Your search keyword '"Moyle, Robert G."' showing total 30 results

1. On the brink of explosion? Identifying the source and potential spread of introduced Zosterops white-eyes in North America

Author

DeRaad, Devon A, DeRaad, Devon A, Cobos, Marlon E, Hofmeister, Natalie R, DeCicco, Lucas H, Venkatraman, Madhvi X, Nishiumi, Isao, McKay, Bailey, Zou, Fa-Sheng, Kawakami, Kazuto, Kim, Chang-Hoe, Lin, Ruey-Shing, Yao, Cheng-Te, Garrett, Kimball L, Aguillon, Stepfanie M, McCormack, John E, Mays, Herman L, Peterson, A Townsend, Moyle, Robert G, Shultz, Allison J, DeRaad, Devon A, DeRaad, Devon A, Cobos, Marlon E, Hofmeister, Natalie R, DeCicco, Lucas H, Venkatraman, Madhvi X, Nishiumi, Isao, McKay, Bailey, Zou, Fa-Sheng, Kawakami, Kazuto, Kim, Chang-Hoe, Lin, Ruey-Shing, Yao, Cheng-Te, Garrett, Kimball L, Aguillon, Stepfanie M, McCormack, John E, Mays, Herman L, Peterson, A Townsend, Moyle, Robert G, and Shultz, Allison J

Abstract

Understanding the source of non-native introduced populations is crucial for forecasting geographic invasion potential and understanding the ecological consequences of potential establishment. Here we use genomics to identify the source populations and invasion dynamics of two non-native introduced populations from the iconic avian lineage of ‘great speciators’ known as white-eyes (genus Zosterops). We established confidently for the first time that introduced Zosterops populations in Hawaii and southern California are completely unrelated and derived from independent introductions of the species Z. japonicus and Z. simplex, respectively. We used descriptive population genetic statistics to identify a reduction in genetic diversity and increase in private alleles in the southern California population supporting a recent, potentially ongoing, genetic bottleneck in this population. In contrast, the introduced population in Hawaii showed no such characteristics, likely due to a larger founding population size and repeated introductions in this intentionally introduced population. Ecological niche modeling indicated that there is little environmentally suitable habitat for Z. simplex across the continent of North America, suggesting limited invasion potential, assuming niche conservatism. Yet, portions of the introduced Z. simplex population have already surpassed areas projected as suitable, likely because the urbanized environment of southern California offers biotic resources and microhabitats not captured by our model. Because Z. simplex appears to have overcome both the ‘invasion paradox’ of low founding genetic diversity and relatively unfamiliar environmental conditions in southern California, we suggest that this population may continue expanding beyond our environmental niche model projections in other temperate, urban regions.

