Your search keyword '"Tyler C. Coverdale"' showing total 15 results

1. Unravelling the relationship between plant diversity and vegetation structural complexity: A review and theoretical framework

Author

Tyler C. Coverdale and Andrew B. Davies

Subjects

Ecology, Plant Science, Ecology, Evolution, Behavior and Systematics

Published

2023

2. Experimental insect suppression causes loss of induced, but not constitutive, resistance in Solanum carolinense

Author

Tyler C. Coverdale and Anurag A. Agrawal

Subjects

Coleoptera, Insecticides, Insecta, Animals, Herbivory, Solanum, Ecology, Evolution, Behavior and Systematics

Abstract

Spatiotemporal variation in herbivory is a major driver of intraspecific variation in plant defense. Comparatively little is known, however, about how changes in herbivory regime affect the balance of constitutive and induced resistance, which are often considered alternative defensive strategies. Here, we investigated how nearly a decade of insect herbivore suppression affected constitutive and induced resistance in horsenettle (Solanum carolinense), a widespread herbaceous perennial. We allowed replicated horsenettle populations to respond to the presence or absence of herbivores by applying insecticide to all plants in half of 16 field plots. Horsenettle density rapidly increased in response to insecticide treatment, and this effect persisted for at least 4 years after the cessation of herbivore suppression. We subsequently grew half-sibling families from seeds collected during and shortly after insecticide treatment in a common garden and found strong effects of insect suppression on induced resistance. Feeding trials in field mesocosms with false Colorado potato beetles (Leptinotarsa juncta), a common specialist herbivore, revealed that multiyear herbivore suppression drove rapid attenuation of induced resistance: offspring of plants from insect-suppression plots exhibited a near-complete loss of induced resistance to beetles, whereas those from control plots incurred ~70% less damage after experimental induction. Plants from insect-suppression plots also had ~40% greater constitutive resistance compared with those from control plots, although this difference was not statistically significant. We nonetheless detected a strong trade-off between constitutive and induced resistance across families. In contrast, the constitutive expression of trypsin inhibitors (TI), an important chemical defense trait in horsenettle, was reduced by 20% in the offspring of plants from insect-suppression plots relative to those from control plots. However, TIs were induced to an equal extent whether or not insect herbivores had been historically suppressed. Although several defense and performance traits (prickle density, TI concentration, resistance against false Colorado potato beetles and flea beetles, biomass, and seed mass) varied markedly across families, no traits exhibited significant pairwise correlations. Overall, our results indicate that, whereas the divergent responses of multiple defense traits to insect suppression led to comparatively small changes in overall constitutive resistance, they significantly reduced induced resistance against false Colorado potato beetle.

Published

2022

3. Ecological consequences of large herbivore exclusion in an <scp>A</scp> frican savanna: 12 years of data from the <scp>UHURU</scp> experiment

Author

Jesse M. Alston, Courtney G. Reed, Leo M. Khasoha, Bianca R. P. Brown, Gilbert Busienei, Nathaniel Carlson, Tyler C. Coverdale, Megan Dudenhoeffer, Marissa A. Dyck, John Ekeno, Abdikadir A. Hassan, Rhianna Hohbein, Rhiannon P. Jakopak, Buas Kimiti, Samson Kurukura, Peter Lokeny, Allison M. Louthan, Simon Musila, Paul M. Musili, Tosca Tindall, Sarah Weiner, Tyler R. Kartzinel, Todd M. Palmer, Robert M. Pringle, and Jacob R. Goheen

Subjects

Mammals, Animals, Herbivory, Grassland, Kenya, Ecosystem, Ecology, Evolution, Behavior and Systematics

