM, Prati D, Bezemer TM, Joshi J (2019). The relative importance of plant-soil feedbacks for plant- species performance increases with decreasing intensity of herbivory. Oecologia, 190, 651-664. |
| [33] | Heinze J, Wacker A, Kulmatiski A (2020). Plant-soil feedback effects altered by aboveground herbivory explain plant species abundance in the landscape. Ecology, 101, e03023. DOI: 10.1002/ecy.3023. |
| [34] | Hoestra H (1968). Replant Diseases of Apple in the Netherlands. PhD dissertation, Wageningen Agricultural University, Wageningen, the Netherlands. |
| [35] | Huang YY, Chen YX, Castro-Izaguirre N, Baruffol M, Brezzi M, Lang A, Li Y, H?rdtle W, von Oheimb G, Yang XF, Liu XJ, Pei KQ, Both S, Yang B, Eichenberg D, et al. (2018). Impacts of species richness on productivity in a large-scale subtropical forest experiment. Science, 362, 80-83. |
| [36] | Hülsmann L, Chisholm RA, Hartig F (2021). Is variation in conspecific negative density dependence driving tree diversity patterns at large scales? Trends in Ecology & Evolution, 36, 151-163. |
| [37] | in ‘t Zandt D, Hoekstra NJ, Wagemaker CAM, de Caluwe H, Smit-Tiekstra AE, Visser EJW, de Kroon H (2020). Local soil legacy effects in a multispecies grassland community are underlain by root foraging and soil nutrient availability. Journal of Ecology, 108, 2243-2255. |
| [38] | Janzen DH (1970). Herbivores and the number of tree species in tropical forests. The American Naturalist, 104, 501-528. |
| [39] | Jing JY, Bezemer TM, van der Putten WH (2015). Complementarity and selection effects in early and mid-successional plant communities are differentially affected by plant-soil feedback. Journal of Ecology, 103, 641-647. |
| [40] | Johnson DJ, Beaulieu WT, Bever JD, Clay K (2012). Conspecific negative density dependence and forest diversity. Science, 336, 904-907. |
| [41] | Johnson MTJ, Stinchcombe JR (2007). An emerging synthesis between community ecology and evolutionary biology. Trends in Ecology & Evolution, 22, 250-257. |
| [42] | Kandlikar GS, Johnson CA, Yan XY, Kraft NJB, Levine JM (2019). Winning and losing with microbes: how microbially mediated fitness differences influence plant diversity. Ecology Letters, 22, 1178-1191. |
| [43] | Kandlikar GS, Yan XY, Levine JM, Kraft NJB (2021). Soil microbes generate stronger fitness differences than stabilization among California annual plants. The American Naturalist, 197, E30-E39. |
| [44] | Kardol P, Bezemer TM, van der Putten WH (2006). Temporal variation in plant-soil feedback controls succession. Ecology Letters, 9, 1080-1088. |
| [45] | Kardol P, Cornips NJ, Bakx-Schotman JMT, van der Putten WH (2007). Microbe-mediated plant-soil feedback causes historical contingency effects in plant community assembly. Ecological Monographs, 77, 147-162. |
| [46] | Ke PJ, Letten AD (2018). Coexistence theory and the frequency- dependence of priority effects. Nature Ecology & Evolution, 2, 1691-1695. |
| [47] | Ke PJ, Wan J (2020). Effects of soil microbes on plant competition: a perspective from modern coexistence theory. Ecological Monographs, 90, e01391. DOI: 10.1002/ecm.1391. |
| [48] | Klironomos JN (2002). Feedback with soil biota contributes to plant rarity and invasiveness in communities. Nature, 417, 67-70. |
| [49] | Kraft NJB, Godoy O, Levine JM (2015). Plant functional traits and the multidimensional nature of species coexistence. Proceedings of the National Academy of Sciences of the United States of America, 112, 797-802. |