Published

2024

2. Specimen collection is essential for modern science

Author

Nachman, Michael W., Beckman, Elizabeth J., Bowie, Rauri C. K., Cicero, Carla, Conroy, Chris J., Dudley, Robert, Hayes, Tyrone B., Koo, Michelle S., Lacey, Eileen A., Martin, Christopher H., McGuire, Jimmy A., Patton, James L., Spencer, Carol L., Tarvin, Rebecca D., Wake, Marvalee H., Wang, Ian J., Achmadi, Anang, Álvarez-Castañeda, Sergio Ticul, Andersen, Michael J., Arroyave, Jairo, Austin, Christopher C., Barker, F. Keith, Barrow, Lisa N., Barrowclough, George F., Bates, John, Bauer, Aaron M., Bell, Kayce C., Bell, Rayna C., Bronson, Allison W., Brown, Rafe M., Burbrink, Frank T., Burns, Kevin J., Cadena, Carlos Daniel, Cannatella, David C., Castoe, Todd A., Chakrabarty, Prosanta, Colella, Jocelyn P., Cook, Joseph A., Cracraft, Joel L., Davis, Drew R., Rabosky, Alison R. Davis, D'Elía, Guillermo, Dumbacher, John P., Dunnum, Jonathan L., Edwards, Scott V., Esselstyn, Jacob A., Faivovich, Julián, Fjeldså, Jon, Flores-Villela, Oscar A., Ford, Kassandra, Fuchs, Jérôme, Fujita, Matthew K., Good, Jeffrey M., Greenbaum, Eli, Greene, Harry W., Hackett, Shannon, Hamidy, Amir, Hanken, James, Haryoko, Tri, Hawkins, Melissa T.R., Heaney, Lawrence R., Hillis, David M., Hollingsworth, Bradford D., Hornsby, Angela D., Hosner, Peter A., Irham, Mohammad, Jansa, Sharon, Jiménez, Rosa Alicia, Joseph, Leo, Kirchman, Jeremy J., LaDuc, Travis J., Leaché, Adam D., Lessa, Enrique P., López-Fernández, Hernán, Mason, Nicholas A., McCormack, John E., McMahan, Caleb D., Moyle, Robert G., Ojeda, Ricardo A., Olson, Link E., Onn, Chan Kin, Parenti, Lynne R., Parra-Olea, Gabriela, Patterson, Bruce D., Pauly, Gregory B., Pavan, Silvia E., Peterson, A. Townsend, Poe, Steven, Rabosky, Daniel L., Raxworthy, Christopher J., Reddy, Sushma, Rico-Guevara, Alejandro, Riyanto, Awal, Rocha, Luiz A., Ron, Santiago R., Rovito, Sean M., Rowe, Kevin C., Rowley, Jodi, Ruane, Sara, Salazar-Valenzuela, David, Shultz, Allison J., Sidlauskas, Brian, Sikes, Derek S., Simmons, Nancy B., Stiassny, Melanie L. J., Streicher, Jeffrey W., Stuart, Bryan L., Summers, Adam P., Tavera, Jose, Teta, Pablo, Thompson, Cody W., Timm, Robert M., Torres-Carvajal, Omar, Voelker, Gary, Voss, Robert S., Winker, Kevin, Witt, Christopher, Wommack, Elizabeth A., Zink, Robert M., Nachman, Michael W., Beckman, Elizabeth J., Bowie, Rauri C. K., Cicero, Carla, Conroy, Chris J., Dudley, Robert, Hayes, Tyrone B., Koo, Michelle S., Lacey, Eileen A., Martin, Christopher H., McGuire, Jimmy A., Patton, James L., Spencer, Carol L., Tarvin, Rebecca D., Wake, Marvalee H., Wang, Ian J., Achmadi, Anang, Álvarez-Castañeda, Sergio Ticul, Andersen, Michael J., Arroyave, Jairo, Austin, Christopher C., Barker, F. Keith, Barrow, Lisa N., Barrowclough, George F., Bates, John, Bauer, Aaron M., Bell, Kayce C., Bell, Rayna C., Bronson, Allison W., Brown, Rafe M., Burbrink, Frank T., Burns, Kevin J., Cadena, Carlos Daniel, Cannatella, David C., Castoe, Todd A., Chakrabarty, Prosanta, Colella, Jocelyn P., Cook, Joseph A., Cracraft, Joel L., Davis, Drew R., Rabosky, Alison R. Davis, D'Elía, Guillermo, Dumbacher, John P., Dunnum, Jonathan L., Edwards, Scott V., Esselstyn, Jacob A., Faivovich, Julián, Fjeldså, Jon, Flores-Villela, Oscar A., Ford, Kassandra, Fuchs, Jérôme, Fujita, Matthew K., Good, Jeffrey M., Greenbaum, Eli, Greene, Harry W., Hackett, Shannon, Hamidy, Amir, Hanken, James, Haryoko, Tri, Hawkins, Melissa T.R., Heaney, Lawrence R., Hillis, David M., Hollingsworth, Bradford D., Hornsby, Angela D., Hosner, Peter A., Irham, Mohammad, Jansa, Sharon, Jiménez, Rosa Alicia, Joseph, Leo, Kirchman, Jeremy J., LaDuc, Travis J., Leaché, Adam D., Lessa, Enrique P., López-Fernández, Hernán, Mason, Nicholas A., McCormack, John E., McMahan, Caleb D., Moyle, Robert G., Ojeda, Ricardo A., Olson, Link E., Onn, Chan Kin, Parenti, Lynne R., Parra-Olea, Gabriela, Patterson, Bruce D., Pauly, Gregory B., Pavan, Silvia E., Peterson, A. Townsend, Poe, Steven, Rabosky, Daniel L., Raxworthy, Christopher J., Reddy, Sushma, Rico-Guevara, Alejandro, Riyanto, Awal, Rocha, Luiz A., Ron, Santiago R., Rovito, Sean M., Rowe, Kevin C., Rowley, Jodi, Ruane, Sara, Salazar-Valenzuela, David, Shultz, Allison J., Sidlauskas, Brian, Sikes, Derek S., Simmons, Nancy B., Stiassny, Melanie L. J., Streicher, Jeffrey W., Stuart, Bryan L., Summers, Adam P., Tavera, Jose, Teta, Pablo, Thompson, Cody W., Timm, Robert M., Torres-Carvajal, Omar, Voelker, Gary, Voss, Robert S., Winker, Kevin, Witt, Christopher, Wommack, Elizabeth A., and Zink, Robert M.