Abstract

Diverse communities of large mammalian herbivores (LMH), once widespread, are now rare. LMH exert strong direct and indirect effects on community structure and ecosystem functions, and measuring these effects is important for testing ecological theory and for understanding past, current, and future environmental change. This in turn requires long-term experimental manipulations, owing to the slow and often nonlinear responses of populations and assemblages to LMH removal. Moreover, the effects of particular species or body-size classes within diverse LMH guilds are difficult to pinpoint, and the magnitude and even direction of these effects often depends on environmental context. Since 2008, we have maintained the Ungulate Herbivory Under Rainfall Uncertainty (UHURU) experiment, a series of size-selective LMH exclosures replicated across a rainfall/productivity gradient in a semiarid Kenyan savanna. The goals of the UHURU experiment are to measure the effects of removing successively smaller size classes of LMH (mimicking the process of size-biased extirpation) and to establish how these effects are shaped by spatial and temporal variation in rainfall. The UHURU experiment comprises three LMH-exclusion treatments and an unfenced control, applied to nine randomized blocks of contiguous 1-ha plots (n = 36). The fenced treatments are MEGA (exclusion of megaherbivores, elephant and giraffe), MESO (exclusion of herbivores ≥40 kg), and TOTAL (exclusion of herbivores ≥5 kg). Each block is replicated three times at three sites across the 20-km rainfall gradient, which has fluctuated over the course of the experiment. The first 5 years of data were published previously (Ecological Archives E095-064) and have been used in numerous studies. Since that publication, we have (1) continued to collect data following the original protocols, (2) improved the taxonomic resolution and accuracy of plant and small-mammal identifications, and (3) begun collecting several new data sets. Here, we present updated and extended raw data from the first 12 years of the UHURU experiment (2008-2019). Data include daily rainfall data throughout the experiment; annual surveys of understory plant communities; annual censuses of woody-plant communities; annual measurements of individually tagged woody plants; monthly monitoring of flowering and fruiting phenology; every-other-month small-mammal mark-recapture data; and quarterly large-mammal dung surveys. There are no copyright restrictions; notification of when and how data are used is appreciated and users of UHURU data should cite this data paper when using the data.

Published

2022

4. Trophic rewilding revives biotic resistance to shrub invasion

Author

Tyler R. Kartzinel, Johan Pansu, Arjun B. Potter, Michael J. Peel, Matthew C. Hutchinson, Ana Gledis da Conceição, Robert M. Pringle, Joshua H. Daskin, Marc Stalmans, Jennifer A. Guyton, and Tyler C. Coverdale

Subjects

0106 biological sciences, 0303 health sciences, Biomass (ecology), Herbivore, Ungulate, Ecology, Resistance (ecology), biology, ved/biology, ved/biology.organism_classification_rank.species, Introduced species, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Shrub, 03 medical and health sciences, Ecosystem, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Trophic level

Abstract

Trophic rewilding seeks to rehabilitate degraded ecosystems by repopulating them with large animals, thereby re-establishing strong top-down interactions. Yet there are very few tests of whether such initiatives can restore ecosystem structure and functions, and on what timescales. Here we show that war-induced collapse of large-mammal populations in Mozambique's Gorongosa National Park exacerbated woody encroachment by the invasive shrub Mimosa pigra-considered one of the world's 100 worst invasive species-and that one decade of concerted trophic rewilding restored this invasion to pre-war baseline levels. Mimosa occurrence increased between 1972 and 2015, a period encompassing the near extirpation of large herbivores during the Mozambican Civil War. From 2015 to 2019, mimosa abundance declined as ungulate biomass recovered. DNA metabarcoding revealed that ruminant herbivores fed heavily on mimosa, and experimental exclosures confirmed the causal role of mammalian herbivory in containing shrub encroachment. Our results provide mechanistic evidence that trophic rewilding has rapidly revived a key ecosystem function (biotic resistance to a notorious woody invader), underscoring the potential for restoring ecological health in degraded protected areas.

