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887 results on '"Sanders, Nathan J."'

1. The global distribution of known and undiscovered ant biodiversity

Author

Kass, Jamie M, Guénard, Benoit, Dudley, Kenneth L, Jenkins, Clinton N, Azuma, Fumika, Fisher, Brian L, Parr, Catherine L, Gibb, Heloise, Longino, John T, Ward, Philip S, Chao, Anne, Lubertazzi, David, Weiser, Michael, Jetz, Walter, Guralnick, Robert, Blatrix, Rumsaïs, Lauriers, James Des, Donoso, David A, Georgiadis, Christos, Gomez, Kiko, Hawkes, Peter G, Johnson, Robert A, Lattke, John E, MacGown, Joe A, Mackay, William, Robson, Simon, Sanders, Nathan J, Dunn, Robert R, and Economo, Evan P

Subjects
Life Below Water, Animals, Ants, Biodiversity, Ecosystem, Invertebrates, Phylogeny, Vertebrates
Abstract

Invertebrates constitute the majority of animal species and are critical for ecosystem functioning and services. Nonetheless, global invertebrate biodiversity patterns and their congruences with vertebrates remain largely unknown. We resolve the first high-resolution (~20-km) global diversity map for a major invertebrate clade, ants, using biodiversity informatics, range modeling, and machine learning to synthesize existing knowledge and predict the distribution of undiscovered diversity. We find that ants and different vertebrate groups have distinct features in their patterns of richness and rarity, underscoring the need to consider a diversity of taxa in conservation. However, despite their phylogenetic and physiological divergence, ant distributions are not highly anomalous relative to variation among vertebrate clades. Furthermore, our models predict that rarity centers largely overlap (78%), suggesting that general forces shape endemism patterns across taxa. This raises confidence that conservation of areas important for small-ranged vertebrates will benefit invertebrates while providing a "treasure map" to guide future discovery.

Published
2022

4. Herbarium specimens reveal increasing herbivory over the past century

Author

Meineke, Emily K, Classen, Aimée T, Sanders, Nathan J, and Davies, T Jonathan

Subjects
Climate Action, climate change, global change ecology, herbarium, herbivory, historical data, museum specimen, urbanization, warming, Environmental Sciences, Biological Sciences, Agricultural and Veterinary Sciences, Ecology
Abstract

Predicting how ecological interactions will respond to global change is a major challenge. Plants and their associated insect herbivores compose much of macroscopic diversity, yet how their interactions have been altered by recent environmental change remains underexplored. To address this gap, we quantified herbivory on herbarium specimens of four plant species with records extending back 112 years. Our study focused on the northeastern US, where temperatures have increased rapidly over the last few decades. This region also represents a range of urban development, a form of global change that has shown variable effects on herbivores in the past studies. Herbarium specimens collected in the early 2000s were 23% more likely to be damaged by herbivores than those collected in the early 1900s. Herbivory was greater following warmer winters and at low latitudes, suggesting that climate warming may drive increasing insect damage over time. In contrast, human population densities were negatively associated with herbivore damage. To explore whether changes in insect occurrence or abundance might explain shifts in herbivory, we used insect observational records to build climate occupancy models for lepidopteran herbivores (butterflies and moths) of our focal plant species. These models show that higher winter temperatures were associated with higher probability of insect herbivore presence, while urbanization was associated with reduced probability of herbivore presence, supporting a link between insect herbivore occurrence and herbivory mediated through environment. Synthesis. Using a temporal record of plant herbivory that spans over a century, we show that both temperature and urbanization influence insect damage to plants, but in very different ways. Our results indicate that damage to plants by insect herbivores will likely continue to increase through time in the northeastern US as global temperatures rise, but that urbanization may disrupt local effects of winter warming on herbivory by excluding certain herbivores. These changes may scale to shape ecosystem processes that are driven by herbivory, including plant productivity.