Published

2023

3. Specimen collection is essential for modern science

Author

Nachman, Michael W., Beckman, Elizabeth J., Bowie, Rauri C. K., Cicero, Carla, Conroy, Chris J., Dudley, Robert, Hayes, Tyrone B., Koo, Michelle S., Lacey, Eileen A., Martin, Christopher H., McGuire, Jimmy A., Patton, James L., Spencer, Carol L., Tarvin, Rebecca D., Wake, Marvalee H., Wang, Ian J., Achmadi, Anang, Álvarez-Castañeda, Sergio Ticul, Andersen, Michael J., Arroyave, Jairo, Austin, Christopher C., Barker, F. Keith, Barrow, Lisa N., Barrowclough, George F., Bates, John, Bauer, Aaron M., Bell, Kayce C., Bell, Rayna C., Bronson, Allison W., Brown, Rafe M., Burbrink, Frank T., Burns, Kevin J., Cadena, Carlos Daniel, Cannatella, David C., Castoe, Todd A., Chakrabarty, Prosanta, Colella, Jocelyn P., Cook, Joseph A., Cracraft, Joel L., Davis, Drew R., Rabosky, Alison R. Davis, D'Elía, Guillermo, Dumbacher, John P., Dunnum, Jonathan L., Edwards, Scott V., Esselstyn, Jacob A., Faivovich, Julián, Fjeldså, Jon, Flores-Villela, Oscar A., Ford, Kassandra, Fuchs, Jérôme, Fujita, Matthew K., Good, Jeffrey M., Greenbaum, Eli, Greene, Harry W., Hackett, Shannon, Hamidy, Amir, Hanken, James, Haryoko, Tri, Hawkins, Melissa T.R., Heaney, Lawrence R., Hillis, David M., Hollingsworth, Bradford D., Hornsby, Angela D., Hosner, Peter A., Irham, Mohammad, Jansa, Sharon, Jiménez, Rosa Alicia, Joseph, Leo, Kirchman, Jeremy J., LaDuc, Travis J., Leaché, Adam D., Lessa, Enrique P., López-Fernández, Hernán, Mason, Nicholas A., McCormack, John E., McMahan, Caleb D., Moyle, Robert G., Ojeda, Ricardo A., Olson, Link E., Onn, Chan Kin, Parenti, Lynne R., Parra-Olea, Gabriela, Patterson, Bruce D., Pauly, Gregory B., Pavan, Silvia E., Peterson, A. Townsend, Poe, Steven, Rabosky, Daniel L., Raxworthy, Christopher J., Reddy, Sushma, Rico-Guevara, Alejandro, Riyanto, Awal, Rocha, Luiz A., Ron, Santiago R., Rovito, Sean M., Rowe, Kevin C., Rowley, Jodi, Ruane, Sara, Salazar-Valenzuela, David, Shultz, Allison J., Sidlauskas, Brian, Sikes, Derek S., Simmons, Nancy B., Stiassny, Melanie L. J., Streicher, Jeffrey W., Stuart, Bryan L., Summers, Adam P., Tavera, Jose, Teta, Pablo, Thompson, Cody W., Timm, Robert M., Torres-Carvajal, Omar, Voelker, Gary, Voss, Robert S., Winker, Kevin, Witt, Christopher, Wommack, Elizabeth A., Zink, Robert M., Nachman, Michael W., Beckman, Elizabeth J., Bowie, Rauri C. K., Cicero, Carla, Conroy, Chris J., Dudley, Robert, Hayes, Tyrone B., Koo, Michelle S., Lacey, Eileen A., Martin, Christopher H., McGuire, Jimmy A., Patton, James L., Spencer, Carol L., Tarvin, Rebecca D., Wake, Marvalee H., Wang, Ian J., Achmadi, Anang, Álvarez-Castañeda, Sergio Ticul, Andersen, Michael J., Arroyave, Jairo, Austin, Christopher C., Barker, F. Keith, Barrow, Lisa N., Barrowclough, George F., Bates, John, Bauer, Aaron M., Bell, Kayce C., Bell, Rayna C., Bronson, Allison W., Brown, Rafe M., Burbrink, Frank T., Burns, Kevin J., Cadena, Carlos Daniel, Cannatella, David C., Castoe, Todd A., Chakrabarty, Prosanta, Colella, Jocelyn P., Cook, Joseph A., Cracraft, Joel L., Davis, Drew R., Rabosky, Alison R. Davis, D'Elía, Guillermo, Dumbacher, John P., Dunnum, Jonathan L., Edwards, Scott V., Esselstyn, Jacob A., Faivovich, Julián, Fjeldså, Jon, Flores-Villela, Oscar A., Ford, Kassandra, Fuchs, Jérôme, Fujita, Matthew K., Good, Jeffrey M., Greenbaum, Eli, Greene, Harry W., Hackett, Shannon, Hamidy, Amir, Hanken, James, Haryoko, Tri, Hawkins, Melissa T.R., Heaney, Lawrence R., Hillis, David M., Hollingsworth, Bradford D., Hornsby, Angela D., Hosner, Peter A., Irham, Mohammad, Jansa, Sharon, Jiménez, Rosa Alicia, Joseph, Leo, Kirchman, Jeremy J., LaDuc, Travis J., Leaché, Adam D., Lessa, Enrique P., López-Fernández, Hernán, Mason, Nicholas A., McCormack, John E., McMahan, Caleb D., Moyle, Robert G., Ojeda, Ricardo A., Olson, Link E., Onn, Chan Kin, Parenti, Lynne R., Parra-Olea, Gabriela, Patterson, Bruce D., Pauly, Gregory B., Pavan, Silvia E., Peterson, A. Townsend, Poe, Steven, Rabosky, Daniel L., Raxworthy, Christopher J., Reddy, Sushma, Rico-Guevara, Alejandro, Riyanto, Awal, Rocha, Luiz A., Ron, Santiago R., Rovito, Sean M., Rowe, Kevin C., Rowley, Jodi, Ruane, Sara, Salazar-Valenzuela, David, Shultz, Allison J., Sidlauskas, Brian, Sikes, Derek S., Simmons, Nancy B., Stiassny, Melanie L. J., Streicher, Jeffrey W., Stuart, Bryan L., Summers, Adam P., Tavera, Jose, Teta, Pablo, Thompson, Cody W., Timm, Robert M., Torres-Carvajal, Omar, Voelker, Gary, Voss, Robert S., Winker, Kevin, Witt, Christopher, Wommack, Elizabeth A., and Zink, Robert M.