Published

2020

5. Predator-induced collapse of niche structure and species coexistence

Author

Thomas W. Schoener, Jonathan B. Losos, Tyler C. Coverdale, Joshua H. Daskin, Matthew C. Hutchinson, Naomi A Man In 't Veld, Charles C.Y. Xu, Johanna E. Wegener, Todd M. Palmer, Dominic A. Evangelista, Jason J. Kolbe, Kiyoko M. Gotanda, Kena Fox-Dobbs, Robert M. Pringle, David A. Spiller, Rowan D. H. Barrett, Timothy J. Thurman, and Tyler R. Kartzinel

Subjects

0106 biological sciences, 0301 basic medicine, Ecological niche, Multidisciplinary, biology, Ecology, Interspecific competition, Brown anole, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Anolis, Predation, 03 medical and health sciences, 030104 developmental biology, Anolis smaragdinus, Trophic level, Apex predator

Abstract

Biological invasions are both a pressing environmental challenge and an opportunity to investigate fundamental ecological processes, such as the role of top predators in regulating biodiversity and food-web structure. In whole-ecosystem manipulations of small Caribbean islands on which brown anole lizards (Anolis sagrei) were the native top predator, we experimentally staged invasions by competitors (green anoles, Anolis smaragdinus) and/or new top predators (curly-tailed lizards, Leiocephalus carinatus). We show that curly-tailed lizards destabilized the coexistence of competing prey species, contrary to the classic idea of keystone predation. Fear-driven avoidance of predators collapsed the spatial and dietary niche structure that otherwise stabilized coexistence, which intensified interspecific competition within predator-free refuges and contributed to the extinction of green-anole populations on two islands. Moreover, whereas adding either green anoles or curly-tailed lizards lengthened food chains on the islands, adding both species reversed this effect—in part because the apex predators were trophic omnivores. Our results underscore the importance of top-down control in ecological communities, but show that its outcomes depend on prey behaviour, spatial structure, and omnivory. Diversity-enhancing effects of top predators cannot be assumed, and non-consumptive effects of predation risk may be a widespread constraint on species coexistence. Whole-ecosystem manipulations of Caribbean islands occupied by brown anoles, involving the addition of competitors (green anoles) and/or top predators (curly-tailed lizards), demonstrate that predator introductions can alter the ecological niches and destabilize the coexistence of competing prey species.

Published

2019

6. Large herbivores suppress liana infestation in an African savanna

Author

Jacob R. Goheen, Robert M. Pringle, Tyler R. Kartzinel, Todd M. Palmer, Matthew C. Hutchinson, Tyler C. Coverdale, Corina E. Tarnita, Mahesh Sankaran, David J. Augustine, Amanda Savagian, and Ryan D. O’Connell

Subjects

0106 biological sciences, Livestock, Defaunation, Elephants, Wildlife, Animals, Wild, Giraffes, Biology, medicine.disease_cause, 010603 evolutionary biology, 01 natural sciences, Trees, Food Preferences, Abundance (ecology), Infestation, medicine, Animals, Humans, Herbivory, Ecosystem, Environmental Restoration and Remediation, 2. Zero hunger, Herbivore, Multidisciplinary, Cynanchum, Ecology, Plant community, 15. Life on land, Biological Sciences, Liana, Exclosure, Africa, 010606 plant biology & botany

Abstract

African savannas are the last stronghold of diverse large-mammal communities, and a major focus of savanna ecology is to understand how these animals affect the relative abundance of trees and grasses. However, savannas support diverse plant life-forms, and human-induced changes in large-herbivore assemblages-declining wildlife populations and their displacement by livestock-may cause unexpected shifts in plant community composition. We investigated how herbivory affects the prevalence of lianas (woody vines) and their impact on trees in an East African savanna. Although scarce (

Published

2021

7. Evolution of shade tolerance is associated with attenuation of shade avoidance and reduced phenotypic plasticity in North American milkweeds

Author

Tyler C. Coverdale and Anurag Agrawal

Subjects

Phenotypic plasticity, biology, Specific leaf area, Light, Ecology, fungi, social sciences, Plant Science, biology.organism_classification, Adaptation, Physiological, humanities, Plant Leaves, Shade avoidance, Habitat, North America, Genetics, Colonization, Evolutionary ecology, Shade tolerance, health care economics and organizations, Ecology, Evolution, Behavior and Systematics, Asclepias, Phylogeny

