Chinese Journal of Applied Ecology ›› 2022, Vol. 33 ›› Issue (8): 2279-2285.doi: 10.13287/j.1001-9332.202208.004
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TANG Jiao1, YIN Jin-zhong1, PAN Fei-fei2, LI Jun-na1, ZHAO Yun-fei1, WU Da-fu1*
Received:
2022-01-06
Accepted:
2022-02-23
Online:
2022-08-15
Published:
2023-02-15
TANG Jiao, YIN Jin-zhong, PAN Fei-fei, LI Jun-na, ZHAO Yun-fei, WU Da-fu. Research progress on nurse effects of shrubs in ecological restoration[J]. Chinese Journal of Applied Ecology, 2022, 33(8): 2279-2285.
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URL: https://www.cjae.net/EN/10.13287/j.1001-9332.202208.004
[1] Callaway RM, Walker LR. Competition and facilitation: A synthetic approach to interactions in plant communities. Ecology, 1997, 78: 1958-1965 [2] Brooker RW, Maestre FT, Callaway RM, et al. Facilitation in plant communities: The past, the present, and the future. Journal of Ecology, 2010, 96: 18-34 [3] 张炜平, 王根轩. 植物邻体间的正相互作用. 生态学报, 2010, 30(19): 5371-5380 [4] Bertness MD, Callaway RM. Positive interactions in communities. Trends in Ecology & Evolution, 1994, 9: 191-193 [5] 张炜平, 潘莎, 贾昕, 等. 植物间正相互作用对种群动态和群落结构的影响: 基于个体模型的研究进展.植物生态学报, 2013, 37(6): 571-582 [6] Callaway RM. Positive Interactions and Interdependence in Plant Communities. Dordrecht: Springer, 2007: 56-88 [7] Maestre F, Callaway RM, Valladares F, et al. Refining the stress-gradient hypothesis for competition and facilitation in plant communities. Journal of Ecology, 2009, 97: 199-205 [8] Gómez-Aparicio L. The role of plant interactions in the restoration of degraded ecosystems: A meta-analysis across life-forms and ecosystems. Journal of Ecology, 2010, 97: 1202-1214 [9] Guignabert A, Augusto L, Gonzalez M, et al. Complex biotic interactions mediated by shrubs: Revisiting the stress-gradient hypothesis and consequences for tree seedling survival. Journal of Applied Ecology, 2020, 57: 1341-1350 [10] Peláez M, Dirzo R, Fernandes GW, et al. Nurse plant size and biotic stress determine quantity and quality of plant facilitation in oak savannas. Forest Ecology and Management, 2019, 437: 435-442 [11] Quon LH, Bobich EG, Questad EJ. Facilitation and herbivory during restoration of California coastal sage scrub. Restoration Ecology, 2019, 27: 1041-1052 [12] Caldeira MC, Ibáez I, Nogueira C, et al. Direct and indirect effects of tree canopy facilitation in the recruitment of Mediterranean oaks. Journal of Applied Ecology, 2014, 51: 349-358 [13] Castro J, Zamora R, Hódar JA, et al. Benefits of using shrubs as nurse plants for reforestation in Mediterranean mountains: A 4-year study. Restoration Ecology, 2004, 12: 352-358 [14] Gomez-Aparicio L, Zamora R, Gomez J, et al. Applying plant positive interaction to deforestation in Mediterranean mountains: A meta-analysis of the use of shrubs as nurse plants. Ecological Applications, 2004, 14: 1128-1138 [15] Padilla F, Pugnaire F. The role of nurse plants in the restoration of degraded environments. Frontiers in Eco-logy and the Environment, 2006, 4: 196-202 [16] Yelenik SG, Dimanno N, D'Antonio CM. Evaluating nurse plants for restoring native woody species to degra-ded subtropical woodlands. Ecology & Evolution, 2015, 5: 300-313 [17] Saixiyala, Yang D, Zhang SD, et al. Facilitation by a spiny shrub on a rhizomatous clonal herbaceous in thicke-tization-grassland in Northern China: Increased soil resources or shelter from herbivores. Frontiers in Plant Science, 2017, 8: 809 [18] Zhang HY, Lü XT, Knapp AK, et al. Facilitation by leguminous shrubs increases along a precipitation gradient. Functional Ecology, 2018, 32: 203-213 [19] Su YZ, Zhao HF. Soil properties and plant species in an age sequence of Caragana microphylla plantations in the Horqin Sandy Land, north China. Ecological Enginee-ring, 2003, 20: 223-235 [20] 丁威, 王玉冰, 向官海, 等. 小叶锦鸡儿灌丛化对典型草原群落结构与生态系统功能的影响. 