| [50] | Kulmatiski A, Beard KH, Heavilin J (2012). Plant-soil feedbacks provide an additional explanation for diversity- productivity relationships. Proceedings of the Royal Society B: Biological Sciences, 279, 3020-3026. |
| [51] | Kulmatiski A, Beard KH, Norton JM, Heavilin JE, Forero LE, Grenzer J (2017). Live long and prosper: plant-soil feedback, lifespan, and landscape abundance covary. Ecology, 98, 3063-3073. |
| [52] | Kulmatiski A, Kardol P (2008). Getting plant—Soil feedbacks out of the greenhouse: experimental and conceptual approaches//Lüttge U, Beyschlag W, Murata J. Progress in Botany. Springer, Berlin. 449-472. |
| [53] | LaManna JA, Mangan SA, Alonso A, Bourg NA, Brockelman WY, Bunyavejchewin S, Chang LW, Chiang JM, Chuyong GB, Clay K, Condit R, Cordell S, Davies SJ, Furniss TJ, Giardina CP, et al. (2017). Plant diversity increases with the strength of negative density dependence at the global scale. Science, 356, 1389-1392. |
| [54] | Liang MX, Liu XB, Parker IM, Johnson D, Zheng Y, Luo S, Gilbert GS, Yu SX (2019). Soil microbes drive phylogenetic diversity-productivity relationships in a subtropical forest. Science Advances, 5, eaax5088. DOI: 10.1126/sciadv.aax5088. |
| [55] | Liu XB, Liang MX, Etienne RS, Wang YF, Staehelin C, Yu SX (2012). Experimental evidence for a phylogenetic Janzen- Connell effect in a subtropical forest. Ecology Letters, 15, 111-118. |
| [56] | Loreau M, Hector A (2001). Partitioning selection and complementarity in biodiversity experiments. Nature, 412, 72-76. |
| [57] | Maherali H, Klironomos JN (2007). Influence of phylogeny on fungal community assembly and ecosystem functioning. Science, 316, 1746-1748. |
| [58] | Mangan SA, Schnitzer SA, Herre EA, Mack KML, Valencia MC, Sanchez EI, Bever JD (2010). Negative plant-soil feedback predicts tree-species relative abundance in a tropical forest. Nature, 466, 752-755. |
| [59] | Maron JL, Laney Smith A, Ortega YK, Pearson DE, Callaway RM (2016). Negative plant-soil feedbacks increase with plant abundance, and are unchanged by competition. Ecology, 97, 2055-2063. |
| [60] | Maron JL, Marler M, Klironomos JN, Cleveland CC (2011). Soil fungal pathogens and the relationship between plant diversity and productivity. Ecology Letters, 14, 36-41. |
| [61] | Mayfield MM, Levine JM (2010). Opposing effects of competitive exclusion on the phylogenetic structure of communities. Ecology Letters, 13, 1085-1093. |
| [62] | Mazzoleni S, Bonanomi G, Incerti G, Chiusano ML, Termolino P, Mingo A, Senatore M, Giannino F, Cartenì F, Rietkerk M, Lanzotti V (2015a). Inhibitory and toxic effects of extracellular self-DNA in litter: a mechanism for negative plant-soil feedbacks? New Phytologist, 205, 1195-1210. |
| [63] | Mazzoleni S, Cartenì F, Bonanomi G, Senatore M, Termolino P, Giannino F, Incerti G, Rietkerk M, Lanzotti V, Chiusano ML (2015b). Inhibitory effects of extracellular self- DNA: a general biological process? New Phytologist, 206, 127-132. |
| [64] | McCarthy-Neumann S, Ibá?ez I (2013). Plant-soil feedback links negative distance dependence and light gradient partitioning during seedling establishment. Ecology, 94, 780-786. |
| [65] | McCarthy-Neumann S, Kobe RK (2010). Conspecific and heterospecific plant-soil feedbacks influence survivorship and growth of temperate tree seedlings. Journal of Ecology, 98, 408-418. |