Abstract

PREMISE Mismatches between light conditions and light-capture strategy can reduce plant performance and prevent colonization of novel habitats. Although light-capture strategies tend to be highly conserved among closely related species, evolutionary transitions from shaded to unshaded habitats (and vice versa) occur in numerous plant lineages. METHODS We combined phylogenetic approaches with field and greenhouse experiments to investigate evolutionary constraints on light-capture strategy in North American milkweeds (genus Asclepias) and to determine whether colonization of shaded habitats in this heliophilic clade is associated with reduced plasticity and attenuation of the shade avoidance response. RESULTS Colonization of shaded habitats has occurred at least 10 times in this genus, including at least once in each major North American clade. Evolutionary transitions between habitats exhibit strong directional bias, with shifts from full-sun to shaded habitats occurring at least three times as often as the opposite transition. In field and greenhouse experiments, sun species responded to shade by increasing internode length, height, and specific leaf area, consistent with the shade avoidance response; paired shade species exhibited reduced plasticity overall, and only one trait (specific leaf area) responded to experimental shade. CONCLUSIONS Our results suggest that milkweeds colonized shaded environments multiple times using a light-capture strategy distinct from the ancestral (putatively shade avoidant) strategy, including a general attenuation of plasticity in response to variable light conditions. This pattern bolsters the notion that shade avoidance and tolerance represent divergent evolutionary strategies for maximizing performance under qualitatively different types of shade.

Published

2020

8. Trophic rewilding revives biotic resistance to shrub invasion

Author

Jennifer A, Guyton, Johan, Pansu, Matthew C, Hutchinson, Tyler R, Kartzinel, Arjun B, Potter, Tyler C, Coverdale, Joshua H, Daskin, Ana Gledis, da Conceição, Mike J S, Peel, Marc E, Stalmans, and Robert M, Pringle

Subjects

Mammals, Conservation of Natural Resources, Animals, Herbivory, Introduced Species, Ecosystem

Abstract

Trophic rewilding seeks to rehabilitate degraded ecosystems by repopulating them with large animals, thereby re-establishing strong top-down interactions. Yet there are very few tests of whether such initiatives can restore ecosystem structure and functions, and on what timescales. Here we show that war-induced collapse of large-mammal populations in Mozambique's Gorongosa National Park exacerbated woody encroachment by the invasive shrub Mimosa pigra-considered one of the world's 100 worst invasive species-and that one decade of concerted trophic rewilding restored this invasion to pre-war baseline levels. Mimosa occurrence increased between 1972 and 2015, a period encompassing the near extirpation of large herbivores during the Mozambican Civil War. From 2015 to 2019, mimosa abundance declined as ungulate biomass recovered. DNA metabarcoding revealed that ruminant herbivores fed heavily on mimosa, and experimental exclosures confirmed the causal role of mammalian herbivory in containing shrub encroachment. Our results provide mechanistic evidence that trophic rewilding has rapidly revived a key ecosystem function (biotic resistance to a notorious woody invader), underscoring the potential for restoring ecological health in degraded protected areas.

Published

2019

9. Elephants in the understory: opposing direct and indirect effects of consumption and ecosystem engineering by megaherbivores

Author

Todd M. Palmer, Tyler C. Coverdale, Robert K. Shriver, Tyler R. Kartzinel, Robert M. Pringle, Jacob R. Goheen, Kathryn L. Grabowski, and Abdikadir A. Hassan

Subjects

0106 biological sciences, Conservation of Natural Resources, Herbivore, Biomass (ecology), Ecology, 010604 marine biology & hydrobiology, Elephants, Biodiversity, Understory, Biology, 010603 evolutionary biology, 01 natural sciences, Disturbance (ecology), Animals, Ecosystem, Herbivory, Species richness, Ecology, Evolution, Behavior and Systematics, Environmental Monitoring, Trophic level