Published
2019

8. A global database of ant species abundances

Author

Gibb, Heloise, Dunn, Rob R, Sanders, Nathan J, Grossman, Blair F, Photakis, Manoli, Abril, Silvia, Agosti, Donat, Andersen, Alan N, Angulo, Elena, Armbrecht, Inge, Arnan, Xavier, Baccaro, Fabricio B, Bishop, Tom R, Boulay, Raphaël, Brühl, Carsten, Castracani, Cristina, Cerda, Xim, Del Toro, Israel, Delsinne, Thibaut, Diaz, Mireia, Donoso, David A, Ellison, Aaron M, Enriquez, Martha L, Fayle, Tom M, Feener, Donald H, Fisher, Brian L, Fisher, Robert N, Fitzpatrick, Matthew C, Gómez, Crisanto, Gotelli, Nicholas J, Gove, Aaron, Grasso, Donato A, Groc, Sarah, Guenard, Benoit, Gunawardene, Nihara, Heterick, Brian, Hoffmann, Benjamin, Janda, Milan, Jenkins, Clinton, Kaspari, Michael, Klimes, Petr, Lach, Lori, Laeger, Thomas, Lattke, John, Leponce, Maurice, Lessard, Jean‐Philippe, Longino, John, Lucky, Andrea, Luke, Sarah H, Majer, Jonathan, McGlynn, Terrence P, Menke, Sean, Mezger, Dirk, Mori, Alessandra, Moses, Jimmy, Munyai, Thinandavha Caswell, Pacheco, Renata, Paknia, Omid, Pearce‐Duvet, Jessica, Pfeiffer, Martin, Philpott, Stacy M, Resasco, Julian, Retana, Javier, Silva, Rogerio R, Sorger, Magdalena D, Souza, Jorge, Suarez, Andrew, Tista, Melanie, Vasconcelos, Heraldo L, Vonshak, Merav, Weiser, Michael D, Yates, Michelle, and Parr, Catherine L

Subjects
Climate Change Impacts and Adaptation, Biological Sciences, Ecology, Environmental Sciences, Animals, Ants, Databases, Factual, Ecosystem, abundance, ants, database, disturbance, Formicidae, geo-referenced, habitat, local assemblage, ccurrence, pitfall trap, Winkler trap, occurrence, Ecological Applications, Evolutionary Biology, Zoology, Ecological applications
Abstract

What forces structure ecological assemblages? A key limitation to general insights about assemblage structure is the availability of data that are collected at a small spatial grain (local assemblages) and a large spatial extent (global coverage). Here, we present published and unpublished data from 51 ,388 ant abundance and occurrence records of more than 2,693 species and 7,953 morphospecies from local assemblages collected at 4,212 locations around the world. Ants were selected because they are diverse and abundant globally, comprise a large fraction of animal biomass in most terrestrial communities, and are key contributors to a range of ecosystem functions. Data were collected between 1949 and 2014, and include, for each geo-referenced sampling site, both the identity of the ants collected and details of sampling design, habitat type, and degree of disturbance. The aim of compiling this data set was to provide comprehensive species abundance data in order to test relationships between assemblage structure and environmental and biogeographic factors. Data were collected using a variety of standardized methods, such as pitfall and Winkler traps, and will be valuable for studies investigating large-scale forces structuring local assemblages. Understanding such relationships is particularly critical under current rates of global change. We encourage authors holding additional data on systematically collected ant assemblages, especially those in dry and cold, and remote areas, to contact us and contribute their data to this growing data set.

Published
2017

9. UAV data and deep learning : efficient tools to map ant mounds and their ecological impact

Author

Monsimet, Jérémy, Sjögersten, Sofie, Sanders, Nathan J., Jonsson, Micael, Olofsson, Johan, Siewert, Matthias, Monsimet, Jérémy, Sjögersten, Sofie, Sanders, Nathan J., Jonsson, Micael, Olofsson, Johan, and Siewert, Matthias

Abstract

High-resolution unoccupied aerial vehicle (UAVs) data have alleviated the mismatch between the scale of ecological processes and the scale of remotely sensed data, while machine learning and deep learning methods allow new avenues for quantification in ecology. Ant nests play key roles in ecosystem functioning, yet their distribution and effects on entire landscapes remain poorly understood, in part because they and their mounds are too small for satellite remote sensing. This research maps the distribution and impact of ant mounds in a 20 ha treeline ecotone. We evaluate the detectability from UAV imagery using a deep learning model for object detection and different combinations of RGB, thermal and multispectral sensor data. We were able to detect ant mounds in all imagery using manual detection and deep learning. However, the highest precision rates were achieved by deep learning using RGB data which has the highest spatial resolution (1.9 cm) at comparable UAV flight height. While multispectral data were outperformed for detection, it allows for novel insights into the ecology of ants and their spatial impact on vegetation productivity using the normalized difference vegetation index. Scaling up, this suggests that ant mounds quantifiably impact vegetation productivity for up to 4% of our study area and up to 8% of the Betula nana vegetation communities, the vegetation type with the highest abundance of ant mounds. Therefore, they could have an overlooked role in nutrient-limited tundra vegetation, and on the shrubification of this habitat. Further, we show the powerful combination UAV multi-sensor data and deep learning for efficient ecological tracking and monitoring of mound-building ants and their spatial impact.

