The Influence of Tree Diversity on Natural Enemies—a Review of the “Enemies” Hypothesis in Forests

Abstract Purpose of Review Natural enemies are an important component for forest functioning. By consuming herbivores, they can be effective top-down regulators of potential pest species. Tree mixtures are generally expected to have larger predator and parasitoid populations compared to monocultures. This assumption is based on the “enemies” hypothesis, a classical ecological concept predicting a positive relationship between plant diversity (and complexity) and natural enemies, which, in turn, should increase top-down control in more diverse environments. However, the “enemies” hypothesis has mostly been tested and supported in relatively simple agricultural ecosystems. Until recently, research in forests was sparse. We summarize the upcoming knowledge-base for forests and identify forest characteristics likely shaping relationships between tree diversity, natural enemies (abundance, species richness, diversity), and top-down control. We further identify possible implications for mixed species forestry and key knowledge gaps. Recent Findings Tree diversity (almost exclusively quantified as tree species richness) does not consistently increase enemy abundance, diversity, or result in herbivore control. Tests of the “enemies” hypothesis are largely based on aboveground natural enemies (mainly generalists) and have highly variable outcomes across taxa and study systems, sometimes even finding a decrease in predator diversity with increasing tree diversity. Recurrent effects of tree species identity and composition indicate that a closer focus on tree functional and phylogenetic diversity might help to foster a mechanistic understanding of the specific circumstances under which tree diversity can promote top-down control. Summary Our review suggests that the “enemies” hypothesis may not unambiguously apply to forests. With trees as structurally complex organisms, even low-diversity forests can maintain a high degree of habitat heterogeneity and may provide niches for many predator and parasitoid species, possibly blurring correlations between tree and natural enemy diversity. Several further factors, such as latitude, identity effects, intraguild predation, or functional and phylogenetic components of biodiversity, may confound the predictions of the “enemies” hypothesis. We identify topics needing more research to fully understand under which conditions tree diversity increases natural enemy diversity and top-down control—knowledge that will be crucial for forest management.

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Meta-analysis of tree diversity effects on the abundance, diversity and activity of herbivores' enemies

10.1101/2021.07.05.451117 ◽

2021 ◽

Author(s):

Alex Stemmelen ◽

Hervé Jactel ◽

Eckehard Brockerhoff ◽

Bastien Castagneyrol

Keyword(s):

Natural Enemies ◽

Natural Enemy ◽

Meta Analysis ◽

Mixed Forest ◽

Forest Tree ◽

Tree Diversity ◽

Enemies Hypothesis ◽

Natural Enemies Hypothesis ◽

Abundance And Diversity ◽

Diversity Effects

The natural enemies hypothesis predicts that the abundance and diversity of antagonists such as predators and parasitoids of herbivores increases with the diversity of plants, which can lead to more effective top-down control of insect herbivores. However, although the hypothesis has received large support in agricultural systems, fewer studies have been conducted in forest ecosystems and a comprehensive synthesis of previous research is still lacking. We conducted a meta-analysis of 65 publications comparing the diversity, abundance or activity of various groups of natural enemies (including birds, bats, spiders and insect parasitoids) in pure vs. mixed forest stands. We tested the effects of forest biome, natural enemy taxon and type of study (managed vs experimental forest). We found a significant positive effect of forest tree diversity on natural enemy abundance and diversity but not on their activity. The effect of tree diversity on natural enemies was stronger towards lower latitudes but was not contingent on the natural enemy taxon. Overall, our study contributes substantially toward a better understanding of the natural enemies hypothesis in forest systems and provides new insights about the mechanisms involved. Furthermore, we outline potential avenues for strengthening forest resistance to the growing threat of herbivorous insects.

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Effect of tree species identity and related habitat parameters on understorey bryophytes – interrelationships between bryophyte, soil and tree factors in a 50-year-old experimental forest

Plant and Soil ◽

10.1007/s11104-021-05074-w ◽

2021 ◽

Author(s):

Kaja Rola ◽

Vítězslav Plášek ◽

Katarzyna Rożek ◽

Szymon Zubek

Keyword(s):