Abstract

Positive indirect effects of consumers on their resources can stabilize food webs by preventing overexploitation, but the coupling of trophic and non-trophic interactions remains poorly integrated into our understanding of community dynamics. Elephants engineer African savanna ecosystems by toppling trees and breaking branches, and although their negative effects on trees are well documented, their effects on small-statured plants remain poorly understood. Using data on 117 understory plant taxa collected over 7 yr within 36 1-ha experimental plots in a semi-arid Kenyan savanna, we measured the strength and direction of elephant impacts on understory vegetation. We found that elephants had neutral effects on most (83-89%) species, with a similar frequency of positive and negative responses among the remainder. Overall, estimated understory biomass was 5-14% greater in the presence of elephants across a range of rainfall levels. Whereas direct consumption likely accounts for the negative effects, positive effects are presumably indirect. We hypothesized that elephants create associational refuges for understory plants by damaging tree canopies in ways that physically inhibit feeding by other large herbivores. As predicted, understory biomass and species richness beneath elephant-damaged trees were 55% and 21% greater, respectively, than under undamaged trees. Experimentally simulated elephant damage increased understory biomass by 37% and species richness by 49% after 1 yr. Conversely, experimentally removing elephant damaged branches decreased understory biomass by 39% and richness by 30% relative to sham-manipulated trees. Camera-trap surveys revealed that elephant damage reduced the frequency of herbivory by 71%, whereas we detected no significant effect of damage on temperature, light, or soil moisture. We conclude that elephants locally facilitate understory plants by creating refuges from herbivory, which countervails the direct negative effects of consumption and enhances larger-scale biomass and diversity by promoting the persistence of rare and palatable species. Our results offer a counterpoint to concerns about the deleterious impacts of elephant "overpopulation" that should be considered in debates over wildlife management in African protected areas: understory species comprise the bulk of savanna plant biodiversity, and their responses to elephants are buffered by the interplay of opposing consumptive and non-consumptive interactions.

Published

2016

10. Predator-induced collapse of niche structure and species coexistence

Author

Robert M, Pringle, Tyler R, Kartzinel, Todd M, Palmer, Timothy J, Thurman, Kena, Fox-Dobbs, Charles C Y, Xu, Matthew C, Hutchinson, Tyler C, Coverdale, Joshua H, Daskin, Dominic A, Evangelista, Kiyoko M, Gotanda, Naomi, A Man In 't Veld, Johanna E, Wegener, Jason J, Kolbe, Thomas W, Schoener, David A, Spiller, Jonathan B, Losos, and Rowan D H, Barrett

Subjects

Male, Competitive Behavior, Food Chain, Species Specificity, Predatory Behavior, West Indies, Animals, Female, Lizards, Biodiversity, Feeding Behavior, Biological Evolution, Biota

Abstract

Biological invasions are both a pressing environmental challenge and an opportunity to investigate fundamental ecological processes, such as the role of top predators in regulating biodiversity and food-web structure. In whole-ecosystem manipulations of small Caribbean islands on which brown anole lizards (Anolis sagrei) were the native top predator, we experimentally staged invasions by competitors (green anoles, Anolis smaragdinus) and/or new top predators (curly-tailed lizards, Leiocephalus carinatus). We show that curly-tailed lizards destabilized the coexistence of competing prey species, contrary to the classic idea of keystone predation. Fear-driven avoidance of predators collapsed the spatial and dietary niche structure that otherwise stabilized coexistence, which intensified interspecific competition within predator-free refuges and contributed to the extinction of green-anole populations on two islands. Moreover, whereas adding either green anoles or curly-tailed lizards lengthened food chains on the islands, adding both species reversed this effect-in part because the apex predators were trophic omnivores. Our results underscore the importance of top-down control in ecological communities, but show that its outcomes depend on prey behaviour, spatial structure, and omnivory. Diversity-enhancing effects of top predators cannot be assumed, and non-consumptive effects of predation risk may be a widespread constraint on species coexistence.

