Your search keyword '"Joshua S. Madin"' showing total 3 results

1. Partitioning colony size variation into growth and partial mortality

Author

Maria Dornelas, Andrew H. Baird, Sean R. Connolly, Marissa L. Baskett, Joshua S. Madin, John Templeton Foundation, University of St Andrews. School of Biology, University of St Andrews. Centre for Biological Diversity, University of St Andrews. Fish Behaviour and Biodiversity Research Group, and University of St Andrews. Marine Alliance for Science & Technology Scotland

Subjects

0106 biological sciences, demography, QH301 Biology, Coral, Body size, Biology, 010603 evolutionary biology, 01 natural sciences, life-histories, partial mortality, Predation, QH301, Animals, Body Size, Demography, Evolutionary Biology, Agricultural and Biological Sciences(all), Ecology, 010604 marine biology & hydrobiology, Trade offs, DAS, Biological Sciences, Anthozoa, Agricultural and Biological Sciences (miscellaneous), trade-offs, Good Health and Well Being, Trait, colonial organism, Population Ecology, Allometry, General Agricultural and Biological Sciences

Abstract

We thank the Australian Research Council for fellowship and research support. M.A.D. is funded by a Leverhulme Fellowship and by the John Templeton Foundation grant no. 60501. Body size is a trait that broadly influences the demography and ecology of organisms. In unitary organisms, body size tends to increase with age. In modular organisms, body size can either increase or decrease with age, with size changes being the net difference between modules added through growth and modules lost through partial mortality. Rates of colony extension are independent of body size, but net growth is allometric, suggesting a significant role of size-dependent mortality. In this study, we develop a generalizable model of partitioned growth and partial mortality and apply it to data from 11 species of reef-building coral. We show that corals generally grow at constant radial increments that are size independent, and that partial mortality acts more strongly on small colonies. We also show a clear life-history trade-off between growth and partial mortality that is governed by growth form. This decomposition of net growth can provide mechanistic insights into the relative demographic effects of the intrinsic factors (e.g. acquisition of food and life-history strategy), which tend to affect growth, and extrinsic factors (e.g. physical damage, and predation), which tend to affect mortality. Postprint Postprint

Published

2020

2. Ecological traits influencing range expansion across large oceanic dispersal barriers: insights from tropical Atlantic reef fishes

Author

Peter Wirtz, Joshua S. Madin, Luiz A. Rocha, Osmar J. Luiz, D. Ross Robertson, and Sergio R. Floeter

Subjects

Coral reef fish, Range (biology), Speciation, Population Dynamics, Coral-Reefs, Conservation, Tropical Atlantic, Biology, General Biochemistry, Genetics and Molecular Biology, Homing Behavior, Water Movements, Animals, Body Size, Patterns, Atlantic Ocean, Research Articles, Macroecology, General Environmental Science, Comparative Phylogeography, Tropical Climate, Life-History, Geography, Distance, General Immunology and Microbiology, Coral Reefs, Ecology, Body-Size, Fishes, Pelagic zone, General Medicine, Fishery, Oceanic dispersal, Habitat, Larva, Pelagic Larval Duration, Indo-Pacific, Biological dispersal, Animal Migration, General Agricultural and Biological Sciences

Abstract

How do biogeographically different provinces arise in response to oceanic barriers to dispersal? Here, we analyse how traits related to the pelagic dispersal and adult biology of 985 tropical reef fish species correlate with their establishing populations on both sides of two Atlantic marine barriers: the Mid-Atlantic Barrier (MAB) and the Amazon-Orinoco Plume (AOP). Generalized linear mixed-effects models indicate that predictors for successful barrier crossing are the ability to raft with flotsam for the deep-water MAB, non-reef habitat usage for the freshwater and sediment-rich AOP, and large adult-size and large latitudinal-range for both barriers. Variation in larval-development mode, often thought to be broadly related to larval-dispersal potential, is not a significant predictor in either case. Many more species of greater taxonomic diversity cross the AOP than the MAB. Rafters readily cross both barriers but represent a much smaller proportion of AOP crossers than MAB crossers. Successful establishment after crossing both barriers may be facilitated by broad environmental tolerance associated with large body size and wide latitudinal-range. These results highlight the need to look beyond larval-dispersal potential and assess adult-biology traits when assessing determinants of successful movements across marine barriers. International Macquarie University; Australian Research Council; Smithsonian Tropical Research Institute; National Geographic Society [7937-05]; CNPq; NSF [DEB-0072909]; University of California

Published

2011

3. High-performance spider webs: integrating biomechanics, ecology and behaviour

Author

Aaron M. T. Harmer, Joshua S. Madin, Todd A. Blackledge, and Marie E. Herberstein

Subjects

Spider web, Foraging, Population Dynamics, Biomedical Engineering, Biophysics, Silk, Bioengineering, Biology, Biochemistry, Synthetic materials, Biomechanical Phenomena, Biomaterials, Feeding behavior, Animals, Review Articles, Phylogeny, Spider, Ecology, Spiders, Feeding Behavior, Adaptation, Physiological, Biological Evolution, SILK, Animal ecology, Predatory Behavior, Biotechnology

Abstract

Spider silks exhibit remarkable properties, surpassing most natural and synthetic materials in both strength and toughness. Orb-web spider dragline silk is the focus of intense research by material scientists attempting to mimic these naturally produced fibres. However, biomechanical research on spider silks is often removed from the context of web ecology and spider foraging behaviour. Similarly, evolutionary and ecological research on spiders rarely considers the significance of silk properties. Here, we highlight the critical need to integrate biomechanical and ecological perspectives on spider silks to generate a better understanding of (i) how silk biomechanics and web architectures interacted to influence spider web evolution along different structural pathways, and (ii) how silks function in an ecological context, which may identify novel silk applications. An integrative, mechanistic approach to understanding silk and web function, as well as the selective pressures driving their evolution, will help uncover the potential impacts of environmental change and species invasions (of both spiders and prey) on spider success. Integrating these fields will also allow us to take advantage of the remarkable properties of spider silks, expanding the range of possible silk applications from single threads to two- and three-dimensional thread networks.

Published

2010