Published

2023

4. Population connectivity across a highly fragmented distribution:Phylogeography of the Chalcophaps doves

Author

DeRaad, Devon A., Manthey, Joseph D., Ostrow, Emily N., DeCicco, Lucas H., Andersen, Michael J., Hosner, Peter A., Shult, Hannah T., Joseph, Leo, Dumbacher, John P., Moyle, Robert G., DeRaad, Devon A., Manthey, Joseph D., Ostrow, Emily N., DeCicco, Lucas H., Andersen, Michael J., Hosner, Peter A., Shult, Hannah T., Joseph, Leo, Dumbacher, John P., and Moyle, Robert G.

Abstract

Chalcophaps is a morphologically conserved genus of ground-walking doves distributed from India to mainland China, south to Australia, and across the western Pacific to Vanuatu. Here, we reconstruct the evolutionary history of this genus using DNA sequence data from two nuclear genes and one mitochondrial gene, sampled from throughout the geographic range of Chalcophaps. We find support for three major evolutionary lineages in our phylogenetic reconstruction, each corresponding to the three currently recognized Chalcophaps species. Despite this general concordance, we identify discordant mitochondrial and nuclear ancestries in the subspecies C. longirostris timorensis, raising further questions about the evolutionary history of this Timor endemic population. Within each of the three species, we find evidence for isolation by distance or hierarchical population structure, indicating an important role for geography in the diversification of this genus. Despite being distributed broadly across a highly fragmented geographic region known as a hotspot for avian diversification, the Chalcophaps doves show modest levels of phenotypic and genetic diversity, a pattern potentially explained by strong population connectivity owing to high overwater dispersal capability.

Published

2022

5. The role of evolutionary time, diversification rates and dispersal in determining the global diversity of a large radiation of passerine birds

Author

Cai, Tianlong, Shao, Shimiao, Kennedy, Jonathan D., Alstrom, Per, Moyle, Robert G., Qu, Yanhua, Lei, Fumin, Fjeldså, Jon, Cai, Tianlong, Shao, Shimiao, Kennedy, Jonathan D., Alstrom, Per, Moyle, Robert G., Qu, Yanhua, Lei, Fumin, and Fjeldså, Jon

Abstract

Aim: Variation in species diversity among different geographical areas may result from differences in speciation and extinction rates, immigration and time for diversification. An area with high species diversity may be the result of a high net diversification rate, multiple immigration events from adjacent regions, and a long time available for the accumulation of species (known as the 'time-for-speciation effect'). Here, we examine the relative importance of the three aforementioned processes in shaping the geographical diversity patterns of a large radiation of passerine birds.Location: Global.Taxon: Babblers (Aves: Passeriformes).Methods: Using a comprehensive phylogeny of extant species (similar to 90% sampled) and distributions of the world's babblers, we reconstructed their biogeographical history and analysed the diversification dynamics. We examined how species richness correlates with the timing of regional colonization, the number of immigration events and the rate of speciation within all 13 geographical distribution regions.Results: We found that babblers likely originated in the Sino-Himalayan Mountains (SHM) in the early Miocene, suggesting a long time for diversification and species accumulation within the SHM. Regression analyses showed the regional diversity of babblers can be well explained by the timing of the first colonization within of these areas, while differences in rates of speciation or immigration have far weaker effects. Nonetheless, the rapid speciation of Zosterops during the Pleistocene has accounted for the increased diversification and accumulation of species in the oceanic islands.Main Conclusions: Our results suggest that the global diversity patterns of babblers have predominantly been shaped by the time-for-speciation effect. Our findings also support an origin centred in tropical and subtropical parts of the SHM, with a cradle of recent diversification in the oceanic islands of the Indo-Pa

Published

2020

6. The role of evolutionary time, diversification rates and dispersal in determining the global diversity of a large radiation of passerine birds

Author

Cai, Tianlong, Shao, Shimiao, Kennedy, Jonathan D., Alström, Per, Moyle, Robert G., Qu, Yanhua, Lei, Fumin, Fjelds, Jon, Cai, Tianlong, Shao, Shimiao, Kennedy, Jonathan D., Alström, Per, Moyle, Robert G., Qu, Yanhua, Lei, Fumin, and Fjelds, Jon