Species Richness ◽

Tree Species ◽

Forest Floor ◽

Vascular Plant ◽

Soil Parameters ◽

Species Identity ◽

Habitat Factors ◽

Positive Correlations ◽

Old Trees ◽

Habitat Parameters

Abstract Aim Overstorey tree species influence both soil properties and microclimate conditions in the forest floor, which in turn can induce changes in ground bryophyte communities. The aim of the study was to investigate the effect of tree species identity and the most important habitat factors influencing understorey bryophytes. Methods We assessed the effect of 14 tree species and related habitat parameters, including soil parameters, vascular plant presence and light intensity on bryophytes in monospecific plots covered by nearly fifty-year-old trees in the Siemianice Experimental Forest (Poland). Results The canopy tree species determined bryophyte species richness and cover. The strongest differences were observed between plots with deciduous and coniferous trees. Soils with a more acidic pH and lower content of macronutrients supported larger bryophyte coverage. We also found a positive correlations between vascular plants and availability of light as well as bryophyte species richness. Conclusion Tree species identity and differences in habitat conditions in the forest floor lead to changes of ground bryophyte richness, cover and species composition. Consequently, the changes in the dominant tree species in the stand may result in significant repercussions on ground bryophyte communities. We indicated that the introduction of alien tree species, i.e. Quercus rubra, has an adverse effect on bryophyte communities and suggested that the selection of tree species that contribute to the community consistent with the potential natural vegetation is highly beneficial for maintaining ground bryophyte biodiversity.

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Disentangling tree species identity and richness effects on the herb layer: first results from a German tree diversity experiment

Journal of Vegetation Science ◽

10.1111/jvs.12281 ◽

2015 ◽

Vol 26 (4) ◽

pp. 742-755 ◽

Cited By ~ 15

Author(s):

Evy Ampoorter ◽

Lander Baeten ◽

Margot Vanhellemont ◽

Helge Bruelheide ◽

Michael Scherer-Lorenzen ◽

...

Keyword(s):

Tree Species ◽

Tree Diversity ◽

Herb Layer ◽

Species Identity ◽

First Results

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Tree species richness modulates water supply in the local tree neighbourhood: evidence from wood δ 13 C signatures in a large-scale forest experiment

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2020.3100 ◽

2021 ◽

Vol 288 (1946) ◽

pp. 20203100

Author(s):

Kirstin Jansen ◽

Goddert von Oheimb ◽

Helge Bruelheide ◽

Werner Härdtle ◽

Andreas Fichtner

Keyword(s):

Species Richness ◽

Water Supply ◽

Water Use ◽

Water Availability ◽

Tree Species ◽

Large Scale ◽

Isotope Composition ◽

Tree Diversity ◽

Tree Species Richness ◽

Neighbourhood Scale

Biodiversity is considered to mitigate the adverse effects of changing precipitation patterns. However, our understanding of how tree diversity at the local neighbourhood scale modulates the water use and leaf physiology of individual trees remains unclear. We made use of a large-scale tree diversity experiment in subtropical China to study eight tree species along an experimentally manipulated gradient of local neighbourhood tree species richness. Twig wood carbon isotope composition ( δ 13 C wood ) was used as an indicator for immediate leaf-level responses to water availability in relation to local neighbourhood conditions and a target tree's functional traits. Across species, a target tree's δ 13 C wood signatures decreased progressively with increasing neighbourhood species richness, with effects being strongest at high neighbourhood shading intensity. Moreover, the δ 13 C wood -shading relationship shifted from positive (thin-leaved species) or neutral (thick-leaved species) in conspecific to negative in heterospecific neighbourhoods, most likely owing to a lower interspecific competition for water and microclimate amelioration. This suggests that promoting tree species richness at the local neighbourhood scale may improve a tree's local water supply with potential effects for an optimized water-use efficiency of tree communities during drought. This assumption, however, requires validation by further studies that focus on mechanisms that regulate the water availability in mixtures.

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Tropical tree diversity mediates foraging and predatory effects of insectivorous birds

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2018.1842 ◽

2018 ◽

Vol 285 (1890) ◽

pp. 20181842 ◽

Cited By ~ 10

Author(s):

Colleen S. Nell ◽

Luis Abdala-Roberts ◽

Victor Parra-Tabla ◽

Kailen A. Mooney

Keyword(s):

Species Richness ◽

Indirect Effect ◽

Tree Species ◽

Attack Rate ◽

Tree Diversity ◽

Trophic Levels ◽

Tropical Tree ◽

Insectivorous Birds ◽

Bird Abundance ◽

Tree Species Richness

Biodiversity affects the structure of ecological communities, but little is known about the interactive effects of diversity across multiple trophic levels. We used a large-scale forest diversity experiment to investigate the effects of tropical tree species richness on insectivorous birds, and the subsequent indirect effect on predation rates by birds. Diverse plots (four tree species) had higher bird abundance (61%), phylogenetic diversity (61%), and functional diversity (55%) than predicted based on single-species monocultures, which corresponded to higher attack rates on artificial caterpillars (65%). Tree diversity effects on attack rate were driven by complementarity among tree species, with increases in attack rate observed on all tree species in polycultures. Attack rates on artificial caterpillars were higher in plots with higher bird abundance and diversity, but the indirect effect of tree species richness was mediated by bird diversity, providing evidence that diversity can interact across trophic levels with consequences tied to ecosystem services and function.

