Meta-analysis reveals that vertebrates enhance plant litter decomposition at the global scale.
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[1] E. S. Bakker,et al. Large mammalian herbivores affect arthropod food webs via changes in vegetation characteristics and microclimate , 2023, Journal of Ecology.
[2] P. D. de Bruyn,et al. Are hippos Africa's most influential megaherbivore? A review of ecosystem engineering by the semi‐aquatic common hippopotamus , 2023, Biological reviews of the Cambridge Philosophical Society.
[3] M. Lagisz,et al. Quantitative evidence synthesis: a practical guide on meta-analysis, meta-regression, and publication bias tests for environmental sciences , 2023, Environmental Evidence.
[4] M. Schleuning,et al. Trait diversity shapes the carbon cycle. , 2023, Trends in ecology & evolution.
[5] Shawn J. Leroux,et al. Trophic rewilding can expand natural climate solutions , 2023, Nature Climate Change.
[6] M. Lagisz,et al. A robust and readily implementable method for the meta-analysis of response ratios with and without missing standard deviations. , 2022, Ecology letters.
[7] Aaron C. Greenville,et al. Grazing and ecosystem service delivery in global drylands , 2022, Science.
[8] S. Prober,et al. Termite sensitivity to temperature affects global wood decay rates , 2022, Science.
[9] Yan Peng,et al. Litter quality and stream physicochemical properties drive global invertebrate effects on instream litter decomposition , 2022, Biological reviews of the Cambridge Philosophical Society.
[10] Yixin Zhang,et al. Anthropogenic Carrion Subsidy and Herbicide Glyphosate Depressed Leaf-Litter Breakdown: Effects on Environmental Health in Streams , 2022, Frontiers in Environmental Science.
[11] Jian Sun,et al. Additive effects of warming and grazing on fine root decomposition and loss of nutrients in an alpine meadow , 2022, Journal of Plant Ecology.
[12] S. Blake,et al. Megaherbivores modify forest structure and increase carbon stocks through multiple pathways , 2021, bioRxiv.
[13] J. Cornelissen,et al. Soil fauna accelerate litter mixture decomposition globally, especially in dry environments , 2021, Journal of Ecology.
[14] L. Martinelli,et al. Effect of vertebrate exclusion on leaf litter decomposition in the coastal Atlantic forest of southeast Brazil , 2021, Tropical Ecology.
[15] C. Chenu,et al. Role of different size classes of organisms in cropped soils: What do litterbag experiments tell us? A meta-analysis , 2021, Soil Biology and Biochemistry.
[16] Y. Malhi,et al. Can large herbivores enhance ecosystem carbon persistence? , 2021, Trends in ecology & evolution.
[17] J. Cromsigt,et al. Megaherbivore impacts on ecosystem and Earth system functioning: the current state of the science , 2021, Ecography.
[18] T. Hothorn,et al. The contribution of insects to global forest deadwood decomposition , 2021, Nature.
[19] E. Chaneton,et al. Long-term impact of domestic ungulates versus the local controls of the litter decomposition process in arid steppes , 2021, Plant and Soil.
[20] Deli Wang,et al. Livestock diversification implicitly affects litter decomposition depending on altered soil properties and plant litter quality in a meadow steppe , 2021, Plant and Soil.
[21] Frank O. Masese,et al. Impacts of detritivore diversity loss on instream decomposition are greatest in the tropics , 2021, Nature Communications.
[22] C. Parr,et al. The impact of invertebrate decomposers on plants and soil. , 2021, The New phytologist.
[23] A. Risch,et al. A facilitation between large herbivores and ants accelerates litter decomposition by modifying soil microenvironmental conditions , 2021 .
[24] G. Saba,et al. Integral functions of marine vertebrates in the ocean carbon cycle and climate change mitigation , 2021, One Earth.
[25] D. Eldridge,et al. Temporal changes in soil function in a wooded dryland following simulated disturbance by a vertebrate engineer , 2021, CATENA.
[26] Yingjun Zhang,et al. Transformation of litter carbon to stable soil organic matter is facilitated by ungulate trampling , 2021 .
[27] F. Pasmans,et al. Salamander loss alters litter decomposition dynamics. , 2021, The Science of the total environment.
[28] M. Harmon. The role of woody detritus in biogeochemical cycles: past, present, and future , 2021, Biogeochemistry.