Abstract

Aim: Variation in species diversity among different geographical areas may result from differences in speciation and extinction rates, immigration and time for diversification. An area with high species diversity may be the result of a high net diversification rate, multiple immigration events from adjacent regions, and a long time available for the accumulation of species (known as the 'time-for-speciation effect'). Here, we examine the relative importance of the three aforementioned processes in shaping the geographical diversity patterns of a large radiation of passerine birds. Location: Global. Taxon: Babblers (Aves: Passeriformes). Methods: Using a comprehensive phylogeny of extant species (similar to 90% sampled) and distributions of the world's babblers, we reconstructed their biogeographical history and analysed the diversification dynamics. We examined how species richness correlates with the timing of regional colonization, the number of immigration events and the rate of speciation within all 13 geographical distribution regions. Results: We found that babblers likely originated in the Sino-Himalayan Mountains (SHM) in the early Miocene, suggesting a long time for diversification and species accumulation within the SHM. Regression analyses showed the regional diversity of babblers can be well explained by the timing of the first colonization within of these areas, while differences in rates of speciation or immigration have far weaker effects. Nonetheless, the rapid speciation of Zosterops during the Pleistocene has accounted for the increased diversification and accumulation of species in the oceanic islands. Main Conclusions: Our results suggest that the global diversity patterns of babblers have predominantly been shaped by the time-for-speciation effect. Our findings also support an origin centred in tropical and subtropical parts of the SHM, with a cradle of recent diversification in the oceanic islands of the Indo-Pacific and Indian Ocean regions, w

Published

2020

7. Genomic differentiation in an endemic Philippine genus (Aves:Sarcophanops) owing to geographical isolation on recently disassociated islands

Author

Campillo, Luke C., Manthey, Joseph D., Thomson, Robert C., Hosner, Peter A., Moyle, Robert G., Campillo, Luke C., Manthey, Joseph D., Thomson, Robert C., Hosner, Peter A., and Moyle, Robert G.

Abstract

Phylogeographical studies of Philippine vertebrates have demonstrated that genetic variation is broadly partitioned by Pleistocene island aggregation. Contemporary island discontinuity is expected to influence genetic differentiation but remains relatively undocumented, perhaps because the current episode of island isolation started in relatively recent times. We investigated inter- and intra-island population structure in a Philippine endemic bird genus (Sarcophanops) to determine whether genetic differentiation has evolved during the recent period of isolation. We sequenced thousands of genome-wide restriction site associated DNA (RAD) markers from throughout the Mindanao group to assess fine-scale genetic structure across islands. Specifically, we investigated patterns of gene flow and connectivity within and between taxonomic and geographical bounds. A previous assessment of mitochondrial DNA detected deep structure between Sarcophanops samarensis and a sister species, Sarcophanops steerii, but was insufficient to detect differentiation within either species. Analysis of RAD markers, however, revealed structure within S. samarensis between the islands of Samar/Leyte and Bohol. This genetic differentiation probably demonstrates an effect of recent geographical isolation (after the Last Glacial Maximum) on the genetic structure of Philippine avifauna. We suggest that the general lack of evidence for differentiation between recently isolated populations is a failure to detect subtle population structure owing to past genetic sampling constraints, rather than the absence of such structure.

Published

2020

8. Extensive paraphyly in the typical owl family (Strigidae)

Author

Salter, Jessie F., Oliveros, Carl H., Hosner, Peter A., Manthey, Joseph D., Robbins, Mark B., Moyle, Robert G., Brumfield, Robb T., Faircloth, Brant C., Salter, Jessie F., Oliveros, Carl H., Hosner, Peter A., Manthey, Joseph D., Robbins, Mark B., Moyle, Robert G., Brumfield, Robb T., and Faircloth, Brant C.

Abstract

The typical owl family (Strigidae) comprises 194 species in 28 genera, 14 of which are monotypic. Relationships within and among genera in the typical owls have been challenging to discern because mitochondrial data have produced equivocal results and because many monotypic genera have been omitted from previous molecular analyses. Here, we collected and analyzed DNA sequences of ultraconserved elements (UCEs) from 43 species of typical owls to produce concatenated and multispecies coalescent-based phylogenetic hypotheses for all but one genus in the typical owl family. Our results reveal extensive paraphyly of taxonomic groups across phylogenies inferred using different analytical approaches and suggest the genera Athene, Otus, Asio, Megascops, Bubo, and Strix are paraphyletic, whereas Ninox and Glaucidium are polyphyletic. Secondary analyses of protein-coding mitochondrial genes harvested from off-target sequencing reads and mitochondrial genomes downloaded from GenBank generally support the extent of paraphyly we observe, although some disagreements exist at higher taxonomic levels between our nuclear and mitochondrial phylogenetic hypotheses. Overall, our results demonstrate the importance of taxon sampling for understanding and describing evolutionary relationships in this group, as well as the need for additional sampling, study, and taxonomic revision of typical owl species. Additionally, our findings highlight how both divergence and convergence in morphological characters have obscured our understanding of the evolutionary history of typical owls, particularly those with insular distributions.