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Balancing Disturbance and Conservation in Agroecosystems to Improve Biological Control

Annual Review of Entomology ◽

10.1146/annurev-ento-011019-025143 ◽

2020 ◽

Vol 65 (1) ◽

pp. 81-100 ◽

Cited By ~ 7

Author(s):

John F. Tooker ◽

Matthew E. O'Neal ◽

Cesar Rodriguez-Saona

Keyword(s):

Biological Control ◽

Natural Enemies ◽

Natural Enemy ◽

Crop Production ◽

Agricultural Intensification ◽

Conservation Practices ◽

Insect Outbreaks ◽

Top Down ◽

Crop Fields ◽

Pest Outbreaks

Disturbances associated with agricultural intensification reduce our ability to achieve sustainable crop production. These disturbances stem from crop-management tactics and can leave crop fields more vulnerable to insect outbreaks, in part because natural-enemy communities often tend to be more susceptible to disturbance than herbivorous pests. Recent research has explored practices that conserve natural-enemy communities and reduce pest outbreaks, revealing that different components of agroecosystems can influence natural-enemy populations. In this review, we consider a range of disturbances that influence pest control provided by natural enemies and how conservation practices can mitigate or counteract disturbance. We use four case studies to illustrate how conservation and disturbance mitigation increase the potential for biological control and provide co-benefits for the broader agroecosystem. To facilitate the adoption of conservation practices that improve top-down control across significant areas of the landscape, these practices will need to provide multifunctional benefits, but should be implemented with natural enemies explicitly in mind.

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Multi-trophic communities re-establish with canopy cover and microclimate in a subtropical forest biodiversity experiment

Oecologia ◽

10.1007/s00442-021-04921-y ◽

2021 ◽

Author(s):

Felix Fornoff ◽

Michael Staab ◽

Chao-Dong Zhu ◽

Alexandra-Maria Klein

Keyword(s):

Species Richness ◽

Community Composition ◽

Natural Enemies ◽

Trophic Position ◽

Abiotic Factors ◽

Canopy Cover ◽

Tree Diversity ◽

Trophic Levels ◽

Tree Biomass ◽

Wasp Species

AbstractPlant diversity affects multi-trophic communities, but in young regrowth forests, where forest insects are in the process of re-establishment, other biotic and also abiotic factors might be more important. We studied cavity-nesting bees, wasps and their natural enemies along an experimental tree diversity gradient in subtropical South-East China. We compared insect communities of experimental young forests with communities of established natural forests nearby the experiment and tested for direct and indirect effects of tree diversity, tree basal area (a proxy of tree biomass), canopy cover and microclimate on bee and wasp community composition, abundance and species richness. Finally, we tested if the trophic levels of bees, herbivore-hunting wasps, spider-hunting wasps and their natural enemies respond similarly. Forest bee and wasp community composition re-established towards communities of the natural forest with increasing tree biomass and canopy cover. These factors directly and indirectly, via microclimatic conditions, increased the abundance of bees, wasps and their natural enemies. While bee and wasp species richness increased with abundance and both were not related to tree diversity, abundance increased directly with canopy cover, mediated by tree biomass. Abundance of natural enemies increased with host (bee and wasp) abundance irrespective of their trophic position. In conclusion, although maximizing tree diversity is an important goal of reforestation and forest conservation, rapid closure of canopies is also important for re-establishing communities of forest bees, wasps and their natural enemies.

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Comparison of forest regeneration in two sites with different primate abundances in Northwestern Ecuador

Revista de Biología Tropical ◽

10.15517/rbt.v64i2.18415 ◽

2016 ◽

Vol 64 (2) ◽

pp. 493 ◽

Cited By ~ 4

Author(s):

Bayron R. Calle-Rendón ◽

Mika Peck ◽

Sara E. Bennett ◽

Citlalli Morelos-Juarez ◽

Felipe Alfonso

Keyword(s):

