Your search keyword '"Muths, Erin"' showing total 23 results

1. Sex-related differences in aging rate areassociated with sex chromosome system inamphibians

Author

Swiss National Science Foundation, Cayuela, Hugo, Lemaître, Jean-François, Léna, Jean-Paul, Ronget, Víctor, Martínez-Solano, Íñigo, Muths, Erin, Pilliod, David S., Schmidt, Benedikt R., Sánchez-Montes, Gregorio, Gutiérrez-Rodríguez, Jorge, Pyke, Graham, Grossenbacher, Kurt, Lenzi, Omar, Bosch, Jaime, Beard, Karen H., Woolbright, Lawrence L, Lambert, Brad A., Green, David M., Jreidini, Nathalie, Garwood, Justin M., Fisher, Robert N., Matthews, Kathleen, Dudgeon, David, Lau, Anthony, Speybroeck, Jeroen, Homan, Rebecca, Jehle, Robert, Baskale, Eyup, Mori, Emiliano, Arntzen, Jan W., Joly, Pierre, Stile, Rochelle M., Lannoo, Michael J., Maerz, John C., Lowe, Winsor H., Valenzuela-Sánchez, Andrés, Christiansen, Ditte G., Angelini, Claudio, Thirion, Jean-Marc, Merilä, Juha, Colli, Guarino R., Vasconcellos, Mariana M., Boas, Taissa C.V., Arantes, Ísis da C., Levionnois, Pauline, Reinke, Beth A., Vieira, Cristina, Marais, Gabriel A.B., Gaillard, Jean-Michel, Miller, David A.W., Swiss National Science Foundation, Cayuela, Hugo, Lemaître, Jean-François, Léna, Jean-Paul, Ronget, Víctor, Martínez-Solano, Íñigo, Muths, Erin, Pilliod, David S., Schmidt, Benedikt R., Sánchez-Montes, Gregorio, Gutiérrez-Rodríguez, Jorge, Pyke, Graham, Grossenbacher, Kurt, Lenzi, Omar, Bosch, Jaime, Beard, Karen H., Woolbright, Lawrence L, Lambert, Brad A., Green, David M., Jreidini, Nathalie, Garwood, Justin M., Fisher, Robert N., Matthews, Kathleen, Dudgeon, David, Lau, Anthony, Speybroeck, Jeroen, Homan, Rebecca, Jehle, Robert, Baskale, Eyup, Mori, Emiliano, Arntzen, Jan W., Joly, Pierre, Stile, Rochelle M., Lannoo, Michael J., Maerz, John C., Lowe, Winsor H., Valenzuela-Sánchez, Andrés, Christiansen, Ditte G., Angelini, Claudio, Thirion, Jean-Marc, Merilä, Juha, Colli, Guarino R., Vasconcellos, Mariana M., Boas, Taissa C.V., Arantes, Ísis da C., Levionnois, Pauline, Reinke, Beth A., Vieira, Cristina, Marais, Gabriel A.B., Gaillard, Jean-Michel, and Miller, David A.W.

Abstract

Sex-related differences in mortality are widespread in the animal kingdom. Although studies have shown that sex determinationsystems might drive lifespan evolution, sex chromosome influence on aging rates have not been investigated so far, likely due toan apparent lack of demographic data from clades including both XY (with heterogametic males) and ZW (heterogametic females)systems. Taking advantage of a unique collection of capture–recapture datasets in amphibians, a vertebrate group where XY andZW systems have repeatedly evolved over the past 200 million years, we examined whether sex heterogamy can predict sexdifferences in aging rates and lifespans. We showed that the strength and direction of sex differences in aging rates (and notlifespan) differ between XY and ZW systems. Sex-specific variation in aging rates was moderate within each system, but agingrates tended to be consistently higher in the heterogametic sex. This led to small but detectable effects of sex chromosome systemon sex differences in aging rates in our models. Although preliminary, our results suggest that exposed recessive deleteriousmutations on the X/Z chromosome (the “unguarded X/Z effect”) or repeat-rich Y/W chromosome (the “toxic Y/W effect”) couldaccelerate aging in the heterogametic sex in some vertebrate clades.

Published

2022

2. Diverse aging rates in ectothermic tetrapods provide insights for the evolution of aging and longevity

Author

Reinke, Beth A., Cayuela, Hugo, Janzen, Fredric J., Lemaître, Jean-François, Gaillard, Jean-Michel, Lawing, A. Michelle, Iverson, John B., Christiansen, Ditte G., Martínez-Solano, Iñigo, Sánchez-Montes, Gregorio, Gutiérrez-Rodríguez, Jorge, Rose, Francis L., Nelson, Nicola, Keall, Susan, Crivelli, Alain J., Nazirides, Theodoros, Grimm-Seyfarth, Annegret, Henle, Klaus, Mori, Emiliano, Guiller, Gaëtan, Homan, Rebecca, Olivier, Anthony, Muths, Erin, Hossack, Blake R., Bonnet, Xavier, Pilliod, David S., Lettink, Marieke, Whitaker, Tony, Schmidt, Benedikt R., Gardner, Michael G., Cheylan, Marc, Poitevin, Françoise, Golubović, Ana, Tomović, Ljiljana, Arsovski, Dragan, Griffiths, Richard A., Arntzen, Jan W., Baron, Jean-Pierre, Le Galliard, Jean-François, Tully, Thomas, Luiselli, Luca, Capula, Massimo, Rugiero, Lorenzo, McCaffery, Rebecca, Eby, Lisa A., Briggs-Gonzalez, Venetia, Mazzotti, Frank, Pearson, David, Lambert, Brad A., Green, David M., Jreidini, Nathalie, Angelini, Claudio, Pyke, Graham, Thirion, Jean-Marc, Joly, Pierre, Léna, Jean-Paul, Tucker, Anton D., Limpus, Col, Priol, Pauline, Besnard, Aurélien, Bernard, Pauline, Stanford, Kristin, King, Richard, Garwood, Justin, Bosch, Jaime, Souza, Franco L., Bertoluci, Jaime, Famelli, Shirley, Grossenbacher, Kurt, Lenzi, Omar, Matthews, Kathleen, Boitaud, Sylvain, Olson, Deanna H., Jessop, Tim S., Gillespie, Graeme R., Clobert, Jean, Richard, Murielle, Valenzuela-Sánchez, Andrés, Fellers, Gary M., Kleeman, Patrick M., Halstead, Brian J., Grant, Evan H. Campbell, Byrne, Phillip G., Frétey, Thierry, Le Garff, Bernard, Levionnois, Pauline, Maerz, John C., Pichenot, Julian, Olgun, Kurtuluş, Üzüm, Nazan, Avcı, Aziz, Miaud, Claude, Elmberg, Johan, Brown, Gregory P., Shine, Richard, Bendik, Nathan F., O’Donnell, Lisa, Davis, Courtney L., Lannoo, Michael J., Stiles, Rochelle M., Cox, Robert M., Reedy, Aaron M., Warner, Daniel A., Bonnaire, Eric, Grayson, Kristine, Ramos-Targarona, Roberto, Baskale, Eyup, Muñoz, David, Measey, John, de Villiers, F. Andre, Selman, Will, Ronget, Victor, Bronikowski, Anne M., Miller, David A. W., Reinke, Beth A., Cayuela, Hugo, Janzen, Fredric J., Lemaître, Jean-François, Gaillard, Jean-Michel, Lawing, A. Michelle, Iverson, John B., Christiansen, Ditte G., Martínez-Solano, Iñigo, Sánchez-Montes, Gregorio, Gutiérrez-Rodríguez, Jorge, Rose, Francis L., Nelson, Nicola, Keall, Susan, Crivelli, Alain J., Nazirides, Theodoros, Grimm-Seyfarth, Annegret, Henle, Klaus, Mori, Emiliano, Guiller, Gaëtan, Homan, Rebecca, Olivier, Anthony, Muths, Erin, Hossack, Blake R., Bonnet, Xavier, Pilliod, David S., Lettink, Marieke, Whitaker, Tony, Schmidt, Benedikt R., Gardner, Michael G., Cheylan, Marc, Poitevin, Françoise, Golubović, Ana, Tomović, Ljiljana, Arsovski, Dragan, Griffiths, Richard A., Arntzen, Jan W., Baron, Jean-Pierre, Le Galliard, Jean-François, Tully, Thomas, Luiselli, Luca, Capula, Massimo, Rugiero, Lorenzo, McCaffery, Rebecca, Eby, Lisa A., Briggs-Gonzalez, Venetia, Mazzotti, Frank, Pearson, David, Lambert, Brad A., Green, David M., Jreidini, Nathalie, Angelini, Claudio, Pyke, Graham, Thirion, Jean-Marc, Joly, Pierre, Léna, Jean-Paul, Tucker, Anton D., Limpus, Col, Priol, Pauline, Besnard, Aurélien, Bernard, Pauline, Stanford, Kristin, King, Richard, Garwood, Justin, Bosch, Jaime, Souza, Franco L., Bertoluci, Jaime, Famelli, Shirley, Grossenbacher, Kurt, Lenzi, Omar, Matthews, Kathleen, Boitaud, Sylvain, Olson, Deanna H., Jessop, Tim S., Gillespie, Graeme R., Clobert, Jean, Richard, Murielle, Valenzuela-Sánchez, Andrés, Fellers, Gary M., Kleeman, Patrick M., Halstead, Brian J., Grant, Evan H. Campbell, Byrne, Phillip G., Frétey, Thierry, Le Garff, Bernard, Levionnois, Pauline, Maerz, John C., Pichenot, Julian, Olgun, Kurtuluş, Üzüm, Nazan, Avcı, Aziz, Miaud, Claude, Elmberg, Johan, Brown, Gregory P., Shine, Richard, Bendik, Nathan F., O’Donnell, Lisa, Davis, Courtney L., Lannoo, Michael J., Stiles, Rochelle M., Cox, Robert M., Reedy, Aaron M., Warner, Daniel A., Bonnaire, Eric, Grayson, Kristine, Ramos-Targarona, Roberto, Baskale, Eyup, Muñoz, David, Measey, John, de Villiers, F. Andre, Selman, Will, Ronget, Victor, Bronikowski, Anne M., and Miller, David A. W.