Published

2020

9. The role of evolutionary time, diversification rates and dispersal in determining the global diversity of a large radiation of passerine birds

Author

Cai, Tianlong, Shao, Shimiao, Kennedy, Jonathan D., Alstrom, Per, Moyle, Robert G., Qu, Yanhua, Lei, Fumin, Fjeldså, Jon, Cai, Tianlong, Shao, Shimiao, Kennedy, Jonathan D., Alstrom, Per, Moyle, Robert G., Qu, Yanhua, Lei, Fumin, and Fjeldså, Jon

Abstract

Aim: Variation in species diversity among different geographical areas may result from differences in speciation and extinction rates, immigration and time for diversification. An area with high species diversity may be the result of a high net diversification rate, multiple immigration events from adjacent regions, and a long time available for the accumulation of species (known as the 'time-for-speciation effect'). Here, we examine the relative importance of the three aforementioned processes in shaping the geographical diversity patterns of a large radiation of passerine birds.Location: Global.Taxon: Babblers (Aves: Passeriformes).Methods: Using a comprehensive phylogeny of extant species (similar to 90% sampled) and distributions of the world's babblers, we reconstructed their biogeographical history and analysed the diversification dynamics. We examined how species richness correlates with the timing of regional colonization, the number of immigration events and the rate of speciation within all 13 geographical distribution regions.Results: We found that babblers likely originated in the Sino-Himalayan Mountains (SHM) in the early Miocene, suggesting a long time for diversification and species accumulation within the SHM. Regression analyses showed the regional diversity of babblers can be well explained by the timing of the first colonization within of these areas, while differences in rates of speciation or immigration have far weaker effects. Nonetheless, the rapid speciation of Zosterops during the Pleistocene has accounted for the increased diversification and accumulation of species in the oceanic islands.Main Conclusions: Our results suggest that the global diversity patterns of babblers have predominantly been shaped by the time-for-speciation effect. Our findings also support an origin centred in tropical and subtropical parts of the SHM, with a cradle of recent diversification in the oceanic islands of the Indo-Pa

Published

2020

10. Extensive paraphyly in the typical owl family (Strigidae)

Author

Salter, Jessie F., Oliveros, Carl H., Hosner, Peter A., Manthey, Joseph D., Robbins, Mark B., Moyle, Robert G., Brumfield, Robb T., Faircloth, Brant C., Salter, Jessie F., Oliveros, Carl H., Hosner, Peter A., Manthey, Joseph D., Robbins, Mark B., Moyle, Robert G., Brumfield, Robb T., and Faircloth, Brant C.

Abstract

The typical owl family (Strigidae) comprises 194 species in 28 genera, 14 of which are monotypic. Relationships within and among genera in the typical owls have been challenging to discern because mitochondrial data have produced equivocal results and because many monotypic genera have been omitted from previous molecular analyses. Here, we collected and analyzed DNA sequences of ultraconserved elements (UCEs) from 43 species of typical owls to produce concatenated and multispecies coalescent-based phylogenetic hypotheses for all but one genus in the typical owl family. Our results reveal extensive paraphyly of taxonomic groups across phylogenies inferred using different analytical approaches and suggest the genera Athene, Otus, Asio, Megascops, Bubo, and Strix are paraphyletic, whereas Ninox and Glaucidium are polyphyletic. Secondary analyses of protein-coding mitochondrial genes harvested from off-target sequencing reads and mitochondrial genomes downloaded from GenBank generally support the extent of paraphyly we observe, although some disagreements exist at higher taxonomic levels between our nuclear and mitochondrial phylogenetic hypotheses. Overall, our results demonstrate the importance of taxon sampling for understanding and describing evolutionary relationships in this group, as well as the need for additional sampling, study, and taxonomic revision of typical owl species. Additionally, our findings highlight how both divergence and convergence in morphological characters have obscured our understanding of the evolutionary history of typical owls, particularly those with insular distributions.

Published

2020

11. Earth history and the passerine superradiation

Author

Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Barker, F. Keith, Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Chesser, R. Terry, Claramunt, Santiago, Cracraft, Joel, Cuervo, Andres M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Peterson, A. Townsend, Robbins, Mark B., Sheldon, Frederick H., Silveira, Luis Fabio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., Faircloth, Brant C., Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Barker, F. Keith, Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Chesser, R. Terry, Claramunt, Santiago, Cracraft, Joel, Cuervo, Andres M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Peterson, A. Townsend, Robbins, Mark B., Sheldon, Frederick H., Silveira, Luis Fabio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., and Faircloth, Brant C.

Abstract

Avian diversification has been influenced by global climate change, plate tectonic movements, and mass extinction events. However, the impact of these factors on the diversification of the hyper-diverse perching birds (passerines) is unclear because family level relationships are unresolved and the timing of splitting events among lineages is uncertain. We analyzed DNA data from 4,060 nuclear loci and 137 passerine families using concatenation and coalescent approaches to infer a comprehensive phylogenetic hypothesis that clarifies relationships among all passerine families. Then, we calibrated this phylogeny using 13 fossils to examine the effects of different events in Earth history on the timing and rate of passerine diversification. Our analyses reconcile passerine diversification with the fossil and geological records; suggest that passerines originated on the Australian landmass ∼47 Ma; and show that subsequent dispersal and diversification of passerines was affected by a number of climatological and geological events, such as Oligocene glaciation and inundation of the New Zealand landmass. Although passerine diversification rates fluctuated throughout the Cenozoic, we find no link between the rate of passerine diversification and Cenozoic global temperature, and our analyses show that the increases in passerine diversification rate we observe are disconnected from the colonization of new continents. Taken together, these results suggest more complex mechanisms than temperature change or ecological opportunity have controlled macroscale patterns of passerine speciation.