Species Richness ◽

Tree Species ◽

Forest Regeneration ◽

Tree Diversity ◽

Primate Species ◽

Species Accumulation Curves ◽

Dispersal Syndrome ◽

Species Accumulation ◽

Accumulation Curves ◽

Understory Tree

There is increasing evidence that large-bodied primates play important roles as seed dispersers and in the maintenance of tree diversity in forest ecosystems. In this study we compared forest regeneration at two sites with differing primate abundances in the Ecuadorian Chocoan rainforest. We predicted: (1) significant differences in primate abundance between the two sites; (2) higher understory tree species richness and density at the site with greater primate abundance; (3) the site with lower primate abundance characterized by tree species dispersed by non-primate biotic agents and/or abiotic factors. We compared two sites, Tesoro Escondido (TE) a campesino cooperative, and the El Pambilar (EP) wildlife refuge that both maintain populations of mantled howler monkey (Alouatta palliata), the brown-headed spider monkey (Ateles fusciceps fusciceps) and the capuchin monkey (Cebus capucinus). We characterized canopy structure by point-quadrant sampling, determined primate abundance and sampled seedlings/saplings in 1 m2 plots, classifying tree species based on three dispersal syndromes: adapted for primate dispersal, dispersed by other biological agents, and abiotic dispersal. We compared sites in terms of primate abundance (groups and individuals observed per day) and regeneration characteristics (overall density, species richness, and dispersal syndrome). We carried out within site comparisons and constructed understory tree species accumulation curves. Overall the forests were structurally similar - with significantly higher densities of A. f. fusciceps at TE. Encounter rates for the other two primate species were similar at both sites. Understory tree density and species richness was significantly higher in TE with no stabilization of tree species accumulation curves. The species accumulation curve for understory trees at EP stabilized. Higher densities and species richness of primate dispersed tree species were observed at TE, with non-primate biotically dispersed tree species the dominant dispersal syndrome at both sites. Our observations are consistent with those from other studies investigating the role of large-bodied frugivorous primates in forest regeneration, and point to a general pattern: future lowland tropical forest tree diversity depends on maintaining robust populations of large primate species in these systems. It is highly probable that the maintenance of high levels of tree diversity in Chocoan rainforests is dependent on the conservation of its largest resident primate, the critically endangered brown-headed spider monkey (A. f. fusciceps).

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Neither global nor consistent: a technical comment on the tree diversity-productivity analysis of Liang et al. (2016)

10.1101/524363 ◽

2019 ◽

Cited By ~ 3

Author(s):

Carsten F. Dormann ◽

Helge Schneider ◽

Jonas Gorges

Keyword(s):

Species Richness ◽

Tree Species ◽

Forest Productivity ◽

Local Scale ◽

Tree Diversity ◽

Productivity Analysis ◽

Combine Data ◽

Relative Measure ◽

Tree Species Richness ◽

Global Consistency

AbstractThe publication of Liang et al. (2016, Science) seems to demonstrate very clearly that increasing tree species richness substantially increases forest productivity. To combine data from very different ecoregions, the authors constructed a relative measure of tree species richness. This relative richness however confounds plot-level tree species richness and the polar-tropical gradient of tree species richness. We re-analysed their orginal data, computing a regional measure of tree species richness and addressing several other issues in their analysis. We find that there is virtually no effect of relative tree species richness on productivity when computing species richness at the local scale. Also, different ecoregions have very different relationships between tree species richness and productivity. Thus, neither the “global” consistency nor the actual effect can be confirmed.

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Drivers of understorey biomass – tree species identity is more important than richness in a young forest

Journal of Plant Ecology ◽

10.1093/jpe/rtab004 ◽

2021 ◽

Author(s):

Markus S Germany ◽

Helge Bruelheide ◽

Alexandra Erfmeier

Keyword(s):

Species Richness ◽

Tree Species ◽

Ecosystem Functioning ◽

Temporal Dynamics ◽

Light Transmittance ◽

Productivity Change ◽

Species Identity ◽

Tree Species Richness ◽

Young Forest ◽

Species Richness Gradient

Abstract Aims Positive biodiversity ecosystem functioning relationships have been widely reported, predominately from grassland ecosystems. However, this does not necessarily have to apply accordingly in more complex situations such as in forests across different vertical strata. For instance, overstorey tree species richness has been shown to be associated with a lower understorey productivity. Whether or not tree species richness effects add to understorey productivity by increasing (i.e. due to habitat heterogeneity) or reducing resource availability (i.e. through increasing competition) and whether understorey productivity is indeed being governed more strongly by tree species identity are likely to change over time. Moreover, studies also suggested that richness-productivity relationships change with the environmental context. Using an experimental forest plantation with manipulated tree species richness, this study examined these temporal and environmental dynamics across strata. Methods In the context of the Biodiversity-Ecosystem Functioning project in subtropical China (BEF-China), we made use of understorey biomass samples repeatedly collected over a time period of three years along a tree species richness gradient. The effects of tree species richness, tree species identities and time were studied across different environmental treatments for their impact on understorey biomass. Important Findings While we found significant and consistent tree layer identity effects on understorey biomass, no such effect was encountered for tree species richness. Our results also indicate that among structural layers in forests, there might not be a single, generalizable overstorey species richness- understorey productivity relationship, and that the extent as to which overstorey-related environmental factors such as light transmittance contribute to understorey productivity change with time. Overall, we demonstrate that temporal dynamics should be considered when studying relationship among structural layers in forests.

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