| [66] | Mommer L, Cotton TEA, Raaijmakers JM, Termorshuizen AJ, van Ruijven J, Hendriks M, van Rijssel SQ, van de Mortel JE, van der Paauw JW, Schijlen EGWM, Smit-Tiekstra AE, Berendse F, de Kroon H, Dumbrell AJ (2018). Lost in diversity: the interactions between soil-borne fungi, biodiversity and plant productivity. New Phytologist, 218, 542-553. |
| [67] | Mordecai EA (2011). Pathogen impacts on plant communities: unifying theory, concepts, and empirical work. Ecological Monographs, 81, 429-441. |
| [68] | Nguyen NH, Song ZW, Bates ST, Branco S, Tedersoo L, Menke J, Schilling JS, Kennedy PG (2016). FUNGuild: an open annotation tool for parsing fungal community datasets by ecological guild. Fungal Ecology, 20, 241-248. |
| [69] | Nu?ez MA, Dickie IA (2014). Invasive belowground mutualists of woody plants. Biological Invasions, 16, 645-661. |
| [70] | Pacala SW, Tilman D (2002). The transition from sampling to complementarity//Kinzig AP, Pacala SW, Tilman D. The Functional Consequences of Biodiversity: Empirical Progress and Theoretical Extensions. Princeton University Press, Princeton, USA. 151-166. |
| [71] | Petermann JS, Fergus AJF, Turnbull LA, Schmid B (2008). Janzen-Connell effects are widespread and strong enough to maintain diversity in grasslands. Ecology, 89, 2399-2406. |
| [72] | Png GK, Lambers H, Kardol P, Turner BL, Wardle DA, Laliberté E (2019). Biotic and abiotic plant-soil feedback depends on nitrogen-acquisition strategy and shifts during long-term ecosystem development. Journal of Ecology, 107, 142-153. |
| [73] | P?lme S, Abarenkov K, Henrik Nilsson R, Lindahl BD, Clemmensen KE, Kauserud H, Nguyen N, Kj?ller R, Bates ST, Baldrian P, Fr?slev TG, Adojaan K, Vizzini A, Suija A, Pfister D (2021). FungalTraits: a user-friendly traits database of fungi and fungus-like stramenopiles. Fungal Diversity, 105, 1-16. |
| [74] | Reinhart KO (2012). The organization of plant communities: negative plant-soil feedbacks and semiarid grasslands. Ecology, 93, 2377-2385. |
| [75] | Reinhart KO, Anacker BL (2014). More closely related plants have more distinct mycorrhizal communities. AoB PLANTS, 6, plu051. DOI: 10.1093/aobpla/plu051. |
| [76] | Reinhart KO, Bauer JT, McCarthy-Neumann S, MacDougall AS, Hierro JL, Chiuffo MC, Mangan SA, Heinze J, Bergmann J, Joshi J, Duncan RP, Diez JM, Kardol P, Rutten G, Fischer M, et al. (2021). Globally, plant-soil feedbacks are weak predictors of plant abundance. Ecology and Evolution, 11, 1756-1768. |
| [77] | Reynolds HL, Packer A, Bever JD, Clay K (2003). Grassroots ecology: plant-microbe-soil interactions as drivers of plant community structure and dynamics. Ecology, 84, 2281-2291. |
| [78] | Ricklefs RE (2015). Intrinsic dynamics of the regional community. Ecology Letters, 18, 497-503. |
| [79] | Ricklefs RE (2016). Intrinsic and extrinsic influences on ecological communities. Contributions to Science, 12, 27-34. |
| [80] | Rutten G, Prati D, Hemp A, Fischer M (2016). Plant-soil feedback in East-African savanna trees. Ecology, 97, 294-301. |
| [81] | Schnitzer SA, Klironomos JN, HilleRisLambers J, Kinkel LL, Reich PB, Xiao K, Rillig MC, Sikes BA, Callaway RM, Mangan SA, van Nes EH, Scheffer M (2011). Soil microbes drive the classic plant diversity-productivity pattern. Ecology, 92, 296-303. |