Published

2019

12. Earth history and the passerine superradiation

Author

Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Barker, F. Keith, Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Chesser, R. Terry, Claramunt, Santiago, Cracraft, Joel, Cuervo, Andres M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Peterson, A. Townsend, Robbins, Mark B., Sheldon, Frederick H., Silveira, Luis Fabio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., Faircloth, Brant C., Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Barker, F. Keith, Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Chesser, R. Terry, Claramunt, Santiago, Cracraft, Joel, Cuervo, Andres M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Peterson, A. Townsend, Robbins, Mark B., Sheldon, Frederick H., Silveira, Luis Fabio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., and Faircloth, Brant C.

Abstract

Avian diversification has been influenced by global climate change, plate tectonic movements, and mass extinction events. However, the impact of these factors on the diversification of the hyper-diverse perching birds (passerines) is unclear because family level relationships are unresolved and the timing of splitting events among lineages is uncertain. We analyzed DNA data from 4,060 nuclear loci and 137 passerine families using concatenation and coalescent approaches to infer a comprehensive phylogenetic hypothesis that clarifies relationships among all passerine families. Then, we calibrated this phylogeny using 13 fossils to examine the effects of different events in Earth history on the timing and rate of passerine diversification. Our analyses reconcile passerine diversification with the fossil and geological records; suggest that passerines originated on the Australian landmass ∼47 Ma; and show that subsequent dispersal and diversification of passerines was affected by a number of climatological and geological events, such as Oligocene glaciation and inundation of the New Zealand landmass. Although passerine diversification rates fluctuated throughout the Cenozoic, we find no link between the rate of passerine diversification and Cenozoic global temperature, and our analyses show that the increases in passerine diversification rate we observe are disconnected from the colonization of new continents. Taken together, these results suggest more complex mechanisms than temperature change or ecological opportunity have controlled macroscale patterns of passerine speciation.

Published

2019

13. Earth history and the passerine superradiation

Author

Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Barker, F. Keith, Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Chesser, R. Terry, Claramunt, Santiago, Cracraft, Joel, Cuervo, Andres M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Peterson, A. Townsend, Robbins, Mark B., Sheldon, Frederick H., Silveira, Luis Fabio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., Faircloth, Brant C., Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Barker, F. Keith, Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Chesser, R. Terry, Claramunt, Santiago, Cracraft, Joel, Cuervo, Andres M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Peterson, A. Townsend, Robbins, Mark B., Sheldon, Frederick H., Silveira, Luis Fabio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., and Faircloth, Brant C.

Abstract

Avian diversification has been influenced by global climate change, plate tectonic movements, and mass extinction events. However, the impact of these factors on the diversification of the hyper-diverse perching birds (passerines) is unclear because family level relationships are unresolved and the timing of splitting events among lineages is uncertain. We analyzed DNA data from 4,060 nuclear loci and 137 passerine families using concatenation and coalescent approaches to infer a comprehensive phylogenetic hypothesis that clarifies relationships among all passerine families. Then, we calibrated this phylogeny using 13 fossils to examine the effects of different events in Earth history on the timing and rate of passerine diversification. Our analyses reconcile passerine diversification with the fossil and geological records; suggest that passerines originated on the Australian landmass ∼47 Ma; and show that subsequent dispersal and diversification of passerines was affected by a number of climatological and geological events, such as Oligocene glaciation and inundation of the New Zealand landmass. Although passerine diversification rates fluctuated throughout the Cenozoic, we find no link between the rate of passerine diversification and Cenozoic global temperature, and our analyses show that the increases in passerine diversification rate we observe are disconnected from the colonization of new continents. Taken together, these results suggest more complex mechanisms than temperature change or ecological opportunity have controlled macroscale patterns of passerine speciation.

Published

2019

14. Earth history and the passerine superradiation

Author

Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Barker, F. Keith, Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Chesser, R. Terry, Claramunt, Santiago, Cracraft, Joel, Cuervo, Andres M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Peterson, A. Townsend, Robbins, Mark B., Sheldon, Frederick H., Silveira, Luis Fabio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., Faircloth, Brant C., Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Barker, F. Keith, Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Chesser, R. Terry, Claramunt, Santiago, Cracraft, Joel, Cuervo, Andres M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Peterson, A. Townsend, Robbins, Mark B., Sheldon, Frederick H., Silveira, Luis Fabio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., and Faircloth, Brant C.

Abstract

Avian diversification has been influenced by global climate change, plate tectonic movements, and mass extinction events. However, the impact of these factors on the diversification of the hyper-diverse perching birds (passerines) is unclear because family level relationships are unresolved and the timing of splitting events among lineages is uncertain. We analyzed DNA data from 4,060 nuclear loci and 137 passerine families using concatenation and coalescent approaches to infer a comprehensive phylogenetic hypothesis that clarifies relationships among all passerine families. Then, we calibrated this phylogeny using 13 fossils to examine the effects of different events in Earth history on the timing and rate of passerine diversification. Our analyses reconcile passerine diversification with the fossil and geological records; suggest that passerines originated on the Australian landmass ∼47 Ma; and show that subsequent dispersal and diversification of passerines was affected by a number of climatological and geological events, such as Oligocene glaciation and inundation of the New Zealand landmass. Although passerine diversification rates fluctuated throughout the Cenozoic, we find no link between the rate of passerine diversification and Cenozoic global temperature, and our analyses show that the increases in passerine diversification rate we observe are disconnected from the colonization of new continents. Taken together, these results suggest more complex mechanisms than temperature change or ecological opportunity have controlled macroscale patterns of passerine speciation.