Published
2024
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10. Dynamic primary resources, not just wild prey availability, underpin lion depredation of livestock in a savanna ecosystem.

Author

Mills, Kirby L., Bennitt, Emily, Zhu, Kai, Bartlam‐Brooks, Hattie L. A., Hubel, Tatjana Y., Wilson, Alan M., Carter, Neil H., and Sanders, Nathan J.

Subjects
COMPETITION (Biology), PREY availability, WATER supply, CLIMATE change, LIVESTOCK, LIONS
Abstract

Because it can lead to retaliatory killing, livestock depredation by large carnivores is among the foremost threats to carnivore conservation, and it severely impacts human well‐being worldwide. Ongoing climate change can amplify these human–wildlife conflicts, but such issues are largely unexplored, though are becoming increasingly recognized. Here, we assessed how the availability of primary resources and wild prey interact to shape large carnivore selection for livestock rather than wild prey (i.e., via prey switching or apparent competition). Specifically, we combined remotely sensed estimates of primary resources (i.e., water availability and primary productivity), wild prey movement, and 7 years (2015–2021) of reports for livestock depredation by African lions (Panthera leo) in the Makgadikgadi Pans ecosystem, Botswana. Although livestock depredation did not vary between wet versus dry seasons, analyses at finer temporal scales revealed higher incidences of livestock depredation when primary production, water availability, and wild prey availability were lower, though the effects of wild prey availability were mediated by water availability. Increased precipitation also amplified livestock depredation events despite having no influence on wild prey availability. Our results suggest that livestock depredation is influenced by the diverse responses of livestock, wild prey, and lions to primary resource availability, a driver that is largely overlooked or oversimplified in studies of human–carnivore conflict. Our findings provide insight into tailoring potential conflict mitigation strategies to fine‐scale changes in resource conditions to efficiently reduce conflict and support human livelihoods. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Sodium‐enriched nectar shapes plant–pollinator interactions in a subalpine meadow.

Author

VanValkenburg, Ethan, Gonçalves Souza, Thiago, Sanders, Nathan J., and CaraDonna, Paul

Subjects
BIOTIC communities, FORAGING behavior, NECTAR, POLLINATORS, PLANT species, BUMBLEBEES
Abstract

Many plants have evolved nutrient rewards to attract pollinators to flowers, but most research has focused on the sugar content of floral nectar resources. Concentrations of sodium in floral nectar (a micronutrient in low concentrations in nectar) can vary substantially both among and within co‐occurring species. It is hypothesized that sodium concentrations in floral nectar might play an important and underappreciated role in plant–pollinator interactions, especially because many animals, including pollinators, are sodium limited in nature. Yet, the consequences of variation in sodium concentrations in floral nectar remain largely unexplored. Here, we investigate whether enriching floral nectar with sodium influences the composition, diversity, and frequency of plant–pollinator interactions. We experimentally enriched sodium concentrations in four plant species in a subalpine meadow in Colorado, USA. We found that flowers with sodium‐enriched nectar received more visits from a greater diversity of pollinators throughout the season. Different pollinator species foraged more frequently on flowers enriched with sodium and showed evidence of other changes to foraging behavior, including greater dietary evenness. These findings are consistent with the "salty nectar hypothesis," providing evidence for the importance of sodium limitation in pollinators and suggesting that even small nectar constituents can shape plant–pollinator interactions. [ABSTRACT FROM AUTHOR]

Published
2024
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16. Climate mediates the effects of disturbance on ant assemblage structure