[29] Xuan Xu,et al. Cellulose dominantly affects soil fauna in the decomposition of forest litter: A meta-analysis , 2020 .
[30] Shawn J. Leroux,et al. Food Webs and Ecosystems: Linking Species Interactions to the Carbon Cycle , 2020 .
[31] F. Li,et al. Changes in litter decomposition rate of dominant plants in a semi-arid steppe across different land-use types: Soil moisture, not home-field advantage, plays a dominant role , 2020 .
[32] Jean-Louis Martin,et al. Deer slow down litter decomposition by reducing litter quality in a temperate forest. , 2020, Ecology.
[33] C. Parr,et al. Clarifying Terrestrial Recycling Pathways. , 2020, Trends in ecology & evolution.
[34] Han Y. H. Chen,et al. Functional and phylogenetic diversity promote litter decomposition across terrestrial ecosystems , 2020 .
[35] J. Cornelissen,et al. Dynamic feedbacks among tree functional traits, termite populations and deadwood turnover , 2020, Journal of Ecology.
[36] Shawn J. Leroux,et al. Herbivore Impacts on Carbon Cycling in Boreal Forests. , 2020, Trends in ecology & evolution.
[37] L. Lai,et al. A global meta-analysis of livestock grazing impacts on soil properties , 2020, PloS one.
[38] R. Aerts,et al. Decomposition of leaf litter mixtures across biomes: The role of litter identity, diversity and soil fauna , 2020, Journal of Ecology.
[39] K. Norris,et al. Biodiversity Conservation and the Earth System: Mind the Gap , 2020, Trends in Ecology & Evolution.
[40] J. Cahill,et al. The effects of livestock grazing on biodiversity are multi-trophic: a meta-analysis. , 2020, Ecology letters.
[41] Zacchaeus G. Compson,et al. Synergistic effects: a common theme in mixed-species litter decomposition. , 2020, The New phytologist.
[42] Tao Wang,et al. Grazing exclusion altered the effect of plant root diameter on decomposition rates in a semiarid grassland ecosystem, northeastern China , 2020 .
[43] Guiyao Zhou,et al. Grazing intensity significantly changes the C : N : P stoichiometry in grassland ecosystems , 2020 .
[44] Xia Yuan,et al. Litter decomposition in fenced and grazed grasslands: A test of the home-field advantage hypothesis , 2019, Geoderma.
[45] H. Gibb,et al. Rainfall‐dependent impacts of threatened ecosystem engineers on organic matter cycling , 2019, Functional Ecology.
[46] Jake E. Bicknell,et al. Quantifying the impacts of defaunation on natural forest regeneration in a global meta-analysis , 2019, Nature Communications.
[47] C. Montaña,et al. Revisiting “what do tadpoles really eat?” A 10‐year perspective , 2019, Freshwater Biology.
[48] J. Cushman,et al. Synthesizing the effects of large, wild herbivore exclusion on ecosystem function , 2019, Functional Ecology.
[49] F. Hou,et al. Grazing activity increases decomposition of yak dung and litter in an alpine meadow on the Qinghai-Tibet plateau , 2019, Plant and Soil.
[50] Wiebke J. Boeing,et al. Decaying woodrat (Neotoma spp.) middens increase soil resources and accelerate decomposition of contemporary litter , 2019, Journal of Arid Environments.
[51] Philippe Ciais,et al. Carbon stocks in central African forests enhanced by elephant disturbance , 2019, Nature Geoscience.
[52] Shinichi Nakagawa,et al. Global meta‐analysis of soil‐disturbing vertebrates reveals strong effects on ecosystem patterns and processes , 2019, Global Ecology and Biogeography.
[53] J. Cromsigt,et al. Elephant effects on treefall and logfall highlight the absence of megaherbivores in coarse woody debris conceptual frameworks , 2019, Forest Ecology and Management.
[54] E. Lamb,et al. Yak Dung Deposition Affects Litter Mixing Effects on Mass Loss in Tibetan Alpine Grassland ☆ , 2019, Rangeland Ecology and Management.
[55] R. Alford,et al. Tadpole species have variable roles in litter breakdown, sediment removal, and nutrient cycling in a tropical stream , 2019, Freshwater Science.
[56] T. Evans,et al. Termites can decompose more than half of deadwood in tropical rainforest , 2019, Current Biology.