植物生态学报, 2020, 44(1): 33-43 [21] Andivia E, Villar-Salvador P, Tovar L, et al. Multiscale assessment of woody species recruitment in Mediterranean shrublands: Facilitation and beyond. Journal of Vegetation Science, 2017, 28: 639-648 [22] Xie LN, Guo HY, Liu Z, et al. Shrubs facilitate recruitment of Caragana stenophylla Pojark: Microhabitat amelioration and protection against herbivory. Annals of Forest Science, 2017, 74: 70 [23] Morrison TA, Holdo RM, Rugemalila DM, et al. Grass competition overwhelms effects of herbivores and precipitation on early tree establishment in Serengeti. Journal of Ecology, 2018, 107: 216-228 [24] O'Donnell L, Pickles BJ, Campbell CM, et al. Native tree and shrub canopy facilitates oak seedling regeneration in semiarid woodland. Ecosphere, 2020, 11: e03017 [25] Leiva MJ, Mancilla-Leyton JM, MartínVicente Á. Differences in the facilitative ability of two Mediterranean shrubs on holm-oak seedling recruitment in Mediterranean savanna-forest ecosystems. Ecological Engineering, 2015, 82: 349-354 [26] Armas C, Pugnaire FI. Plant interactions govern population dynamics in a semi-arid plant community. Journal of Ecology, 2005, 93: 978-989 [27] Holmgren M, Gomez-Aparicio L, Quero J, et al. Non-linear effects of drought under shade: Reconciling phy-siological and ecological models in plant communities. Oecologia, 2012, 169: 293-305 [28] Rolo V, Plieninger T, Moreno G. Facilitation of holm oak recruitment through two contrasted shrubs species in Mediterranean grazed woodlands. Journal of Vegetation Science, 2012, 24: 344-355 [29] Bai YX, She WW, Richard M, et al. Benefactor facilitation and beneficiary feedback effects drive shrub-dominated community succession in a semi-arid dune ecosystem. Applied Vegetation Science, 2018, 21: 595-606 [30] Tian L, Wang XA. Role of nurse shrubs for restoration planting of two conifers in southeast of Mu Us Sandland, China. Journal of Environmental Biology, 2015, 36: 331-336 [31] Gonzalez SL, Ghermandi L, Prieto Aguilar I. Dwarf shrub facilitates seedling recruitment and plant diversity in semiarid grasslands. PLoS One, 2019, 14(2): e0212058 [32] Montes-Hernández B, López-Barrera F. Seedling establishment of Quercus insignis: A critically endangered oak tree species in southern Mexico. Forest Ecology and Management, 2013, 310: 927-934 [33] Smit C, Vandenberghe C, Ouden JD, et al. Nurse plants, tree saplings and grazing pressure: Changes in facilitation along a biotic environmental gradient. Oecologia, 2007, 152: 265-273 [34] Zhang PJ, Yang J, Zhao LQ, et al. Effect of Caragana tibetica nebkhas on sand entrapment and fertile islands in steppe-desert ecotones on the Inner Mongolia Plateau, China. Plant and Soil, 2011, 347: 79-90 [35] El-Keblawy A, Kafhaga T, Navarro T. Live and dead shrubs and grasses have different facilitative and interfe-ring effects on associated plants in arid Arabian deserts. Journal of Arid Environments, 2016, 125: 127-135 [36] 王正宁, 王新平, 刘博. 荒漠灌丛内降雨和土壤水分再分配. 应用生态学报, 2016, 27(3): 755-760 [37] van Zonneveld M, Gutiérrez J, Holmgren M. Shrub facilitation increases plant diversity along an arid scrubland-temperate rainforest boundary in South America. Journal of Vegetation Science, 2012, 23: 541-551 [38] Zhao HL, Zhou RL, Su YZ, et al. Shrub facilitation of desert land restoration in the Horqin Sand Land of Inner Mongolia. Ecological Engineering, 2007, 31: 1-8 [39] 苏永中, 赵哈林, 张铜会. 几种灌木、半灌木对沙地土壤肥力影响机制的研究. 