Author

Gibb, Heloise, Sanders, Nathan J, Dunn, Robert R, Watson, Simon, Photakis, Manoli, Abril, Silvia, Andersen, Alan N, Angulo, Elena, Armbrecht, Inge, Arnan, Xavier, Baccaro, Fabricio B, Bishop, Tom R, Boulay, Raphael, Castracani, Cristina, Del Toro, Israel, Delsinne, Thibaut, Diaz, Mireia, Donoso, David A, Enríquez, Martha L, Fayle, Tom M, Feener, Donald H, Fitzpatrick, Matthew C, Gómez, Crisanto, Grasso, Donato A, Groc, Sarah, Heterick, Brian, Hoffmann, Benjamin D, Lach, Lori, Lattke, John, Leponce, Maurice, Lessard, Jean-Philippe, Longino, John, Lucky, Andrea, Majer, Jonathan, Menke, Sean B, Mezger, Dirk, Mori, Alessandra, Munyai, Thinandavha C, Paknia, Omid, Pearce-Duvet, Jessica, Pfeiffer, Martin, Philpott, Stacy M, de Souza, Jorge LP, Tista, Melanie, Vasconcelos, Heraldo L, Vonshak, Merav, and Parr, Catherine L

Subjects
Life Below Water, Animals, Ants, Biodiversity, Climate, Climate Change, Temperature, assemblage structure, dominance, global warming, probability of interspecific encounter, species evenness, Biological Sciences, Agricultural and Veterinary Sciences, Medical and Health Sciences
Abstract

Many studies have focused on the impacts of climate change on biological assemblages, yet little is known about how climate interacts with other major anthropogenic influences on biodiversity, such as habitat disturbance. Using a unique global database of 1128 local ant assemblages, we examined whether climate mediates the effects of habitat disturbance on assemblage structure at a global scale. Species richness and evenness were associated positively with temperature, and negatively with disturbance. However, the interaction among temperature, precipitation and disturbance shaped species richness and evenness. The effect was manifested through a failure of species richness to increase substantially with temperature in transformed habitats at low precipitation. At low precipitation levels, evenness increased with temperature in undisturbed sites, peaked at medium temperatures in disturbed sites and remained low in transformed sites. In warmer climates with lower rainfall, the effects of increasing disturbance on species richness and evenness were akin to decreases in temperature of up to 9°C. Anthropogenic disturbance and ongoing climate change may interact in complicated ways to shape the structure of assemblages, with hot, arid environments likely to be at greatest risk.

Published
2015

17. Unraveling microbial community structure–function relationships in the horizontal and vertical spatial dimensions in extreme environments.

Author

Jing, Xin, Classen, Aimée T., Li, Daijiang, Lin, Litao, Lu, Mingzhen, Sanders, Nathan J., Wang, Yugang, and Feng, Wenting

Subjects
MICROBIAL communities, SOIL microbial ecology, EXTREME environments, MICROBIAL ecology, SOIL texture, SOIL salinization, SOIL salinity, SOIL depth
Abstract

A fundamental challenge in soil macroecology is to understand how microbial community structure shapes ecosystem function along environmental gradients of the land surface at broad spatial scales (i.e. the horizontal dimension). However, little is known about microbial community structure–function relationships in extreme environments along environmental gradients of soil depth at finer spatial scales (i.e. the vertical dimension). Here, we propose a general spatial dimension partitioning approach for assessing the patterns and drivers of soil microbial community structure–function relationships across horizontal and vertical spatial gradients simultaneously. We leveraged a 200‐km desert soil salinity gradient created by a 12‐year saline‐water irrigation in the Tarim basin of Taklamakan Desert. Specifically, using a general linear model, hierarchical variance partitioning, and a path model, we assessed the patterns and key ecological processes controlling spatial turnover in microbial community structure (i.e. β‐diversity) and enzymatic activity relevant to carbon, nitrogen, and phosphorus cycling along soil salinity gradients across study sites (horizontal dimension) and soil depths (vertical dimension). We found a decoupled relationship between soil microbial β‐diversity and enzymatic activity. Differences in soil depth (on the scale of meters) were as important as geographic distance (on the scale of kilometers) in shaping bacterial and fungal β‐diversity. However, the vertical and horizontal turnover in enzymatic activity was largely attributed to an increase in the heterogeneity of soil properties, such as soil texture, water content, and pH. Our findings suggest that dispersal limitation controls microbial community β‐diversity and that environmental heterogeneity, rather than soil salinization, controls enzymatic activity. Taken together, this work highlights that in the face of ongoing environmental alterations, soil depth is an under‐explored spatial dimension that must be considered in soil conservation efforts as a critical factor in determining microbial community structure and function in extreme environments. [ABSTRACT FROM AUTHOR]

Published
2024
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18. Temperature‐driven homogenization of an ant community over 60 years in a montane ecosystem.