[57] Shawn J. Leroux,et al. Animals and the zoogeochemistry of the carbon cycle , 2018, Science.
[58] D. Post,et al. Context dependency of animal resource subsidies , 2018, Biological reviews of the Cambridge Philosophical Society.
[59] J. Pumpanen,et al. Beavers affect carbon biogeochemistry: both short‐term and long‐term processes are involved , 2018, Mammal Review.
[60] F. Hou,et al. Grazing increases litter decomposition rate but decreases nitrogen release rate in an alpine meadow , 2018, Biogeosciences.
[61] Q. Guo,et al. Large herbivores influence plant litter decomposition by altering soil properties and plant quality in a meadow steppe , 2018, Scientific Reports.
[62] Zhanqing Hao,et al. Global signal of top-down control of terrestrial plant communities by herbivores , 2018, Proceedings of the National Academy of Sciences.
[63] Ya-hui Huang,et al. Effects of fish predators and litter pack size on leaf breakdown in a subtropical stream , 2018, Hydrobiologia.
[64] K. Niu,et al. Interacting effects of yak dung deposition and litter quality on litter mass loss and nitrogen dynamics in Tibetan alpine grassland , 2018 .
[65] X. Otero,et al. Seabird colonies as important global drivers in the nitrogen and phosphorus cycles , 2018, Nature Communications.
[66] E. Bork,et al. Long-Term Grazing Accelerated Litter Decomposition in Northern Temperate Grasslands , 2018, Ecosystems.
[67] Deli Wang,et al. Sheep grazing and local community diversity interact to control litter decomposition of dominant species in grassland ecosystem , 2017 .
[68] J. Fragoso,et al. Mammal diversity influences the carbon cycle through trophic interactions in the Amazon , 2017, Nature Ecology & Evolution.
[69] D. Wall,et al. Responses of belowground communities to large aboveground herbivores: Meta‐analysis reveals biome‐dependent patterns and critical research gaps , 2017, Global change biology.
[70] G. Romero,et al. Terrestrial vertebrate predators drive the structure and functioning of aquatic food webs. , 2017, Ecology.
[71] Y. Clough,et al. The role of ants, birds and bats for ecosystem functions and yield in oil palm plantations. , 2017, Ecology.
[72] Shinichi Nakagawa,et al. Meta-evaluation of meta-analysis: ten appraisal questions for biologists , 2017, BMC Biology.
[73] N. Prat,et al. Top predator absence enhances leaf breakdown in an intermittent stream. , 2016, The Science of the total environment.
[74] Atul K. Jain,et al. Global Carbon Budget 2016 , 2016 .
[75] S. Ohdachi,et al. Top-Down Cascade Effects of the Long-Clawed Shrew (Sorex unguiculatus) on the Soil Invertebrate Community in a Cool-Temperate Forest , 2016, Mammal Study.
[76] B. McConkey,et al. Grazing improves C and N cycling in the Northern Great Plains: a meta-analysis , 2016, Scientific Reports.
[77] A. Mori,et al. Ungulates decelerate litter decomposition by altering litter quality above and below ground , 2016, European Journal of Forest Research.
[78] S. Hättenschwiler,et al. The importance of litter traits and decomposers for litter decomposition: A comparison of aquatic and terrestrial ecosystems within and across biomes , 2016 .
[79] D. Wall,et al. Temporal dynamics of biotic and abiotic drivers of litter decomposition. , 2016, Ecology letters.
[80] David Kenfack,et al. Contrasting effects of defaunation on aboveground carbon storage across the global tropics , 2016, Nature Communications.
[81] M. Ulyshen. Wood decomposition as influenced by invertebrates , 2016, Biological reviews of the Cambridge Philosophical Society.
[82] T. Raffel,et al. Differential consumption and assimilation of leaf litter by wetland herbivores: alternative pathways for decomposition and trophic transfer , 2016, Freshwater Science.
[83] W. Wieder,et al. Understanding the dominant controls on litter decomposition , 2016 .
[84] O. Ovaskainen,et al. Defaunation affects carbon storage in tropical forests , 2015, Science Advances.
[85] Q. Luo,et al. Effects of land use and precipitation on above- and below-ground litter decomposition in a semi-arid temperate steppe in Inner Mongolia, China , 2015 .
[86] T. Crowl,et al. Effects of the presence of a predatory fish and the phenotype of its prey (a shredding shrimp) on leaf litter decomposition , 2015 .
[87] Petr Baldrian,et al. Biotic interactions mediate soil microbial feedbacks to climate change , 2015, Proceedings of the National Academy of Sciences.
[88] Mark V Brown,et al. Soil-foraging animals alter the composition and co-occurrence of microbial communities in a desert shrubland , 2015, The ISME Journal.
[89] T. Osono,et al. Mass, nitrogen content, and decomposition of woody debris in forest stands affected by excreta deposited in nesting colonies of Great Cormorant , 2015, Ecological Research.
[90] J. Bakker,et al. Defoliation and Soil Compaction Jointly Drive Large-Herbivore Grazing Effects on Plants and Soil Arthropods on Clay Soil , 2015, Ecosystems.
[91] K. Wantzen,et al. A conceptual model of litter breakdown in low order streams , 2015 .
[92] R. Dirzo,et al. Defaunation in the Anthropocene , 2014, Science.
[93] J. R. King,et al. Climate fails to predict wood decomposition at regional scales , 2014 .
[94] R. Aerts,et al. Consequences of biodiversity loss for litter decomposition across biomes , 2014, Nature.
[95] M. Gessner,et al. Trophic complexity enhances ecosystem functioning in an aquatic detritus-based model system. , 2013, The Journal of animal ecology.
[96] Diana H. Wall,et al. Climate and litter quality differently modulate the effects of soil fauna on litter decomposition across biomes. , 2013, Ecology letters.
[97] J. M. Mancilla-Leytón,et al. Influence of grazing on the decomposition of Pinus pinea L. needles in a silvopastoral system in Doñana, Spain , 2013, Plant and Soil.
[98] D. Srivastava,et al. Predator-induced reduction of freshwater carbon dioxide emissions , 2013 .
[99] D. Wardle,et al. Microclimate within litter bags of different mesh size: Implications for the 'arthropod effect' on litter decomposition , 2013 .
[100] H. Olff,et al. Herbivore trampling as an alternative pathway for explaining differences in nitrogen mineralization in moist grasslands , 2012, Oecologia.
[101] C. Anderson,et al. Organic matter characterization and decomposition dynamics in sub-Antarctic streams impacted by invasive beavers , 2012 .
[102] G. Asner,et al. Landscape-scale effects of herbivores on treefall in African savannas. , 2012, Ecology letters.
[103] L. Boddy,et al. Impacts of elevated temperature on the growth and functioning of decomposer fungi are influenced by grazing collembola , 2012 .
[104] J. Cornelissen,et al. Multiple mechanisms for trait effects on litter decomposition: moving beyond home‐field advantage with a new hypothesis , 2012 .
[105] S. Sjögersten,et al. Impacts of Grazing and Climate Warming on C Pools and Decomposition Rates in Arctic Environments , 2012, Ecosystems.
[106] K. Lips,et al. Do tadpoles affect leaf decomposition in neotropical streams , 2011 .
[107] D. BrethertonWelles,et al. Salmon carcasses alter leaf litter species diversity effects on in-stream decomposition , 2011 .
[108] E. K. Pikitch,et al. Trophic Downgrading of Planet Earth , 2011, Science.
[109] P. Rovira,et al. Root decomposition in grazed and abandoned dry Mediterranean dehesa and mesic mountain grasslands estimated by standard labelled roots , 2010 .
[110] T. Fox,et al. Does Plethodon cinereus Affect Leaf Litter Decomposition and Invertebrate Abundances in Mixed Oak Forest? , 2010 .
[111] Y. Kuzyakov. Priming effects : interactions between living and dead organic matter , 2010 .
[112] Wolfgang Viechtbauer,et al. Conducting Meta-Analyses in R with the metafor Package , 2010 .
[113] M. Gessner,et al. Diversity meets decomposition. , 2010, Trends in ecology & evolution.
[114] B. Modenutti,et al. Does predation by the introduced rainbow trout cascade down to detritus and algae in a forested small stream in Patagonia? , 2010, Hydrobiologia.
[115] S. Wanless,et al. The influence of seabird nutrient enrichment and grazing on the structure and function of island soil food webs , 2010 .
[116] W. Whitford,et al. Animal disturbances promote shrub maintenance in a desertified grassland , 2009 .
[117] V. Reynolds,et al. Decaying Raphia farinifera Palm Trees Provide a Source of Sodium for Wild Chimpanzees in the Budongo Forest, Uganda , 2009, PloS one.
[118] W. Parton,et al. Home-field advantage accelerates leaf litter decomposition in forests , 2009 .
[119] N. Marbà,et al. Fish farming impact on decomposition of Posidonia oceanica litter , 2009 .
[120] D. Wardle,et al. Indirect effects of invasive predators on litter decomposition and nutrient resorption on seabird-dominated islands. , 2009, Ecology.
[121] M. Bertiller,et al. Leaf litterfall, fine-root production, and decomposition in shrublands with different canopy structure induced by grazing in the Patagonian Monte, Argentina , 2008, Plant and Soil.
[122] A. S. Melo,et al. Responses of aquatic invertebrate assemblages and leaf breakdown to macroconsumer exclusion in Amazonian "terra firme" streams , 2008 .
[123] K. Beard,et al. An invasive frog, Eleutherodactylus coqui, increases new leaf production and leaf litter decomposition rates through nutrient cycling in Hawaii , 2008, Biological Invasions.
[124] E. Chaneton,et al. Grazing history effects on above- and below-ground litter decomposition and nutrient cycling in two co-occurring grasses , 2008, Plant and Soil.
[125] Dario A. Fornara,et al. Browsing-induced Effects on Leaf Litter Quality and Decomposition in a Southern African Savanna , 2008, Ecosystems.
[126] R. Houghton. Balancing the Global Carbon Budget , 2007 .
[127] E. Chaneton,et al. Grazing-induced changes in plant composition affect litter quality and nutrient cycling in flooding Pampa grasslands , 2007, Oecologia.
[128] T. Fukami,et al. Above- and below-ground impacts of introduced predators in seabird-dominated island ecosystems. , 2006, Ecology letters.
[129] T. Osono,et al. Reduction of fungal growth and lignin decomposition in needle litter by avian excreta , 2006 .
[130] T. Osono,et al. Immobilization of avian excreta-derived nutrients and reduced lignin decomposition in needle and twig litter in a temperate coniferous forest , 2006 .
[131] S. Yanai,et al. Effects of salmon carcasses on experimental stream ecosystems in Hokkaido, Japan , 2005, Ecological Research.
[132] B. Walton,et al. Contrasting effects of salamanders on forest-floor macro- and mesofauna in laboratory microcosms , 2005 .
[133] D. Wardle,et al. Ecological Linkages Between Aboveground and Belowground Biota , 2004, Science.
[134] J. Negishi,et al. Impacts of marine-derived nutrients on stream ecosystem functioning , 2003, Proceedings of the Royal Society of London. Series B: Biological Sciences.
[135] Mark A. Bradford,et al. Microbiota, fauna, and mesh size interactions in litter decomposition , 2002 .
[136] L. Oksanen,et al. Role of litter decomposition for the increased primary production in areas heavily grazed by reindeer: a litterbag experiment , 2002 .
[137] D. Wardle,et al. The effect of reindeer grazing on decomposition, mineralization and soil biota in a dry oligotrophic Scots pine forest , 2000 .
[138] M. Biondini,et al. Grazing intensity effects on litter decomposition and soil nitrogen mineralization , 1994 .
[139] J. Bryant,et al. Effects of Moose Browsing on Decomposition Rates of Birch Leaf Litter in a Subarctic Stream , 1991 .
[140] J. Gong,et al. Grazing directly or indirectly affect shoot and root litter decomposition in different decomposition stage by changing soil properties , 2022, CATENA.
[141] J. Poulsen,et al. Defaunation of large mammals alters understory vegetation and functional importance of invertebrates in an Afrotropical forest , 2020 .
[142] H. Throop,et al. Animal generation of green leaf litter in an arid shrubland enhances decomposition by altering litter quality and location , 2017 .
[143] C. LeRoy,et al. Salmon carcasses influence genetic linkages between forests and streams , 2016 .
[144] Shan Lin,et al. Effects of grazing and rainfall variability on root and shoot decomposition in a semi-arid grassland , 2009 .
[145] Yiqi Luo,et al. Elevated CO2 stimulates net accumulations of carbon and nitrogen in land ecosystems: a meta-analysis. , 2006, Ecology.
[146] R. Rosenthal. Meta-analytic procedures for social research , 1984 .