应用生态学报, 2002, 13(7): 802-806 [40] Li XH, Jiang DM, Zhou QL, et al. Soil seed bank cha-racteristics beneath an age sequence of caragana microphylla shrubs in the horqin sandy land region of northeastern China. Land Degradation & Development, 2014, 25: 236-243 [41] Allington G, Valone T. Islands of fertility: A byproduct of grazing? Ecosystems, 2014, 17: 127-141 [42] Filazzola A, Lortie CJ. A systematic review and conceptual framework for the mechanistic pathways of nurse plants. Global Ecology & Biogeography, 2014, 23: 1335-1345 [43] Tálamo A, Barchuk AH, Garibaldi LA, et al. Disentangling the effects of shrubs and herbivores on tree rege-neration in a dry Chaco forest (Argentina). Oecologia, 2015, 178: 847-854 [44] Danet A, Kéfi S, Meneses RI, et al. Nurse species and indirect facilitation through grazing drive plant commu-nity functional traits in tropical alpine peatlands. Ecology and Evolution, 2017, 7: 11265-11276 [45] Gorzelak MA, Asay AK, Pickles BJ, et al. Inter-plant communication through mycorrhizal networks mediates complex adaptive behavior in plant communities. AoB Plants, 2015, 7: plv050 [46] Pickles BJ, Simard SW. Mycorrhizal Mediation of Soil. New York: Elsevier, 2017: 53-59 [47] Ochoa-Hueso R, Eldridg DJ, Delgado-Baqueriz M, et al. Soil fungal abundance and plant functional traits drive fertile island formation in global drylands. Journal of Ecology, 2017, 106: 242-253 [48] Deniau M, Vincent J, Lann CL, et al. Janzen-Connell patterns can be induced by fungal-driven decomposition and offset by ectomycorrhizal fungi accumulated under a closely-related canopy. Functional Ecology, 2018, 32: 785-798 [49] Danet A, Schneider FD, Anthelme F, et al. Indirect facilitation drives species composition and stability in drylands. Theoretical Ecology, 2021, 14: 189-203 [50] Wang XT, Richard M, Meng LH, et al. Direct and indirect facilitation affect community productivity through changes in functional diversity in an alpine system. Annals of Botany, 2020, 127: 241-249 [51] Jensen A, Löf M, Witzell J. Effects of competition and indirect facilitation by shrubs on Quercus robur saplings. Plant Ecology, 2012, 213: 535-543 [52] Kunstler G, Curt T, Bouchaud M, et al. Indirect facilitation and competition in tree species colonization of sub-Mediterranean grasslands. Journal of Vegetation Science, 2009, 17: 379-388 [53] Armas C, Pugnaire FI. Ontogenetic shifts in interactions of two dominant shrub species in a semi-arid coastal sand dune system. Journal of Vegetation Science, 2010, 20: 535-546 [54] Maestre FT, Valladares F, Reynolds JF. Is the change of plant-plant interactions with abiotic stress predictable? A meta-analysis of field results in arid environments. Journal of Ecology, 2010, 93: 748-757 [55] Tang J, Davy AJ, Jiang DM, et al. Effects of excluding grazing on the vegetation and soils of degraded sparse-elm grassland in the Horqin Sandy Land, China. Agriculture, Ecosystems & Environment, 2016, 235: 340-348 [56] Boulant N, Navas ML, Corcket E, et al. Habitat ame-lioration and associational defence as main facilitative mechanisms in Mediterranean grasslands grazed by domestic livestock. Écoscience, 2008, 15: 407-415 [57] Klinger R, Rejmanek M. The numerical and functional responses of a granivorous rodent and the fate of Neotropical tree seeds. Ecology, 2009, 90: 1549-1563 [58] Alexandra KU, Peter JW, Jeanne CC, et al. Shrub facilitation of tree establishment varies with ontogeneticstage across environmental gradients. New Phytologist, 2019, 223: 1795-1808 [59] Callaway RM, Kikodze D, Chiboshvili M, et al. Unpa-latable plants protect neighbors from grazing and increase plant community diversity. Ecology, 2005, 86: 1856-1862 [60] Ortiz-Martínez E, Golubov J, Mandujano MC, et al. Factors affecting germination and establishment success of an endemic cactus of the Chihuahuan Desert. Plant Ecology, 2021, 222: 953-963 [61] He Q, Bertness MD. Extreme stresses, niches, and posi-tive species interactions along stress gradients. Ecology, 2014, 95: 1437-1443 [62] Stein JH, Knut R, Marte SL, et al. Junipers enable heavily browsed rowan saplings to escape ungulates in boreal forest. Forest Ecology and Management, 2021, 500: 119651 |
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