Author

Paraskevopoulos, Anna W., Sanders, Nathan J., and Resasco, Julian

Subjects
*ANT communities, *BIOTIC communities, *SPECIES distribution, *CLIMATE change, *ECOSYSTEMS, *ANT colonies
Abstract

Identifying the mechanisms underlying the changes in the distribution of species is critical to accurately predict how species have responded and will respond to climate change. Here, we take advantage of a late‐1950s study on ant assemblages in a canyon near Boulder, Colorado, USA, to understand how and why species distributions have changed over a 60‐year period. Community composition changed over 60 years with increasing compositional similarity among ant assemblages. Community composition differed significantly between the periods, with aspect and tree cover influencing composition. Species that foraged in broader temperature ranges became more widespread over the 60‐year period. Our work highlights that shifts in community composition and biotic homogenization can occur even in undisturbed areas without strong habitat degradation. We also show the power of pairing historical and contemporary data and encourage more mechanistic studies to predict species changes under climate change. [ABSTRACT FROM AUTHOR]

Published
2024
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19. ZooTraits: An R shiny app for exploring animal trait data for ecological and evolutionary research.

Author

Gonçalves‐Souza, Thiago, Milz, Beatriz, Sanders, Nathan J., Reich, Peter B., Maitner, Brian, Chaves, Leonardo S., Boldorini, Gabriel X., Ferreira, Natália, Gusmão, Reginaldo A. F., Perônico, Phamela Bernardes, Teresa, Fabrício B., and Umaña, María Natalia

Subjects
DATABASES, MOBILE apps, INFORMATION sharing, RESEARCH personnel, UPLOADING of data
Abstract

Animal trait data are scattered across several datasets, making it challenging to compile and compare trait information across different groups. For plants, the TRY database has been an unwavering success for those ecologists interested in addressing how plant traits influence a wide variety of processes and patterns, but the same is not true for most animal taxonomic groups. Here, we introduce ZooTraits, a Shiny app designed to help users explore and obtain animal trait data for research in ecology and evolution. ZooTraits was developed to tackle the challenge of finding in a single site information of multiple trait datasets and facilitating access to traits by providing an easy‐to‐use, open‐source platform. This app combines datasets centralized in the Open Trait Network, raw data from the AnimalTraits database, and trait information for animals compiled by Gonçalves‐Souza et al. (2023, Ecology and Evolution 13, e10016). Importantly, the ZooTraits app can be accessed freely and provides a user‐friendly interface through three functionalities that will allow users to easily visualize, compare, download, and upload trait data across the animal tree of life—ExploreTrait, FeedTrait, and GetTrait. By using ExploreTrait and GetTrait, users can explore, compare, and extract 3954 trait records from 23,394 species centralized in the Open Traits Network, and trait data for ~2000 species from the AnimalTraits database. The app summarizes trait information for numerous taxonomic groups within the Animal Kingdom, encompassing data from diverse aquatic and terrestrial ecosystems and various geographic regions worldwide. Moreover, ZooTraits enables researchers to upload trait information, serving as a hub for a continually expanding global trait database. By promoting the centralization of trait datasets and offering a platform for data sharing, ZooTraits is facilitating advancements in trait‐based ecological and evolutionary studies. We hope that other trait databases will evolve to mirror the approach we have outlined here. [ABSTRACT FROM AUTHOR]

Published
2024
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33. Compounded effects of climate change and habitat alteration shift patterns of butterfly diversity

Author

Forister, Matthew L, McCall, Andrew C, Sanders, Nathan J, Fordyce, James A, Thorne, James H, O’Brien, Joshua, Waetjen, David P, and Shapiro, Arthur M

Subjects
Life Below Water, Life on Land, Altitude, Animals, Biodiversity, Butterflies, California, Climate Change, Conservation of Natural Resources, Ecosystem, Endangered Species, Humans, Population Dynamics, Species Specificity, biodiversity, elevational gradient, global change, Lepidoptera, phenology
Abstract

Climate change and habitat destruction have been linked to global declines in vertebrate biodiversity, including mammals, amphibians, birds, and fishes. However, invertebrates make up the vast majority of global species richness, and the combined effects of climate change and land use on invertebrates remain poorly understood. Here we present 35 years of data on 159 species of butterflies from 10 sites along an elevational gradient spanning 0-2,775 m in a biodiversity hotspot, the Sierra Nevada Mountains of Northern California. Species richness has declined at half of the sites, with the most severe reductions at the lowest elevations, where habitat destruction is greatest. At higher elevations, we observed clear upward shifts in the elevational ranges of species, consistent with the influence of global warming. Taken together, these long-term data reveal the interacting negative effects of human-induced changes on both the climate and habitat available to butterfly species in California. Furthermore, the decline of ruderal, disturbance-associated species indicates that the traditional focus of conservation efforts on more specialized and less dispersive species should be broadened to include entire faunas when estimating and predicting the effects of pervasive stressors.