| [82] | Schoener TW (2011). The newest synthesis: understanding the interplay of evolutionary and ecological dynamics. Science, 331, 426-429. |
| [83] | Semchenko M, Leff JW, Lozano YM, Saar S, Davison J, Wilkinson A, Jackson BG, Pritchard WJ, De Long JR, Oakley S, Mason KE, Ostle NJ, Baggs EM, Johnson D, Fierer N, Bardgett RD (2018). Fungal diversity regulates plant-soil feedbacks in temperate grassland. Science Advances, 4, eaau4578. DOI: 10.1126/sciadv.aau4578. |
| [84] | Siepielski AM, McPeek MA (2010). On the evidence for species coexistence: a critique of the coexistence program. Ecology, 91, 3153-3164. |
| [85] | Silvertown J (2004). Plant coexistence and the niche. Trends in Ecology & Evolution, 19, 605-611. |
| [86] | Smith LM, Reynolds HL (2015). Plant-soil feedbacks shift from negative to positive with decreasing light in forest understory species. Ecology, 96, 2523-2532. |
| [87] | Smith-Ramesh LM, Reynolds HL (2017). The next frontier of plant-soil feedback research: unraveling context dependence across biotic and abiotic gradients. Journal of Vegetation Science, 28, 484-494. |
| [88] | terHorst CP, Zee PC (2016). Eco-evolutionary dynamics in plant-soil feedbacks. Functional Ecology, 30, 1062-1072. |
| [89] | Teste FP, Kardol P, Turner BL, Wardle DA, Zemunik G, Renton M, Laliberté E (2017). Plant-soil feedback and the maintenance of diversity in Mediterranean-climate shrublands. Science, 355, 173-176. |
| [90] | Thakur MP, van der Putten WH, Wilschut RA, Veen GF, Kardol P, van Ruijven J, Allan E, Roscher C, van Kleunen M, Bezemer TM (2021). Plant-soil feedbacks and temporal dynamics of plant diversity-productivity relationships. Trends in Ecology & Evolution, 36, 651-661. |
| [91] | Tilman D, Reich PB, Knops J, Wedin D, Mielke T, Lehman C (2001). Diversity and productivity in a long-term grassland experiment. Science, 294, 843-845. |
| [92] | Titus JH, del Moral R (1998). Seedling establishment in different microsites on Mount St. Helens, Washington, USA. Plant Ecology, 134, 13-26. |
| [93] | van de Voorde TFJ, van der Putten WH, Bezemer TM (2011). Intra- and interspecific plant-soil interactions, soil legacies and priority effects during old-field succession. Journal of Ecology, 99, 945-953. |
| [94] | van der Heijden MGA, Bardgett RD, van Straalen NM (2008). The unseen majority: soil microbes as drivers of plant diversity and productivity in terrestrial ecosystems. Ecology Letters, 11, 296-310. |
| [95] | van der Putten WH, Bardgett RD, Bever JD, Bezemer TM, Casper BB, Fukami T, Kardol P, Klironomos JN, Kulmatiski A, Schweitzer JA, Suding KN, van de Voorde TFJ, Wardle DA (2013). Plant-soil feedbacks: the past, the present and future challenges. Journal of Ecology, 101, 265-276. |
| [96] | van der Putten WH, Peters BAM (1997). How soil-borne pathogens may affect plant competition. Ecology, 78, 1785-1795. |
| [97] | van der Putten WH, van Dijk C, Peters BAM (1993). Plant- specific soil-borne diseases contribute to succession in foredune vegetation. Nature, 362, 53-56. |
| [98] | van Ruijven J, Ampt E, Francioli D, Mommer L (2020). Do soil-borne fungal pathogens mediate plant diversity- productivity relationships? Evidence and future opportunities. Journal of Ecology, 108, 1810-1821. |
| [99] | Veresoglou SD, Aguilar-Trigueros CA, Mansour I, Rillig MC (2015). Self-DNA: a blessing in disguise? New Phytologist, 207, 488-490. |