Published

2018

11. Defence emergence during early ontogeny reveals important differences between spines, thorns and prickles

Author

Tyler C. Coverdale

Subjects

musculoskeletal diseases, Ontogeny, Original Articles, Plant Science, Plants, Biology, musculoskeletal system, Plant Leaves, Evolutionary biology, Commentary, Animals, Herbivory, Plant Structures, Ecosystem

Abstract

BACKGROUND AND AIMS: Herbivory by large mammals imposes a critical recruitment bottleneck on plants in many systems. Spines defend plants against large herbivores, and how early they emerge in saplings may be one of the strongest predictors of sapling survival in herbivore-rich environments. Yet little effort has been directed at understanding the variability in spine emergence across saplings. METHODS: We present a multispecies study examining whether and how sapling size, spine type and species' environmental niche (light and precipitation environment) influence early emergence and biomass investment in spines. A phylogenetically diverse pool of 45 species possessing different spine types (spines, prickles and thorns; that are derived from distinct plant organs: leaf, epidermis or cortex, and branch, respectively), were grown under common-garden conditions, and patterns of spine emergence and biomass allocation to spines at 5 and 15 weeks after transplanting were characterized. KEY RESULTS: Spine type and species' resource niche were the main factors driving early emergence and investment patterns. Spines emerged earliest in leaf spine-bearing species, and latest in thorn-bearing species. The probability of early spine emergence increased with decreasing precipitation, and was greater in species from open than from closed habitats. Sapling investment in spines changed with plant mass but was contingent on spine type and habitat type. CONCLUSIONS: Different spine types have strikingly different timing of expression, suggesting that developmental origins of spines play a critical role in sapling defences. Furthermore, species from different precipitation and light environments (open vs. closed habitats) showed contrasting patterns of early spine expression, suggesting that resource limitation in their native range may have driven divergent evolution of early defence expression.

Published

2019

12. DNA metabarcoding illuminates dietary niche partitioning by African large herbivores

Author

Patricia Chen, David L. Erickson, Tyler C. Coverdale, W. John Kress, Tyler R. Kartzinel, Wei Wang, Maria Kuzmina, Robert M. Pringle, and Daniel I. Rubenstein

Subjects

Herbivore, Multidisciplinary, Ecology, Grazing, Biodiversity, Niche differentiation, food and beverages, Plains zebra, Population ecology, Biology, Theoretical ecology, biology.organism_classification, Trophic level

Abstract

Niche partitioning facilitates species coexistence in a world of limited resources, thereby enriching biodiversity. For decades, biologists have sought to understand how diverse assemblages of large mammalian herbivores (LMH) partition food resources. Several complementary mechanisms have been identified, including differential consumption of grasses versus nongrasses and spatiotemporal stratification in use of different parts of the same plant. However, the extent to which LMH partition food-plant species is largely unknown because comprehensive species-level identification is prohibitively difficult with traditional methods. We used DNA metabarcoding to quantify diet breadth, composition, and overlap for seven abundant LMH species (six wild, one domestic) in semiarid African savanna. These species ranged from almost-exclusive grazers to almost-exclusive browsers: Grass consumption inferred from mean sequence relative read abundance (RRA) ranged from >99% (plains zebra) to

Published

2015

13. Termite mounds can increase the robustness of dryland ecosystems to climatic change

Author

Simon A. Levin, Kelly K. Caylor, Corina E. Tarnita, Efrat Sheffer, Tyler C. Coverdale, Robert M. Pringle, Jennifer A. Guyton, and Juan A. Bonachela

Subjects

Multidisciplinary, Ecology, media_common.quotation_subject, fungi, Climate change, Robustness (evolution), Global change, Vegetation, Arid, Substrate (marine biology), Desertification, QA273, Environmental science, Ecosystem, media_common

Abstract

Self-organized spatial vegetation patterning is widespread and has been described using models of scale-dependent feedback between plants and water on homogeneous substrates. As rainfall decreases, these models yield a characteristic sequence of patterns with increasingly sparse vegetation, followed by sudden collapse to desert. Thus, the final, spot-like pattern may provide early warning for such catastrophic shifts. In many arid ecosystems, however, termite nests impart substrate heterogeneity by altering soil properties, thereby enhancing plant growth. We show that termite-induced heterogeneity interacts with scale-dependent feedbacks to produce vegetation patterns at different spatial grains. Although the coarse-grained patterning resembles that created by scale-dependent feedback alone, it does not indicate imminent desertification. Rather, mound-field landscapes are more robust to aridity, suggesting that termites may help stabilize ecosystems under global change.