Abstract

Comparative studies of mortality in the wild are necessary to understand the evolution of aging, yet ectothermic tetrapods are under-represented in this comparative landscape despite their suitability for testing evolutionary hypotheses. We provide the first comprehensive study of aging rates and longevity across tetrapod ectotherms in the wild, utilizing data from 107 populations across 77 species of reptiles and amphibians. We tested hypotheses of how thermoregulatory mode, environmental temperature, protective phenotypes, and pace of life contribute to aging. Controlling for phylogeny and body size, ectotherms displayed a higher diversity of aging rates than endotherms, and included many groups with negligible aging. Protective phenotypes and life-history tactics further explained macroevolutionary patterns of aging. By including ectothermic tetrapods, our comparative analyses enhance our understanding of aging evolution.

Published

2022

3. Diverse aging rates in ectothermic tetrapods provide insights for the evolution of aging and longevity

Author

Reinke, Beth A., Cayuela, Hugo, Janzen, Fredric J., Lemaître, Jean-François, Gaillard, Jean-Michel, Lawing, A. Michelle, Iverson, John B., Christiansen, Ditte G., Martínez-Solano, Íñigo, Sánchez-Montes, Gregorio, Gutiérrez-Rodríguez, Jorge, Rose, Francis L., Nelson, Nicola, Keall, Susan, Crivelli, Alain J., Nazirides, Theodoros, Grimm-Seyfarth, Annegret, Henle, Kalus, Mori, Emiliano, Guiller, Gaëtan, Homan, Rebecca, Olivier, Anothony, Muths, Erin, Hossack, Blake R., Bonnet, Xavier, Pilliod, David S., Lettink, Marieke, Whitaker, Tony, Schmidt, Benedikt R., Gardner, Michael G., Cheylan, Marc, Poitevin, Françoise, Golubovic, Ana, Tomovic, Ljiljana, Arsovski, Dragan, Griffiths, Richard A., Arntzen, Jan W., Baron. Jean-Pierre, Le Galliard, Jean-Françoise, Tully, Thomas, Luiselli, Luca, Capula, Massimo, Rugiero, Lorenzo, Mccaffery, Rebecca, Eby, Lisa A., Briggs-González, Venetia, Mazzotti, Frank, Pearson, David, Lambert, Brad A., Green, David M., Jreidini, Nathalie, Angelini, Claudio, Pyke, Graham, Thirion, Jean-Marc, Joly, Pierre, Léna, Jean-Paul, Tucker, Anton D., Limpus, Col, Priol, Pauline, Besnard, Aurélien, Bernard, Pauline, Stanfor, Kristin, King, Richard, Garwood, Justin, Bosch, Jaime, Souza, Franco L., Bertoluci, Jaime, Famelli, Shirley, Grossenbacher, Kurt, Lenzi, Omar, Matthews, Kathleen, Boitaud, Sylvain, Olson, Deanna H., Jessop, Tim S., Gillespie, Graeme R., Clobert, Jean, Richard, Murielle, Valenzuela-Sánchez, Andrés, Fellers, Gary M., Kleeman, Patrick M., Halstead, Brian J., Campbell Grant, Evan H., Byrne, Phillip G., Frétey, Thierry, Le Garff, Bernard, Levionnois, Pauline, Maerz, John C., Pichenot, Julian, Olgun. Kurtulus, Üzum, Nazan, Avci, Aziz, Miaud, Claude, Elmberg, Johan, Brown, Gregory P., Shine, Richard, Bendik, Nathan F., O'Donnell, Lisa, Davis, Courtney L., Lannoo, Michael J., Stiles, Rochelle M., Cox, Robert M., Reedy, Aaron M., Warner, Daniel A., Bonnaire, Eric, Grayson, Kristine, Ramos-Targarona, Roberto, Baskale, Eyup, Muñoz, David, Measey, John, De Villiers, F. Andre, Selman, Will, Ronget, Victor, Bonikowski, Anne M., Miller, David A.W., Reinke, Beth A., Cayuela, Hugo, Janzen, Fredric J., Lemaître, Jean-François, Gaillard, Jean-Michel, Lawing, A. Michelle, Iverson, John B., Christiansen, Ditte G., Martínez-Solano, Íñigo, Sánchez-Montes, Gregorio, Gutiérrez-Rodríguez, Jorge, Rose, Francis L., Nelson, Nicola, Keall, Susan, Crivelli, Alain J., Nazirides, Theodoros, Grimm-Seyfarth, Annegret, Henle, Kalus, Mori, Emiliano, Guiller, Gaëtan, Homan, Rebecca, Olivier, Anothony, Muths, Erin, Hossack, Blake R., Bonnet, Xavier, Pilliod, David S., Lettink, Marieke, Whitaker, Tony, Schmidt, Benedikt R., Gardner, Michael G., Cheylan, Marc, Poitevin, Françoise, Golubovic, Ana, Tomovic, Ljiljana, Arsovski, Dragan, Griffiths, Richard A., Arntzen, Jan W., Baron. Jean-Pierre, Le Galliard, Jean-Françoise, Tully, Thomas, Luiselli, Luca, Capula, Massimo, Rugiero, Lorenzo, Mccaffery, Rebecca, Eby, Lisa A., Briggs-González, Venetia, Mazzotti, Frank, Pearson, David, Lambert, Brad A., Green, David M., Jreidini, Nathalie, Angelini, Claudio, Pyke, Graham, Thirion, Jean-Marc, Joly, Pierre, Léna, Jean-Paul, Tucker, Anton D., Limpus, Col, Priol, Pauline, Besnard, Aurélien, Bernard, Pauline, Stanfor, Kristin, King, Richard, Garwood, Justin, Bosch, Jaime, Souza, Franco L., Bertoluci, Jaime, Famelli, Shirley, Grossenbacher, Kurt, Lenzi, Omar, Matthews, Kathleen, Boitaud, Sylvain, Olson, Deanna H., Jessop, Tim S., Gillespie, Graeme R., Clobert, Jean, Richard, Murielle, Valenzuela-Sánchez, Andrés, Fellers, Gary M., Kleeman, Patrick M., Halstead, Brian J., Campbell Grant, Evan H., Byrne, Phillip G., Frétey, Thierry, Le Garff, Bernard, Levionnois, Pauline, Maerz, John C., Pichenot, Julian, Olgun. Kurtulus, Üzum, Nazan, Avci, Aziz, Miaud, Claude, Elmberg, Johan, Brown, Gregory P., Shine, Richard, Bendik, Nathan F., O'Donnell, Lisa, Davis, Courtney L., Lannoo, Michael J., Stiles, Rochelle M., Cox, Robert M., Reedy, Aaron M., Warner, Daniel A., Bonnaire, Eric, Grayson, Kristine, Ramos-Targarona, Roberto, Baskale, Eyup, Muñoz, David, Measey, John, De Villiers, F. Andre, Selman, Will, Ronget, Victor, Bonikowski, Anne M., and Miller, David A.W.

Abstract

Comparative studies of mortality in the wild are necessary to understand the evolution of aging; yet, ectothermic tetrapods are underrepresented in this comparative landscape, despite their suitability for testing evolutionary hypotheses. We present a study of aging rates and longevity across wild tetrapod ectotherms, using data from 107 populations (77 species) of nonavian reptiles and amphibians. We test hypotheses of how thermoregulatory mode, environmental temperature, protective phenotypes, and pace of life history contribute to demographic aging. Controlling for phylogeny and body size, ectotherms display a higher diversity of aging rates compared with endotherms and include phylogenetically widespread evidence of negligible aging. Protective phenotypes and life-history strategies further explain macroevolutionary patterns of aging. Analyzing ectothermic tetrapods in a comparative context enhances our understanding of the evolution of aging.

Published

2022

4. Sex‐related differences in aging rate are associated with sex chromosome system in amphibians

Author

Cayuela, Hugo, Lemaître, Jean‐François, Léna, Jean‐Paul, Ronget, Victor, Martínez‐Solano, Iñigo; https://orcid.org/0000-0002-2260-226X, Muths, Erin; https://orcid.org/0000-0002-5498-3132, Pilliod, David S, Schmidt, Benedikt R; https://orcid.org/0000-0002-4023-1001, Sánchez-Montes, Gregorio, Gutiérrez-Rodríguez, Jorge, Pyke, Graham, Grossenbacher, Kurt, Lenzi, Omar; https://orcid.org/0000-0003-1938-6786, Bosch, Jaime, Beard, Karen H, Woolbright, Lawrence L, Lambert, Brad A, Green, David M, Jreidini, Nathalie, Garwood, Justin M, Fisher, Robert N, Matthews, Kathleen, Dudgeon, David, Lau, Anthony, Speybroeck, Jeroen, Homan, Rebecca, Jehle, Robert; https://orcid.org/0000-0003-0545-5664, Başkale, Eyup, Mori, Emiliano, Arntzen, Jan W, Joly, Pierre; https://orcid.org/0000-0003-4918-3277, Stiles, Rochelle M, Lannoo, Michael J, Maerz, John C, Lowe, Winsor H, Valenzuela-Sánchez, Andrés; https://orcid.org/0000-0002-0445-9156, Christiansen, Ditte G, et al, Cayuela, Hugo, Lemaître, Jean‐François, Léna, Jean‐Paul, Ronget, Victor, Martínez‐Solano, Iñigo; https://orcid.org/0000-0002-2260-226X, Muths, Erin; https://orcid.org/0000-0002-5498-3132, Pilliod, David S, Schmidt, Benedikt R; https://orcid.org/0000-0002-4023-1001, Sánchez-Montes, Gregorio, Gutiérrez-Rodríguez, Jorge, Pyke, Graham, Grossenbacher, Kurt, Lenzi, Omar; https://orcid.org/0000-0003-1938-6786, Bosch, Jaime, Beard, Karen H, Woolbright, Lawrence L, Lambert, Brad A, Green, David M, Jreidini, Nathalie, Garwood, Justin M, Fisher, Robert N, Matthews, Kathleen, Dudgeon, David, Lau, Anthony, Speybroeck, Jeroen, Homan, Rebecca, Jehle, Robert; https://orcid.org/0000-0003-0545-5664, Başkale, Eyup, Mori, Emiliano, Arntzen, Jan W, Joly, Pierre; https://orcid.org/0000-0003-4918-3277, Stiles, Rochelle M, Lannoo, Michael J, Maerz, John C, Lowe, Winsor H, Valenzuela-Sánchez, Andrés; https://orcid.org/0000-0002-0445-9156, Christiansen, Ditte G, and et al

Abstract

Sex-related differences in mortality are widespread in the animal kingdom. Although studies have shown that sex determination systems might drive lifespan evolution, sex chromosome influence on aging rates have not been investigated so far, likely due to an apparent lack of demographic data from clades including both XY (with heterogametic males) and ZW (heterogametic females) systems. Taking advantage of a unique collection of capture–recapture datasets in amphibians, a vertebrate group where XY and ZW systems have repeatedly evolved over the past 200 million years, we examined whether sex heterogamy can predict sex differences in aging rates and lifespans. We showed that the strength and direction of sex differences in aging rates (and not lifespan) differ between XY and ZW systems. Sex-specific variation in aging rates was moderate within each system, but aging rates tended to be consistently higher in the heterogametic sex. This led to small but detectable effects of sex chromosome system on sex differences in aging rates in our models. Although preliminary, our results suggest that exposed recessive deleterious mutations on the X/Z chromosome (the “unguarded X/Z effect”) or repeat-rich Y/W chromosome (the “toxic Y/W effect”) could accelerate aging in the heterogametic sex in some vertebrate clades.

Published

2022

5. Batrachochytrium salamandrivorans (Bsal) not detected in an intensive survey of wild North American amphibians.

Author

Waddle, J Hardin, Waddle, J Hardin, Grear, Daniel A, Mosher, Brittany A, Grant, Evan H Campbell, Adams, Michael J, Backlin, Adam R, Barichivich, William J, Brand, Adrianne B, Bucciarelli, Gary M, Calhoun, Daniel L, Chestnut, Tara, Davenport, Jon M, Dietrich, Andrew E, Fisher, Robert N, Glorioso, Brad M, Halstead, Brian J, Hayes, Marc P, Honeycutt, R Ken, Hossack, Blake R, Kleeman, Patrick M, Lemos-Espinal, Julio A, Lorch, Jeffrey M, McCreary, Brome, Muths, Erin, Pearl, Christopher A, Richgels, Katherine LD, Robinson, Charles W, Roth, Mark F, Rowe, Jennifer C, Sadinski, Walt, Sigafus, Brent H, Stasiak, Iga, Sweet, Samuel, Walls, Susan C, Watkins-Colwell, Gregory J, White, C LeAnn, Williams, Lori A, Winzeler, Megan E, Waddle, J Hardin, Waddle, J Hardin, Grear, Daniel A, Mosher, Brittany A, Grant, Evan H Campbell, Adams, Michael J, Backlin, Adam R, Barichivich, William J, Brand, Adrianne B, Bucciarelli, Gary M, Calhoun, Daniel L, Chestnut, Tara, Davenport, Jon M, Dietrich, Andrew E, Fisher, Robert N, Glorioso, Brad M, Halstead, Brian J, Hayes, Marc P, Honeycutt, R Ken, Hossack, Blake R, Kleeman, Patrick M, Lemos-Espinal, Julio A, Lorch, Jeffrey M, McCreary, Brome, Muths, Erin, Pearl, Christopher A, Richgels, Katherine LD, Robinson, Charles W, Roth, Mark F, Rowe, Jennifer C, Sadinski, Walt, Sigafus, Brent H, Stasiak, Iga, Sweet, Samuel, Walls, Susan C, Watkins-Colwell, Gregory J, White, C LeAnn, Williams, Lori A, and Winzeler, Megan E

Abstract

The salamander chytrid fungus (Batrachochytrium salamandrivorans [Bsal]) is causing massive mortality of salamanders in Europe. The potential for spread via international trade into North America and the high diversity of salamanders has catalyzed concern about Bsal in the U.S. Surveillance programs for invading pathogens must initially meet challenges that include low rates of occurrence on the landscape, low prevalence at a site, and imperfect detection of the diagnostic tests. We implemented a large-scale survey to determine if Bsal was present in North America designed to target taxa and localities where Bsal was determined highest risk to be present based on species susceptibility and geography. Our analysis included a Bayesian model to estimate the probability of occurrence of Bsal given our prior knowledge of the occurrence and prevalence of the pathogen. We failed to detect Bsal in any of 11,189 samples from 594 sites in 223 counties within 35 U.S. states and one site in Mexico. Our modeling indicates that Bsal is highly unlikely to occur within wild amphibians in the U.S. and suggests that the best proactive response is to continue mitigation efforts against the introduction and establishment of the disease and to develop plans to reduce impacts should Bsal establish.

Published

2020

6. Determinants and consequences of dispersal in vertebrates with complex life cycles: A review of pond-breeding amphibians

Author

Ministerio de Ciencia, Innovación y Universidades (España), Cayuela, Hugo, Valenzuela-Sánchez, Andrés, Teulier, Loïc, Martínez-Solano, Íñigo, Léna, Jean-Paul, Merilä, Juha, Muths, Erin, Shine, Richard, Quay, Ludivine, Denoël, Jean, Schmidt, Benedikt R., Ministerio de Ciencia, Innovación y Universidades (España), Cayuela, Hugo, Valenzuela-Sánchez, Andrés, Teulier, Loïc, Martínez-Solano, Íñigo, Léna, Jean-Paul, Merilä, Juha, Muths, Erin, Shine, Richard, Quay, Ludivine, Denoël, Jean, and Schmidt, Benedikt R.

Abstract

Dispersal is a central process in ecology and evolution. It strongly influences the dynamics of spatially structured populations and affects evolutionary processes by shaping patterns of gene flow. For these reasons, dispersal has received considerable attention from ecologists, evolutionary biologists, and conservationists. Although it has been studied extensively in taxa such as birds and mammals, much less is known about dispersal in vertebrates with complex life cycles such as pond-breeding amphibians. Over the past two decades, researchers have taken an ever-increasing interest in amphibian dispersal and initiated both basic and applied studies, using a broad range of experimental and observational approaches. This body of research reveals complex dispersal patterns, causations, and syndromes, with dramatic consequences for the demography and genetics of amphibian populations. In this review, our goals are to: redefine and clarify the concept of amphibian dispersal; review current knowledge about the effects of individual (i.e., condition-dependent dispersal) and environmental (i.e., context-dependent dispersal) factors during the three stages of dispersal (i.e., emigration, transience, and immigration); identify the demographic and genetic consequences of dispersal in spatially structured amphibian populations; and propose new research avenues to extend our understanding of amphibian dispersal.

Published

2020

7. Determinants and Consequences of Dispersal in Vertebrates with Complex Life Cycles: A Review of Pond-Breeding Amphibians

Author

Cayuela, Hugo, Valenzuela-Sánchez, Andrés, Teulier, Loïc, Martínez-Solano, Íñigo, Léna, Jean-Paul, Merilä, Juha, Muths, Erin, Shine, Richard, Quay, Ludivine, Denoël, Mathieu, Clobert, Jean, Schmidt, Benedikt R; https://orcid.org/0000-0002-4023-1001, Cayuela, Hugo, Valenzuela-Sánchez, Andrés, Teulier, Loïc, Martínez-Solano, Íñigo, Léna, Jean-Paul, Merilä, Juha, Muths, Erin, Shine, Richard, Quay, Ludivine, Denoël, Mathieu, Clobert, Jean, and Schmidt, Benedikt R; https://orcid.org/0000-0002-4023-1001

Abstract

Dispersal is a central process in ecology and evolution. It strongly influences the dynamics of spatially structured populations and affects evolutionary processes by shaping patterns of gene flow. For these reasons, dispersal has received considerable attention from ecologists, evolutionary biologists, and conservationists. Although it has been studied extensively in taxa such as birds and mammals, much less is known about dispersal in vertebrates with complex life cycles such as pond-breeding amphibians. Over the past two decades, researchers have taken an ever-increasing interest in amphibian dispersal and initiated both basic and applied studies, using a broad range of experimental and observational approaches. This body of research reveals complex dispersal patterns, causations, and syndromes, with dramatic consequences for the demography and genetics of amphibian populations. In this review, our goals are to: redefine and clarify the concept of amphibian dispersal; review current knowledge about the effects of individual (i.e., condition-dependent dispersal) and environmental (i.e., context-dependent dispersal) factors during the three stages of dispersal (i.e., emigration, transience, and immigration); identify the demographic and genetic consequences of dispersal in spatially structured amphibian populations; and propose new research avenues to extend our understanding of amphibian dispersal.

Published

2020

8. Quantifying climate sensitivity and climate-driven change in North American amphibian communities

Author

Miller, David A. W., Grant, Evan H. Campbell, Muths, Erin, Amburgey, Staci M., Adams, Michael J., Joseph, Maxwell B., Waddle, J. Hardin, Johnson, Pieter T. J., Ryan, Maureen E., Schmidt, Benedikt R., Calhoun, Daniel L., Davis, Courtney L., Fisher, Robert N., Green, David M., Hossack, Blake R., Rittenhouse, Tracy A. G., Walls, Susan C., Bailey, Larissa L., Cruickshank, Sam S., Fellers, Gary M., Gorman, Thomas A., Haas, Carola A., Hughson, Ward, Pilliod, David S., Price, Steven J., Ray, Andrew M., Sadinski, Walt, Saenz, Daniel, Barichivich, William J., Brand, Adrianne, Brehme, Cheryl S., Dagit, Rosi, Delaney, Katy S., Glorioso, Brad M., Kats, Lee B., Kleeman, Patrick M., Pearl, Christopher A., Rochester, Carlton J., Riley, Seth P. D., Roth, Mark, Sigafus, Brent H., Miller, David A. W., Grant, Evan H. Campbell, Muths, Erin, Amburgey, Staci M., Adams, Michael J., Joseph, Maxwell B., Waddle, J. Hardin, Johnson, Pieter T. J., Ryan, Maureen E., Schmidt, Benedikt R., Calhoun, Daniel L., Davis, Courtney L., Fisher, Robert N., Green, David M., Hossack, Blake R., Rittenhouse, Tracy A. G., Walls, Susan C., Bailey, Larissa L., Cruickshank, Sam S., Fellers, Gary M., Gorman, Thomas A., Haas, Carola A., Hughson, Ward, Pilliod, David S., Price, Steven J., Ray, Andrew M., Sadinski, Walt, Saenz, Daniel, Barichivich, William J., Brand, Adrianne, Brehme, Cheryl S., Dagit, Rosi, Delaney, Katy S., Glorioso, Brad M., Kats, Lee B., Kleeman, Patrick M., Pearl, Christopher A., Rochester, Carlton J., Riley, Seth P. D., Roth, Mark, and Sigafus, Brent H.

Abstract

Changing climate will impact species' ranges only when environmental variability directly impacts the demography of local populations. However, measurement of demographic responses to climate change has largely been limited to single species and locations. Here we show that amphibian communities are responsive to climatic variability, using >500,000 time-series observations for 81 species across 86 North American study areas. The effect of climate on local colonization and persistence probabilities varies among eco-regions and depends on local climate, species life-histories, and taxonomic classification. We found that local species richness is most sensitive to changes in water availability during breeding and changes in winter conditions. Based on the relationships we measure, recent changes in climate cannot explain why local species richness of North American amphibians has rapidly declined. However, changing climate does explain why some populations are declining faster than others. Our results provide important insights into how amphibians respond to climate and a general framework for measuring climate impacts on species richness.

Published

2018

9. Quantifying climate sensitivity and climate-driven change in North American amphibian communities

Author

Fish and Wildlife Conservation, Miller, David A. W., Grant, Evan H. Campbell, Muths, Erin, Amburgey, Staci M., Adams, Michael J., Joseph, Maxwell B., Waddle, J. Hardin, Johnson, Pieter T. J., Ryan, Maureen E., Schmidt, Benedikt R., Calhoun, Daniel L., Davis, Courtney L., Fisher, Robert N., Green, David M., Hossack, Blake R., Rittenhouse, Tracy A. G., Walls, Susan C., Bailey, Larissa L., Cruickshank, Sam S., Fellers, Gary M., Gorman, Thomas A., Haas, Carola A., Hughson, Ward, Pilliod, David S., Price, Steven J., Ray, Andrew M., Sadinski, Walt, Saenz, Daniel, Barichivich, William J., Brand, Adrianne, Brehme, Cheryl S., Dagit, Rosi, Delaney, Katy S., Glorioso, Brad M., Kats, Lee B., Kleeman, Patrick M., Pearl, Christopher A., Rochester, Carlton J., Riley, Seth P. D., Roth, Mark, Sigafus, Brent H., Fish and Wildlife Conservation, Miller, David A. W., Grant, Evan H. Campbell, Muths, Erin, Amburgey, Staci M., Adams, Michael J., Joseph, Maxwell B., Waddle, J. Hardin, Johnson, Pieter T. J., Ryan, Maureen E., Schmidt, Benedikt R., Calhoun, Daniel L., Davis, Courtney L., Fisher, Robert N., Green, David M., Hossack, Blake R., Rittenhouse, Tracy A. G., Walls, Susan C., Bailey, Larissa L., Cruickshank, Sam S., Fellers, Gary M., Gorman, Thomas A., Haas, Carola A., Hughson, Ward, Pilliod, David S., Price, Steven J., Ray, Andrew M., Sadinski, Walt, Saenz, Daniel, Barichivich, William J., Brand, Adrianne, Brehme, Cheryl S., Dagit, Rosi, Delaney, Katy S., Glorioso, Brad M., Kats, Lee B., Kleeman, Patrick M., Pearl, Christopher A., Rochester, Carlton J., Riley, Seth P. D., Roth, Mark, and Sigafus, Brent H.

Abstract

Changing climate will impact species' ranges only when environmental variability directly impacts the demography of local populations. However, measurement of demographic responses to climate change has largely been limited to single species and locations. Here we show that amphibian communities are responsive to climatic variability, using >500,000 time-series observations for 81 species across 86 North American study areas. The effect of climate on local colonization and persistence probabilities varies among eco-regions and depends on local climate, species life-histories, and taxonomic classification. We found that local species richness is most sensitive to changes in water availability during breeding and changes in winter conditions. Based on the relationships we measure, recent changes in climate cannot explain why local species richness of North American amphibians has rapidly declined. However, changing climate does explain why some populations are declining faster than others. Our results provide important insights into how amphibians respond to climate and a general framework for measuring climate impacts on species richness.

Published

2018

10. Quantifying climate sensitivity and climate-driven change in North American amphibian communities

Author

Miller, David A W, Grant, Evan H Campbell, Muths, Erin; https://orcid.org/0000-0002-5498-3132, Amburgey, Staci M; https://orcid.org/0000-0002-7100-7811, Adams, Michael J; https://orcid.org/0000-0001-8844-042X, Joseph, Maxwell B, Waddle, J Hardin, Johnson, Pieter T J, Ryan, Maureen E, et al, Schmidt, B R; https://orcid.org/0000-0002-4023-1001, Cruickshank, Sam S; https://orcid.org/0000-0003-0183-5352, Miller, David A W, Grant, Evan H Campbell, Muths, Erin; https://orcid.org/0000-0002-5498-3132, Amburgey, Staci M; https://orcid.org/0000-0002-7100-7811, Adams, Michael J; https://orcid.org/0000-0001-8844-042X, Joseph, Maxwell B, Waddle, J Hardin, Johnson, Pieter T J, Ryan, Maureen E, et al, Schmidt, B R; https://orcid.org/0000-0002-4023-1001, and Cruickshank, Sam S; https://orcid.org/0000-0003-0183-5352

Abstract

Changing climate will impact species’ ranges only when environmental variability directly impacts the demography of local populations. However, measurement of demographic responses to climate change has largely been limited to single species and locations. Here we show that amphibian communities are responsive to climatic variability, using >500,000 time-series observations for 81 species across 86 North American study areas. The effect of climate on local colonization and persistence probabilities varies among eco-regions and depends on local climate, species life-histories, and taxonomic classification. We found that local species richness is most sensitive to changes in water availability during breeding and changes in winter conditions. Based on the relationships we measure, recent changes in climate cannot explain why local species richness of North American amphibians has rapidly declined. However, changing climate does explain why some populations are declining faster than others. Our results provide important insights into how amphibians respond to climate and a general framework for measuring climate impacts on species richness.

Published

2018

11. Quantifying climate sensitivity and climate-driven change in North American amphibian communities

Author

Fish and Wildlife Conservation, Miller, David A. W., Grant, Evan H. Campbell, Muths, Erin, Amburgey, Staci M., Adams, Michael J., Joseph, Maxwell B., Waddle, J. Hardin, Johnson, Pieter T. J., Ryan, Maureen E., Schmidt, Benedikt R., Calhoun, Daniel L., Davis, Courtney L., Fisher, Robert N., Green, David M., Hossack, Blake R., Rittenhouse, Tracy A. G., Walls, Susan C., Bailey, Larissa L., Cruickshank, Sam S., Fellers, Gary M., Gorman, Thomas A., Haas, Carola A., Hughson, Ward, Pilliod, David S., Price, Steven J., Ray, Andrew M., Sadinski, Walt, Saenz, Daniel, Barichivich, William J., Brand, Adrianne, Brehme, Cheryl S., Dagit, Rosi, Delaney, Katy S., Glorioso, Brad M., Kats, Lee B., Kleeman, Patrick M., Pearl, Christopher A., Rochester, Carlton J., Riley, Seth P. D., Roth, Mark, Sigafus, Brent H., Fish and Wildlife Conservation, Miller, David A. W., Grant, Evan H. Campbell, Muths, Erin, Amburgey, Staci M., Adams, Michael J., Joseph, Maxwell B., Waddle, J. Hardin, Johnson, Pieter T. J., Ryan, Maureen E., Schmidt, Benedikt R., Calhoun, Daniel L., Davis, Courtney L., Fisher, Robert N., Green, David M., Hossack, Blake R., Rittenhouse, Tracy A. G., Walls, Susan C., Bailey, Larissa L., Cruickshank, Sam S., Fellers, Gary M., Gorman, Thomas A., Haas, Carola A., Hughson, Ward, Pilliod, David S., Price, Steven J., Ray, Andrew M., Sadinski, Walt, Saenz, Daniel, Barichivich, William J., Brand, Adrianne, Brehme, Cheryl S., Dagit, Rosi, Delaney, Katy S., Glorioso, Brad M., Kats, Lee B., Kleeman, Patrick M., Pearl, Christopher A., Rochester, Carlton J., Riley, Seth P. D., Roth, Mark, and Sigafus, Brent H.

Abstract

Changing climate will impact species' ranges only when environmental variability directly impacts the demography of local populations. However, measurement of demographic responses to climate change has largely been limited to single species and locations. Here we show that amphibian communities are responsive to climatic variability, using >500,000 time-series observations for 81 species across 86 North American study areas. The effect of climate on local colonization and persistence probabilities varies among eco-regions and depends on local climate, species life-histories, and taxonomic classification. We found that local species richness is most sensitive to changes in water availability during breeding and changes in winter conditions. Based on the relationships we measure, recent changes in climate cannot explain why local species richness of North American amphibians has rapidly declined. However, changing climate does explain why some populations are declining faster than others. Our results provide important insights into how amphibians respond to climate and a general framework for measuring climate impacts on species richness.

Published

2018

12. Using decision analysis to support proactive management of emerging infectious wildlife diseases

Author

Grant, Evan H Campbell, Muths, Erin, Katz, Rachel A, Canessa, Stefano, Adams, Michael J, Ballard, Jennifer R, Berger, Lee, Briggs, Cheryl J, Coleman, Jeremy T H, Gray, Matthew J, Harris, M Camille, Harris, Reid N, Hossack, Blake, Huyvaert, Kathryn P, Kolby, Jonathan, Lips, Karen R, Lovich, Robert E, McCallum, Hamish I, Mendelson III, Joseph R, Nanjappa, Priya, Olson, Deanna H, Powers, Jenny G, Richgels, Katherine L D, Russell, Robin E, Schmidt, Benedikt R; https://orcid.org/0000-0002-4023-1001, Spitzen-van der Sluijs, Annemarieke, Watry, Mary Kay, Woodhams, Douglas C, White, C LeAnn, Grant, Evan H Campbell, Muths, Erin, Katz, Rachel A, Canessa, Stefano, Adams, Michael J, Ballard, Jennifer R, Berger, Lee, Briggs, Cheryl J, Coleman, Jeremy T H, Gray, Matthew J, Harris, M Camille, Harris, Reid N, Hossack, Blake, Huyvaert, Kathryn P, Kolby, Jonathan, Lips, Karen R, Lovich, Robert E, McCallum, Hamish I, Mendelson III, Joseph R, Nanjappa, Priya, Olson, Deanna H, Powers, Jenny G, Richgels, Katherine L D, Russell, Robin E, Schmidt, Benedikt R; https://orcid.org/0000-0002-4023-1001, Spitzen-van der Sluijs, Annemarieke, Watry, Mary Kay, Woodhams, Douglas C, and White, C LeAnn

Abstract

Despite calls for improved responses to emerging infectious diseases in wildlife, management is seldom considered until a disease has been detected in affected populations. Reactive approaches may limit the potential for control and increase total response costs. An alternative, proactive management framework can identify immediate actions that reduce future impacts even before a disease is detected, and plan subsequent actions that are conditional on disease emergence. We identify four main obstacles to developing proactive management strategies for the newly discovered salamander pathogen Batrachochytrium salamandrivorans (Bsal). Given that uncertainty is a hallmark of wildlife disease management and that associated decisions are often complicated by multiple competing objectives, we advocate using decision analysis to create and evaluate trade-offs between proactive (pre-emergence) and reactive (post-emergence) management options. Policy makers and natural resource agency personnel can apply principles from decision analysis to improve strategies for countering emerging infectious diseases.

Published

2017

13. Non-native and native organisms moving into high elevation and high latitude ecosystems in an era of climate change : new challenges for ecology and conservation

Author

Pauchard, Anibal, Milbau, Ann, Albihn, Ann, Alexander, Jake, Burgess, Treena, Daehler, Curtis, Englund, Göran, Essl, Franz, Evengård, Birgitta, Greenwood, Gregory B., Haider, Sylvia, Lenoir, Jonathan, McDougall, Keith, Muths, Erin, Nunez, Martin A., Olofsson, Johan, Pellissier, Loic, Rabitsch, Wolfgang, Rew, Lisa J., Robertson, Mark, Sanders, Nathan, Kueffer, Christoph, Pauchard, Anibal, Milbau, Ann, Albihn, Ann, Alexander, Jake, Burgess, Treena, Daehler, Curtis, Englund, Göran, Essl, Franz, Evengård, Birgitta, Greenwood, Gregory B., Haider, Sylvia, Lenoir, Jonathan, McDougall, Keith, Muths, Erin, Nunez, Martin A., Olofsson, Johan, Pellissier, Loic, Rabitsch, Wolfgang, Rew, Lisa J., Robertson, Mark, Sanders, Nathan, and Kueffer, Christoph

Abstract

Cold environments at high elevation and high latitude are often viewed as resistant to biological invasions. However, climate warming, land use change and associated increased connectivity all increase the risk of biological invasions in these environments. Here we present a summary of the key discussions of the workshop 'Biosecurity in Mountains and Northern Ecosystems: Current Status and Future Challenges' (Flen, Sweden, 1-3 June 2015). The aims of the workshop were to (1) increase awareness about the growing importance of species expansion-both non-native and native-at high elevation and high latitude with climate change, (2) review existing knowledge about invasion risks in these areas, and (3) encourage more research on how species will move and interact in cold environments, the consequences for biodiversity, and animal and human health and wellbeing. The diversity of potential and actual invaders reported at the workshop and the likely interactions between them create major challenges for managers of cold environments. However, since these cold environments have experienced fewer invasions when compared with many warmer, more populated environments, prevention has a real chance of success, especially if it is coupled with prioritisation schemes for targeting invaders likely to have greatest impact. Communication and co-operation between cold environment regions will facilitate rapid response, and maximise the use of limited research and management resources.

Published

2016

14. Non-native and native organisms moving into high elevation and high latitude ecosystems in an era of climate change:new challenges for ecology and conservation

Author

Pauchard, Aníbal, Milbau, Ann, Albihn, Ann, Alexander, Jake, Burgess, Treena, Daehler, Curtis, Englund, Göran, Essl, Franz, Evengård, Birgitta, Greenwood, Gregory B., Haider, Sylvia, Lenoir, Jonathan, McDougall, Keith, Muths, Erin, Nuñez, Martin A., Olofsson, Johan, Pellissier, Loic, Rabitsch, Wolfgang, Rew, Lisa J., Robertson, Mark, Sanders, Nate, Kueffer, Christoph, Pauchard, Aníbal, Milbau, Ann, Albihn, Ann, Alexander, Jake, Burgess, Treena, Daehler, Curtis, Englund, Göran, Essl, Franz, Evengård, Birgitta, Greenwood, Gregory B., Haider, Sylvia, Lenoir, Jonathan, McDougall, Keith, Muths, Erin, Nuñez, Martin A., Olofsson, Johan, Pellissier, Loic, Rabitsch, Wolfgang, Rew, Lisa J., Robertson, Mark, Sanders, Nate, and Kueffer, Christoph

Abstract

Cold environments at high elevation and high latitude are often viewed as resistant to biological invasions. However, climate warming, land use change and associated increased connectivity all increase the risk of biological invasions in these environments. Here we present a summary of the key discussions of the workshop ‘Biosecurity in Mountains and Northern Ecosystems: Current Status and Future Challenges’ (Flen, Sweden, 1–3 June 2015). The aims of the workshop were to (1) increase awareness about the growing importance of species expansion—both non-native and native—at high elevation and high latitude with climate change, (2) review existing knowledge about invasion risks in these areas, and (3) encourage more research on how species will move and interact in cold environments, the consequences for biodiversity, and animal and human health and wellbeing. The diversity of potential and actual invaders reported at the workshop and the likely interactions between them create major challenges for managers of cold environments. However, since these cold environments have experienced fewer invasions when compared with many warmer, more populated environments, prevention has a real chance of success, especially if it is coupled with prioritisation schemes for targeting invaders likely to have greatest impact. Communication and co-operation between cold environment regions will facilitate rapid response, and maximise the use of limited research and management resources.

Published

2016

15. Quantitative evidence for the effects of multiple drivers on continental-scale amphibian declines

Author

Fish and Wildlife Conservation, Grant, Evan H. Campbell, Miller, David A. W., Schmidt, Benedikt R., Adams, Michael J., Amburgey, Staci M., Chambert, Thierry, Cruickshank, Sam S., Fisher, Robert N., Green, David M., Hossack, Blake R., Johnson, Pieter T. J., Joseph, Maxwell B., Rittenhouse, Tracy A. G., Ryan, Maureen E., Waddle, J. Hardin, Walls, Susan C., Bailey, Larissa L., Fellers, Gary M., Gorman, Thomas A., Ray, Andrew M., Pilliod, David S., Price, Steven J., Saenz, Daniel, Sadinski, Walt, Muths, Erin, Fish and Wildlife Conservation, Grant, Evan H. Campbell, Miller, David A. W., Schmidt, Benedikt R., Adams, Michael J., Amburgey, Staci M., Chambert, Thierry, Cruickshank, Sam S., Fisher, Robert N., Green, David M., Hossack, Blake R., Johnson, Pieter T. J., Joseph, Maxwell B., Rittenhouse, Tracy A. G., Ryan, Maureen E., Waddle, J. Hardin, Walls, Susan C., Bailey, Larissa L., Fellers, Gary M., Gorman, Thomas A., Ray, Andrew M., Pilliod, David S., Price, Steven J., Saenz, Daniel, Sadinski, Walt, and Muths, Erin

Abstract

Since amphibian declines were first proposed as a global phenomenon over a quarter century ago, the conservation community has made little progress in halting or reversing these trends. The early search for a "smoking gun" was replaced with the expectation that declines are caused by multiple drivers. While field observations and experiments have identified factors leading to increased local extinction risk, evidence for effects of these drivers is lacking at large spatial scales. Here, we use observations of 389 time-series of 83 species and complexes from 61 study areas across North America to test the effects of 4 of the major hypothesized drivers of declines. While we find that local amphibian populations are being lost from metapopulations at an average rate of 3.79% per year, these declines are not related to any particular threat at the continental scale; likewise the effect of each stressor is variable at regional scales. This result - that exposure to threats varies spatially, and populations vary in their response - provides little generality in the development of conservation strategies. Greater emphasis on local solutions to this globally shared phenomenon is needed.

Published

2016

16. Mitigating amphibian chytridiomycoses in nature

Author

Garner, Trenton W. J., Schmidt, Benedikt R., Martel, An, Pasmans, Frank, Muths, Erin, Cunningham, Andrew A., Weldon, Che, Fisher, Matthew C., Bosch, Jaime, Garner, Trenton W. J., Schmidt, Benedikt R., Martel, An, Pasmans, Frank, Muths, Erin, Cunningham, Andrew A., Weldon, Che, Fisher, Matthew C., and Bosch, Jaime

Abstract

Amphibians across the planet face the threat of population decline and extirpation caused by the disease chytridiomycosis. Despite consensus that the fungal pathogens responsible for the disease are conservation issues, strategies to mitigate their impacts in the natural world are, at best, nascent. Reducing risk associated with the movement of amphibians, non-amphibian vectors and other sources of infection remains the first line of defence and a primary objective when mitigating the threat of disease in wildlife. Amphibian-associated chytridiomycete fungi and chytridiomycosis are already widespread, though, and we therefore focus on discussing options for mitigating the threats once disease emergence has occurred in wild amphibian populations. All strategies have shortcomings that need to be overcome before implementation, including stronger efforts towards understanding and addressing ethical and legal considerations. Even if these issues can be dealt with, all currently available approaches, or those under discussion, are unlikely to yield the desired conservation outcome of disease mitigation. The decision process for establishing mitigation strategies requires integrated thinking that assesses disease mitigation options critically and embeds them within more comprehensive strategies for the conservation of amphibian populations, communities and ecosystems.

Published

2016

17. Salamander chytrid fungus (Batrachochytrium salamandrivorans) in the United States—Developing research, monitoring, and management strategies

Author

Grant, Evan H Campbell, Muths, Erin L, Katz, Rachel A, Canessa, Stefano, et al, Schmidt, B R, Grant, Evan H Campbell, Muths, Erin L, Katz, Rachel A, Canessa, Stefano, et al, and Schmidt, B R

Abstract

The recently (2013) identified pathogenic chytrid fungus, Batrachochytrium salamandrivorans (Bsal), poses a severe threat to the distribution and abundance of salamanders within the United States and Europe. Development of a response strategy for the potential, and likely, invasion of Bsal into the United States is crucial to protect global salamander biodiversity. A formal working group, led by Amphibian Research and Monitoring Initiative (ARMI) scientists from the U.S. Geological Survey (USGS) Patuxent Wildlife Research Center, Fort Collins Science Center, and Forest and Rangeland Ecosystem Science Center, was held at the USGS Powell Center for Analysis and Synthesis in Fort Collins, Colorado, United States from June 23 to June 25, 2015, to identify crucial Bsal research and monitoring needs that could inform conservation and management strategies for salamanders in the United States. Key findings of the workshop included the following: (1) the introduction of Bsal into the United States is highly probable, if not inevitable, thus requiring development of immediate short-term and long-term intervention strategies to prevent Bsal establishment and biodiversity decline; (2) management actions targeted towards pathogen containment may be ineffective in reducing the long-term spread of Bsal throughout the United States; and (3) early detection of Bsal through surveillance at key amphibian import locations, among high-risk wild populations, and through analysis of archived samples is necessary for developing management responses. Top research priorities during the preinvasion stage included the following: (1) deployment of qualified diagnostic methods for Bsal and establishment of standardized laboratory practices, (2) assessment of susceptibility for amphibian hosts (including anurans), and (3) development and evaluation of short- and long-term pathogen intervention and management strategies. Several outcomes were achieved during the workshop, including development of

Published

2015

18. Demography of common toads after local extirpation of co-occurring midwife toads

Author

Bosch, Jaime, Fernández-Beaskoetxea, Saioa, Scherer, Rick D., Amburgey, Staci M., Muths, Erin, Bosch, Jaime, Fernández-Beaskoetxea, Saioa, Scherer, Rick D., Amburgey, Staci M., and Muths, Erin

Abstract

© Copyright 2014 by Koninklijke Brill NV, Leiden, The Netherlands. Estimating demographic parameters like survival or recruitment provides insight into the state and trajectory of populations, but understanding the contexts influencing those parameters, including both biotic and abiotic factors, is particularly important for management and conservation. At a high elevation national park in Central Spain, common toads (Bufo bufo) are apparently taking advantage of the near-extirpation of the midwife toad (Alytes obstetricans), as colonization into new breeding ponds is evident.Within this scenario, we expected demographic parameters of common toad populations to be affected favorably by the putative release from competition. However, we found the population growth rate was negative in 4 of 5 years at the long-standing population; survival probability at the long-standing population and newly-colonised breeding ponds was lower than reported for other toads living at high elevations and the probability of recruitment was inadequate to compensate for the survival rate in maintaining a positive trajectory for either of the breeding ponds. We assessed weather covariates and disease for their contribution to the context thatmay be limiting the common toad's successful use of the niche vacated by the midwife toad.

Published

2014

19. Evidence for plasticity in the frequency of skipped breeding opportunities in common toads

Author

Muths, Erin, Scherer, Rick D., Bosch, Jaime, Muths, Erin, Scherer, Rick D., and Bosch, Jaime

Abstract

Breeding is limited by energetic or environmental constraints and long-lived species sometimes skip breeding opportunities. Environmental conditions may vary considerably across the geographic and elevational range of a species and species that can respond through variation in life history strategies are likely to maintain populations at the extremes of their ranges. The decision to skip breeding enables animals to adjust life history to circumstances, and plasticity in behavior allows implementation of adjustments. Elevational patterns suggest that breeding may be limited physiologically at high elevations (e.g., greater probability of skipped breeding; resources and environmental conditions more variable) in contrast to low elevations (probability of skipping breeding lower; resources and environmental conditions more predictable). We estimated the probabilities of survival and skipped breeding in a high-elevation population of common toads and compared estimates to existing data for common toads at low elevations, and to another toad species inhabiting a similar high elevation environment. Female common toads at high elevations tend to have high probabilities of skipping breeding and survival relative to data for common toads at low elevations, and appear to use a similar strategy of skipping breeding in response to similar environmental constraints as other toads at high elevations. We provide evidence of variability in this aspect of life history for common toads. Understanding variation in life history within widely distributed species is critical. Knowing that certain life history strategies are employed on a continuum informs conservation efforts, especially as impacts of climate change are likely to be different depending on elevation. © 2013 The Society of Population Ecology and Springer Japan (outside the USA).

Published

2013

20. Terrestrial movement patterns of the Common Toad (Bufo bufo) in Central Spain reveal habitat of conservation importance

Author

Daversa, David R., Muths, Erin, Bosch, Jaime, Daversa, David R., Muths, Erin, and Bosch, Jaime

Abstract

Widespread amphibian declines and habitat fragmentation, coupled with advancements in tracking, have sparked increased emphasis on studying movements and the use of terrestrial habitats by amphibians. Peñalara Natural Park, Sierra de Guadarrama, Central Spain, provides habitat for a number of amphibians that use upland sites. In response to increased pressure on habitat in this region by tourism, we used 4 months of radiotelemetry data for 17 adult Common Toads (Bufo bufo) to characterize the terrestrial movements, assess the factors influencing these movements, and determine the distribution and cover characteristics of summer refugia for these toads. We found that: 1) movements were most pronounced following the breeding season in June, and adults made movements of up to 470 m away from breeding sites, 2) movements were not influenced by basin size, climatic variables, or the sex of the individual, 3) the amount of terrestrial habitat used by toads ranged from 245 m2 to 2.5 ha, and 4) within these areas toads most often used rock piles and juniper patches (Juniperus communis nana) as cover during the summer. Our study emphasizes the importance of considering terrestrial landscapes when developing conservation strategies, and we suggest that a buffer of minimal development extending 550 m from the shoreline of each natal pond be considered when conservation plans are developed for Common Toad habitat in Peñalara Natural Park. © 2012 Society for the Study of Amphibians and Reptiles.

Published

2012

21. Mitigating Amphibian Disease: Strategies to maintain wild populations and control chytridiomycosis

Author

Woodhams, Douglas C, Woodhams, Douglas C, Bosch, Jaime, Briggs, Cheryl J, Cashins, Scott, Davis, Leyla R, Lauer, Antje, Muths, Erin, Puschendorf, Robert, Schmidt, Benedikt R, Sheafor, Brandon, Voyles, Jamie, Woodhams, Douglas C, Woodhams, Douglas C, Bosch, Jaime, Briggs, Cheryl J, Cashins, Scott, Davis, Leyla R, Lauer, Antje, Muths, Erin, Puschendorf, Robert, Schmidt, Benedikt R, Sheafor, Brandon, and Voyles, Jamie

Abstract

Background Rescuing amphibian diversity is an achievable conservation challenge. Disease mitigation is one essential component of population management. Here we assess existing disease mitigation strategies, some in early experimental stages, which focus on the globally emerging chytrid fungus Batrachochytrium dendrobatidis. We discuss the precedent for each strategy in systems ranging from agriculture to human medicine, and the outlook for each strategy in terms of research needs and long-term potential. Results We find that the effects of exposure to Batrachochytrium dendrobatidis occur on a spectrum from transient commensal to lethal pathogen. Management priorities are divided between (1) halting pathogen spread and developing survival assurance colonies, and (2) prophylactic or remedial disease treatment. Epidemiological models of chytridiomycosis suggest that mitigation strategies can control disease without eliminating the pathogen. Ecological ethics guide wildlife disease research, but several ethical questions remain for managing disease in the field. Conclusions Because sustainable conservation of amphibians in nature is dependent on long-term population persistence and co-evolution with potentially lethal pathogens, we suggest that disease mitigation not focus exclusively on the elimination or containment of the pathogen, or on the captive breeding of amphibian hosts. Rather, successful disease mitigation must be context specific with epidemiologically informed strategies to manage already infected populations by decreasing pathogenicity and host susceptibility. We propose population level treatments based on three steps: first, identify mechanisms of disease suppression; second, parameterize epizootiological models of disease and population dynamics for testing under semi-natural conditions; and third, begin a process of adaptive management in field trials with natural populations.

Published

2011

22. Mitigating Amphibian Disease: Strategies to maintain wild populations and control chytridiomycosis

Author

Woodhams, Douglas C, Woodhams, Douglas C, Bosch, Jaime, Briggs, Cheryl J, Cashins, Scott, Davis, Leyla R, Lauer, Antje, Muths, Erin, Puschendorf, Robert, Schmidt, Benedikt R, Sheafor, Brandon, Voyles, Jamie, Woodhams, Douglas C, Woodhams, Douglas C, Bosch, Jaime, Briggs, Cheryl J, Cashins, Scott, Davis, Leyla R, Lauer, Antje, Muths, Erin, Puschendorf, Robert, Schmidt, Benedikt R, Sheafor, Brandon, and Voyles, Jamie

Abstract

Background Rescuing amphibian diversity is an achievable conservation challenge. Disease mitigation is one essential component of population management. Here we assess existing disease mitigation strategies, some in early experimental stages, which focus on the globally emerging chytrid fungus Batrachochytrium dendrobatidis. We discuss the precedent for each strategy in systems ranging from agriculture to human medicine, and the outlook for each strategy in terms of research needs and long-term potential. Results We find that the effects of exposure to Batrachochytrium dendrobatidis occur on a spectrum from transient commensal to lethal pathogen. Management priorities are divided between (1) halting pathogen spread and developing survival assurance colonies, and (2) prophylactic or remedial disease treatment. Epidemiological models of chytridiomycosis suggest that mitigation strategies can control disease without eliminating the pathogen. Ecological ethics guide wildlife disease research, but several ethical questions remain for managing disease in the field. Conclusions Because sustainable conservation of amphibians in nature is dependent on long-term population persistence and co-evolution with potentially lethal pathogens, we suggest that disease mitigation not focus exclusively on the elimination or containment of the pathogen, or on the captive breeding of amphibian hosts. Rather, successful disease mitigation must be context specific with epidemiologically informed strategies to manage already infected populations by decreasing pathogenicity and host susceptibility. We propose population level treatments based on three steps: first, identify mechanisms of disease suppression; second, parameterize epizootiological models of disease and population dynamics for testing under semi-natural conditions; and third, begin a process of adaptive management in field trials with natural populations.

Published

2011

23. Mitigating Amphibian Disease: Strategies to maintain wild populations and control chytridiomycosis

Author

Woodhams, Douglas C., Bosch, Jaime, Briggs, Cheryl J., Cashins, Scott, Davis, Leyla R., Lauer, Antje, Muths, Erin, Puschendorf, Robert, Schmidt, Benedikt R., Sheafor, Brandon, Voyles, Jamie, Woodhams, Douglas C., Bosch, Jaime, Briggs, Cheryl J., Cashins, Scott, Davis, Leyla R., Lauer, Antje, Muths, Erin, Puschendorf, Robert, Schmidt, Benedikt R., Sheafor, Brandon, and Voyles, Jamie

Abstract

Background Rescuing amphibian diversity is an achievable conservation challenge. Disease mitigation is one essential component of population management. Here we assess existing disease mitigation strategies, some in early experimental stages, which focus on the globally emerging chytrid fungus Batrachochytrium dendrobatidis. We discuss the precedent for each strategy in systems ranging from agriculture to human medicine, and the outlook for each strategy in terms of research needs and long-term potential. Results We find that the effects of exposure to Batrachochytrium dendrobatidis occur on a spectrum from transient commensal to lethal pathogen. Management priorities are divided between (1) halting pathogen spread and developing survival assurance colonies, and (2) prophylactic or remedial disease treatment. Epidemiological models of chytridiomycosis suggest that mitigation strategies can control disease without eliminating the pathogen. Ecological ethics guide wildlife disease research, but several ethical questions remain for managing disease in the field. Conclusions Because sustainable conservation of amphibians in nature is dependent on long-term population persistence and co-evolution with potentially lethal pathogens, we suggest that disease mitigation not focus exclusively on the elimination or containment of the pathogen, or on the captive breeding of amphibian hosts. Rather, successful disease mitigation must be context specific with epidemiologically informed strategies to manage already infected populations by decreasing pathogenicity and host susceptibility. We propose population level treatments based on three steps: first, identify mechanisms of disease suppression; second, parameterize epizootiological models of disease and population dynamics for testing under semi-natural conditions; and third, begin a process of adaptive management in field trials with natural populations.

Published

2011