| [100] | Veresoglou SD, Rillig MC (2014). Do closely related plants host similar arbuscular mycorrhizal fungal communities? A meta-analysis. Plant and Soil, 377, 395-406. |
| [101] | Vogelsang KM, Bever JD (2009). Mycorrhizal densities decline in association with nonnative plants and contribute to plant invasion. Ecology, 90, 399-407. |
| [102] | Vogelsang KM, Reynolds HL, Bever JD (2006). Mycorrhizal fungal identity and richness determine the diversity and productivity of a tallgrass prairie system. New Phytologist, 172, 554-562. |
| [103] | Wagg C, Jansa J, Schmid B, van der Heijden MGA (2011). Belowground biodiversity effects of plant symbionts support aboveground productivity. Ecology Letters, 14, 1001-1009. |
| [104] | Walder F, Niemann H, Natarajan M, Lehmann MF, Boller T, Wiemken A (2012). Mycorrhizal networks: common goods of plants shared under unequal terms of trade. Plant Physiology, 159, 789-797. |
| [105] | Wang GZ, Jia JY, Zhang JL (2021). Plant soil feedback theory and its applications and prospects in natural and agricultural ecosystems. Acta Ecologica Sinica, 41, 9130-9143. |
| [105] | [王光州, 贾吉玉, 张俊伶 (2021). 植物-土壤反馈理论及其在自然和农田生态系统中的应用研究进展. 生态学报, 41, 9130-9143.] |
| [106] | Wang GZ, Schultz P, Tipton A, Zhang JL, Zhang FS, Bever JD (2019). Soil microbiome mediates positive plant diversity- productivity relationships in late successional grassland species. Ecology Letters, 22, 1221-1232. |
| [107] | Wardle DA, Bardgett RD, Callaway RM, van der Putten WH (2011). Terrestrial ecosystem responses to species gains and losses. Science, 332, 1273-1277. |
| [108] | Weigelt A, Bol R, Bardgett RD (2005). Preferential uptake of soil nitrogen forms by grassland plant species. Oecologia, 142, 627-635. |
| [109] | Wubs ERJ, Bezemer TM (2016). Effects of spatial plant-soil feedback heterogeneity on plant performance in monocultures. Journal of Ecology, 104, 364-376. |
| [110] | Xi NX, Adler PB, Chen DX, Wu HY, Catford JA, van Bodegom PM, Bahn M, Crawford KM, Chu CJ (2021). Relationships between plant-soil feedbacks and functional traits. Journal of Ecology, 109, 3411-3423. |
| [111] | Xi NX, Bloor JMG, Chu CJ (2020). Soil microbes alter seedling performance and biotic interactions under plant competition and contrasting light conditions. Annals of Botany, 126, 1089-1098. |
| [112] | Xi NX, Bloor JMG, Wang Y, Chu CJ (2019). Contribution of conspecific soil microorganisms to tree seedling light responses: insights from two tropical species with contrasting shade tolerance. Environmental and Experimental Botany, 166, 103826. DOI: 10.1016/j.envexpbot.2019.103826. |
| [113] | Xi NX, Chen DX, Bahn M, Wu HY, Chu CJ, Cadotte MW, Bloor JMG (2022a). Drought soil legacy alters drivers of plant diversity-productivity relationships in oldfield systems. Science Advances, 8, eabn3368. DOI: 10.1126/sciadv.abn3368. |
| [114] | Xi NX, Chu CJ, Bloor JMG (2018). Plant drought resistance is mediated by soil microbial community structure and soil- plant feedbacks in a savanna tree species. Environmental and Experimental Botany, 155, 695-701. |
| [115] | Xi NX, Crawford KM, de Long JR (2022b). Plant landscape abundance and soil fungi modulate drought effects on plant-soil feedbacks. Oikos, 2022, e08836. DOI: 10.1111/oik.08836. |
| [116] | Yelenik SG, Levine JM (2011). The role of plant-soil feedbacks in driving native-species recovery. Ecology, 92, 66-74. |
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