Published

2015

14. Good neighbors make good defenses: associational refuges reduce defense investment in African savanna plants

Author

Jacob R. Goheen, Robert M. Pringle, Tyler C. Coverdale, and Todd M. Palmer

Subjects

0106 biological sciences, Herbivore, Resistance (ecology), Ecology, Acacia, Plant community, Interspecific competition, Biology, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Grassland, Intraspecific competition, Trees, Habitat, Plant defense against herbivory, Animals, Herbivory, Ecology, Evolution, Behavior and Systematics, Ecosystem, 010606 plant biology & botany

Abstract

Intraspecific variation in plant defense phenotype is common and has wide-ranging ecological consequences. Yet prevailing theories of plant defense allocation, which primarily account for interspecific differences in defense phenotype, often fail to predict intraspecific patterns. Furthermore, although individual variation in defense phenotype is often attributed to ecological interactions, few general mechanisms have been proposed to explain the ubiquity of variable defense phenotype within species. Here, we show experimentally that associational refuges and induced resistance interact to create predictable intraspecific variation in defense phenotype in African savanna plants. Physically defended species from four families (Acanthaceae, Asparagaceae, Cactaceae, and Solanaceae) growing in close association with spinescent Acacia trees had 39-78% fewer spines and thorns than did isolated conspecifics. For a subset of these species, we used a series of manipulative experiments to show that this variability is maintained primarily by a reduction in induced responses among individuals that seldom experience mammalian herbivory, whether due to association with Acacia trees or to experimental herbivore exclusion. Unassociated plants incurred 4- to 16-fold more browsing damage than did associated individuals and increased spine density by 16-38% within one month following simulated browsing. In contrast, experimental clipping induced no net change in spine density among plants growing beneath Acacia canopies or inside long-term herbivore exclosures. Associated and unassociated individuals produced similar numbers of flowers and seeds, but seedling recruitment and survival were vastly greater in refuge habitats, suggesting a net fitness benefit of association. We conclude that plant-plant associations consistently decrease defense investment in this system by reducing both the frequency of herbivory and the intensity of induced responses, and that inducible responses enable plants to capitalize on such associations in heterogeneous environments. Given the prevalence of associational and induced defenses in plant communities worldwide, our results suggest a potentially general mechanism by which biotic interactions might predictably shape intraspecific variation in plant defense phenotype.

Published

2018

15. Ecological feedbacks. Termite mounds can increase the robustness of dryland ecosystems to climatic change

Author

Juan A, Bonachela, Robert M, Pringle, Efrat, Sheffer, Tyler C, Coverdale, Jennifer A, Guyton, Kelly K, Caylor, Simon A, Levin, and Corina E, Tarnita

Subjects

Conservation of Natural Resources, Soil, Climate Change, Rain, Animals, Plant Development, Water, Isoptera, Desert Climate, Models, Biological, Ecosystem, Feedback

Abstract

Self-organized spatial vegetation patterning is widespread and has been described using models of scale-dependent feedback between plants and water on homogeneous substrates. As rainfall decreases, these models yield a characteristic sequence of patterns with increasingly sparse vegetation, followed by sudden collapse to desert. Thus, the final, spot-like pattern may provide early warning for such catastrophic shifts. In many arid ecosystems, however, termite nests impart substrate heterogeneity by altering soil properties, thereby enhancing plant growth. We show that termite-induced heterogeneity interacts with scale-dependent feedbacks to produce vegetation patterns at different spatial grains. Although the coarse-grained patterning resembles that created by scale-dependent feedback alone, it does not indicate imminent desertification. Rather, mound-field landscapes are more robust to aridity, suggesting that termites may help stabilize ecosystems under global change.

Published

2015