Published
2010

41. The role of thermal tolerance in determining elevational distributions of four arthropod taxa in mountain ranges of southern Asia

Author

Khaliq, Imran, primary, Shahid, Muhammad Junaid, additional, Kamran, Haseeb, additional, Sheraz, Muhammad, additional, Awais, Muhammad, additional, Shabir, Mehtab, additional, Asghar, Muhammad, additional, Rehman, Abdul, additional, Riaz, Maria, additional, Braschler, Brigitte, additional, Sanders, Nathan J., additional, and Hof, Christian, additional

Published
2023
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48. METABOLIC THEORY AND DIVERSITY GRADIENTS: WHERE DO WE GO FROM HERE?

Author

Hawkins, Bradford A., Diniz, J. Alexandre, Filho, Bini, L. Mauricio, Araújo, Miguel B., Field, Richard, Hortal, Joaquín, Kerr, Jeremy T., Rahbek, Carsten, Rodríguez, Miguel A., and Sanders, Nathan J.

Subjects
Metabolic theory of ecology, diversity gradients, species richness, latitudinal gradient
Published
2007

49. A global evaluation of metabolic theory as an explanation for terrestrial species richness gradients

Author

Hawkins, Bradford A., Albuquerque, Fabio S., Araujo, Miguel B., Beck, Jan, Mauricio Bini, Luis, Cabrero-Sanudo, Francisco J., Castro-Parga, Isabel, Alexandre Felizola Diniz-Filho, Jose, Ferrer-Castan, Dolores, Field, Richard, Gomez, Jose F., Hortal, Joaquin, Kerr, Jeremy T., Kitching, Ian J., Leon-Cortes, Jorge L., Lobo, Jorge M., Montoya, Daniel, Carlos Moreno, Juan, Olalla-Tarraga, Miguel A., Pausas, Juli G., Qian, Hong, Rahbek, Carsten, Rodriguez, Miguel A., Sanders, Nathan J., and Williams, Paul

Subjects
diversity gradients, ectotherm diversity, enzyme kinetics, invertebrate diversity, latitudinal gradient, metabolic theory of ecology, plant diversity, species richness, temperature gradients, terrestrial species, vertebrate diversity
Abstract

We compiled 46 broadscale data sets of species richness for a wide range of terrestrial plant, invertebrate, and ectothermic vertebrate groups in all parts of the world to test the ability of metabolic theory to account for observed diversity gradients. The theory makes two related predictions: (1) In-transformed richness is linearly associated with a linear, inverse transformation of annual temperature, and (2) the slope of the relationship is near -0.65. Of the 46 data sets, 14 had no significant relationship; of the remaining 32, nine were linear, meeting prediction 1. Model I (ordinary least squares, OLS) and model II (reduced major axis, RMA) regressions then tested the linear slopes against prediction 2. In the 23 data sets having nonlinear relationships between richness and temperature, split-line regression divided the data into linear components, and regressions were done on each component to test prediction 2 for subsets of the data. Of the 46 data sets analyzed in their entirety using OLS regression one was consistent with metabolic theory (meeting both predictions), and one was possibly consistent. Using RMA regression, no data sets were consistent. Of 67 analyses of prediction 2 using OLS regression on all linear data sets and subsets, two were consistent with the prediction, and four were possibly consistent. Using RMA regression, one was consistent (albeit weakly), and four were possibly consistent. We also found that the relationship between richness and temperature is both taxonomically and geographically conditional, and there is no evidence for a universal response of diversity to temperature. Meta-analyses confirmed significant heterogeneity in slopes among data sets, and the combined slopes across studies were significantly lower than the range of slopes predicted by metabolic theory based on both OLS and RMA regressions. We conclude that metabolic theory, as currently formulated, is a poor predictor of observed diversity gradients in most terrestrial systems.

Published
2007

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