Published

2019

15. Earth history and the passerine superradiation

Author

Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Barker, F. Keith, Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Chesser, R. Terry, Claramunt, Santiago, Cracraft, Joel, Cuervo, Andres M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Peterson, A. Townsend, Robbins, Mark B., Sheldon, Frederick H., Silveira, Luis Fabio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., Faircloth, Brant C., Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Barker, F. Keith, Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Chesser, R. Terry, Claramunt, Santiago, Cracraft, Joel, Cuervo, Andres M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Peterson, A. Townsend, Robbins, Mark B., Sheldon, Frederick H., Silveira, Luis Fabio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., and Faircloth, Brant C.

Abstract

Avian diversification has been influenced by global climate change, plate tectonic movements, and mass extinction events. However, the impact of these factors on the diversification of the hyper-diverse perching birds (passerines) is unclear because family level relationships are unresolved and the timing of splitting events among lineages is uncertain. We analyzed DNA data from 4,060 nuclear loci and 137 passerine families using concatenation and coalescent approaches to infer a comprehensive phylogenetic hypothesis that clarifies relationships among all passerine families. Then, we calibrated this phylogeny using 13 fossils to examine the effects of different events in Earth history on the timing and rate of passerine diversification. Our analyses reconcile passerine diversification with the fossil and geological records; suggest that passerines originated on the Australian landmass ∼47 Ma; and show that subsequent dispersal and diversification of passerines was affected by a number of climatological and geological events, such as Oligocene glaciation and inundation of the New Zealand landmass. Although passerine diversification rates fluctuated throughout the Cenozoic, we find no link between the rate of passerine diversification and Cenozoic global temperature, and our analyses show that the increases in passerine diversification rate we observe are disconnected from the colonization of new continents. Taken together, these results suggest more complex mechanisms than temperature change or ecological opportunity have controlled macroscale patterns of passerine speciation.

Published

2019

16. Near-complete phylogeny and taxonomic revision of the world's babblers (Aves: Passeriformes)

Author

Cai, Tianlong, Cibois, Alice, Alström, Per, Moyle, Robert G., Kennedy, Jonathan D., Shao, Shimiao, Zhang, Ruiying, Irestedt, Martin, Ericson, Per G. P., Gelang, Magnus, Qu, Yanhua, Lei, Fumin, Fjeldså, Jon, Cai, Tianlong, Cibois, Alice, Alström, Per, Moyle, Robert G., Kennedy, Jonathan D., Shao, Shimiao, Zhang, Ruiying, Irestedt, Martin, Ericson, Per G. P., Gelang, Magnus, Qu, Yanhua, Lei, Fumin, and Fjeldså, Jon

Abstract

The babblers are a diverse group of passerine birds comprising 452 species. The group was long regarded as a “scrap basket” in taxonomic classification schemes. Although several studies have assessed the phylogenetic relationships for subsets of babblers during the past two decades, a comprehensive phylogeny of this group has been lacking. In this study, we used five mitochondrial and seven nuclear loci to generate a dated phylogeny for babblers. This phylogeny includes 402 species (ca. 89% of the overall clade) from 75 genera (97%) and all five currently recognized families, providing a robust basis for taxonomic revision. Our phylogeny supports seven major clades and reveals several non-monophyletic genera. Divergence time estimates indicate that the seven major clades diverged around the same time (18–20 million years ago, Ma) in the early Miocene. We use the phylogeny in a consistent way to propose a new taxonomy, with seven families and 64 genera of babblers, and a new linear sequence of names.

Published

2019

17. Rapid Laurasian diversification of a pantropical bird family during the Oligocene–Miocene transition

Author

Oliveros, Carl H., Andersen, Michael J., Hosner, Peter A., Mauck, William M., Sheldon, Frederick H., Cracraft, Joel, Moyle, Robert G., Oliveros, Carl H., Andersen, Michael J., Hosner, Peter A., Mauck, William M., Sheldon, Frederick H., Cracraft, Joel, and Moyle, Robert G.

Abstract

Disjunct, pantropical distributions are a common pattern among avian lineages, but disentangling multiple scenarios that can produce them requires accurate estimates of historical relationships and timescales. Here, we clarify the biogeographical history of the pantropical avian family of trogons (Trogonidae) by re-examining their phylogenetic relationships and divergence times with genome-scale data. We estimated trogon phylogeny by analysing thousands of ultraconserved element (UCE) loci from all extant trogon genera with concatenation and coalescent approaches. We then estimated a time frame for trogon diversification using MCMCTree and fossil calibrations, after which we performed ancestral area estimation using BioGeoBEARS. We recovered the first well-resolved hypothesis of relationships among trogon genera. Trogons comprise three clades, each confined to one of three biogeographical regions: Africa, Asia and the Neotropics, with the African clade sister to the others. These clades diverged rapidly during the Oligocene-Miocene transition. