Your search keyword '"B. Wetherbee"' showing total 4 results

1. Convergence of marine megafauna movement patterns in coastal and open oceans

Author

D. Hamer, Frédéric Bailleul, John Gunn, Daniel P. Costa, Ari S. Friedlaender, Patrick W. Robinson, Michael J. Weise, Eric Clua, Mahmood S. Shivji, Robert Harcourt, Jorge P. Rodríguez, Ruth H. Carmichael, Robert G. Campbell, Luciana C. Ferreira, R. Wells, Mônica M. C. Muelbert, Camrin D. Braun, M. Goebel, Mary-Anne Lea, Barbara Wienecke, Michael L. Berumen, Nicolas E. Humphries, David W. Sims, Scott A. Shaffer, Andrew D. Lowther, Mike O. Hammill, Mark A. Hindell, Graeme C. Hays, Michele Thums, Carlos M. Duarte, Clive R. McMahon, Jennifer M. Burns, M. J. Caley, A. Wiebkin, Christophe Guinet, Ana M. M. Sequeira, Alastair M. M. Baylis, Luke D. Einoder, Brad Page, Elizabeth A. McHuron, Mark G. Meekan, Jane McKenzie, Gregory B. Skomal, Allen M. Aven, Nuno Queiroz, Simon D. Goldsworthy, L. McLeay, Kerrie Mengersen, Juan Fernández-Gracia, Alice I. Mackay, Anthony M. Pagano, Luis A. Hückstädt, B. Wetherbee, Simon R. Thorrold, Michelle R. Heupel, Stella Villegas-Amtmann, Víctor M. Eguíluz, Neil Hammerschlag, University of Western Australia, UWA Oceans Institute, Australian Institute of Marine Science, King Abdullah University of Science and Technology, Australian Research Council, Indian Ocean Marine Research Centre, Ministerio de Economía y Competitividad (España), European Commission, Ministerio de Educación, Cultura y Deporte (España), Natural Environment Research Council (UK), Save Our Seas Foundation, Fundação para a Ciência e a Tecnologia (Portugal), Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Brasil), IOMRC and The UWA Oceans Institute, The University of Western Australia (UWA), Institute for Marine and Antarctic Studies [Horbat] (IMAS), University of Tasmania (UTAS), Centre d'Études Biologiques de Chizé - UMR 7372 (CEBC), Institut National de la Recherche Agronomique (INRA)-Université de La Rochelle (ULR)-Centre National de la Recherche Scientifique (CNRS), University of Tasmania [Hobart, Australia] (UTAS), and Université de La Rochelle (ULR)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)

Subjects

0106 biological sciences, Root-mean-square, Databases, Factual, turning angles, Oceans and Seas, Climate change, global satellite tracking, 010603 evolutionary biology, 01 natural sciences, Databases, Megafauna, biology.animal, Marine vertebrate, Probability density function, probability density function, Animals, Ecosystem, 14. Life underwater, root-mean-square, Life Below Water, Factual, Global satellite tracking, Multidisciplinary, geography.geographical_feature_category, Turning angles, biology, Ecology, Movement (music), 010604 marine biology & hydrobiology, Vertebrate, Biological Sciences, Arctic ice pack, Geography, Habitat, 13. Climate action, Vertebrates, [SDE]Environmental Sciences, Animal Migration, displacements, Displacements

Abstract

The extent of increasing anthropogenic impacts on large marine vertebrates partly depends on the animals’ movement patterns. Effective conservation requires identification of the key drivers of movement including intrinsic properties and extrinsic constraints associated with the dynamic nature of the environments the animals inhabit. However, the relative importance of intrinsic versus extrinsic factors remains elusive. We analyze a global dataset of ∼2.8 million locations from >2,600 tracked individuals across 50 marine vertebrates evolutionarily separated by millions of years and using different locomotion modes (fly, swim, walk/paddle). Strikingly, movement patterns show a remarkable convergence, being strongly conserved across species and independent of body length and mass, despite these traits ranging over 10 orders of magnitude among the species studied. This represents a fundamental difference between marine and terrestrial vertebrates not previously identified, likely linked to the reduced costs of locomotion in water. Movement patterns were primarily explained by the interaction between species-specific traits and the habitat(s) they move through, resulting in complex movement patterns when moving close to coasts compared with more predictable patterns when moving in open oceans. This distinct difference may be associated with greater complexity within coastal microhabitats, highlighting a critical role of preferred habitat in shaping marine vertebrate global movements. Efforts to develop understanding of the characteristics of vertebrate movement should consider the habitat(s) through which they move to identify how movement patterns will alter with forecasted severe ocean changes, such as reduced Arctic sea ice cover, sea level rise, and declining oxygen content., Workshop funding was granted by the University of Western Australia (UWA) Oceans Institute, the Australian Institute of Marine Science (AIMS), and King Abdullah University of Science and Technology (KAUST). A.M.M.S. was supported by Australian Research Council Grant DE170100841 and an Indian Ocean Ocean Marine Research Centre (UWA, AIMS, Commonwealth of Scientific and Industrial Research Organisation) fellowship. J.P.R., V.M.E., and J.F.G. were supported by Agencia Estatal de Investigación (AEI, Spain) and Fondo Europeo de Desarrollo Regional (FEDER) through project Spatiotemporality in Sociobological Interactions, Models and Methods (SPASIMM) (FIS2016-80067-P AEI/FEDER, European Union), and by research funding from KAUST. J.P.R. was supported by Ministerio de Educación, Cultura y Deporte (Formación de Profesorado Universitario Grant, Spain). D.W.S. was supported by the UK Natural Environment Research Council and Save Our Seas Foundation. N.Q. was supported by Fundação para a Ciência e Tecnologia (Portugal). M.M.C.M. was supported by a Coordenação de Aperfeiçoamento de pessoal de Nível Superior fellowship (Ministry of Education).

Published

2018

2. Some Measurements and Weights of Live Birds

Author

Kenneth B. Wetherbee

Subjects

General Engineering, General Earth and Planetary Sciences, Biology, General Environmental Science

Published

1934

3. Vigabatrin-Induced Retinal Functional Alterations and Second-Order Neuron Plasticity in C57BL/6J Mice.

Author

Chan K, Hoon M, Pattnaik BR, Ver Hoeve JN, Wahlgren B, Gloe S, Williams J, Wetherbee B, Kiland JA, Vogel KR, Jansen E, Salomons G, Walters D, Roullet JB, Gibson KM, and McLellan GJ

Subjects

Animals, Male, Mice, Inbred C57BL, Neuronal Plasticity physiology, Oculomotor Muscles drug effects, Random Allocation, Retina physiopathology, Retinal Diseases drug therapy, Retinal Diseases physiopathology, Tomography, Optical Coherence, Visual Fields physiology, Anticonvulsants pharmacology, GABA Agents pharmacology, Neuronal Plasticity drug effects, Retina drug effects, Vigabatrin pharmacology

Abstract

Purpose: Vigabatrin (VGB) is an effective antiepileptic that increases concentrations of inhibitory γ-aminobutyric acid (GABA) by inhibiting GABA transaminase. Reports of VGB-associated visual field loss limit its clinical usefulness, and retinal toxicity studies in laboratory animals have yielded conflicting results., Methods: We examined the functional and morphologic effects of VGB in C57BL/6J mice that received either VGB or saline IP from 10 to 18 weeks of age. Retinal structure and function were assessed in vivo by optical coherence tomography (OCT), ERG, and optomotor response. After euthanasia, retinas were processed for immunohistochemistry, and retinal GABA, and VGB quantified by mass spectrometry., Results: No significant differences in visual acuity or total retinal thickness were identified between groups by optomotor response or optical coherence tomography, respectively. After 4 weeks of VGB treatment, ERG b-wave amplitude was enhanced, and amplitudes of oscillatory potentials were reduced. Dramatic rod and cone bipolar and horizontal cell remodeling, with extension of dendrites into the outer nuclear layer, was observed in retinas of VGB-treated mice. VGB treatment resulted in a mean 3.3-fold increase in retinal GABA concentration relative to controls and retinal VGB concentrations that were 20-fold greater than brain., Conclusions: No evidence of significant retinal thinning or ERG a- or b-wave deficits were apparent, although we describe significant alterations in ERG b-wave and oscillatory potentials and in retinal cell morphology in VGB-treated C57BL/6J mice. The dramatic concentration of VGB in retina relative to the target tissue (brain), with a corresponding increase in retinal GABA, offers insight into the pathophysiology of VGB-associated visual field loss.

Published

2020

4. Convergence of marine megafauna movement patterns in coastal and open oceans.

Author

Sequeira AMM, Rodríguez JP, Eguíluz VM, Harcourt R, Hindell M, Sims DW, Duarte CM, Costa DP, Fernández-Gracia J, Ferreira LC, Hays GC, Heupel MR, Meekan MG, Aven A, Bailleul F, Baylis AMM, Berumen ML, Braun CD, Burns J, Caley MJ, Campbell R, Carmichael RH, Clua E, Einoder LD, Friedlaender A, Goebel ME, Goldsworthy SD, Guinet C, Gunn J, Hamer D, Hammerschlag N, Hammill M, Hückstädt LA, Humphries NE, Lea MA, Lowther A, Mackay A, McHuron E, McKenzie J, McLeay L, McMahon CR, Mengersen K, Muelbert MMC, Pagano AM, Page B, Queiroz N, Robinson PW, Shaffer SA, Shivji M, Skomal GB, Thorrold SR, Villegas-Amtmann S, Weise M, Wells R, Wetherbee B, Wiebkin A, Wienecke B, and Thums M

Subjects

Animals, Ecosystem, Animal Migration, Databases, Factual, Oceans and Seas, Vertebrates

Abstract

The extent of increasing anthropogenic impacts on large marine vertebrates partly depends on the animals' movement patterns. Effective conservation requires identification of the key drivers of movement including intrinsic properties and extrinsic constraints associated with the dynamic nature of the environments the animals inhabit. However, the relative importance of intrinsic versus extrinsic factors remains elusive. We analyze a global dataset of ∼2.8 million locations from >2,600 tracked individuals across 50 marine vertebrates evolutionarily separated by millions of years and using different locomotion modes (fly, swim, walk/paddle). Strikingly, movement patterns show a remarkable convergence, being strongly conserved across species and independent of body length and mass, despite these traits ranging over 10 orders of magnitude among the species studied. This represents a fundamental difference between marine and terrestrial vertebrates not previously identified, likely linked to the reduced costs of locomotion in water. Movement patterns were primarily explained by the interaction between species-specific traits and the habitat(s) they move through, resulting in complex movement patterns when moving close to coasts compared with more predictable patterns when moving in open oceans. This distinct difference may be associated with greater complexity within coastal microhabitats, highlighting a critical role of preferred habitat in shaping marine vertebrate global movements. Efforts to develop understanding of the characteristics of vertebrate movement should consider the habitat(s) through which they move to identify how movement patterns will alter with forecasted severe ocean changes, such as reduced Arctic sea ice cover, sea level rise, and declining oxygen content., Competing Interests: The authors declare no conflict of interest.

Published

2018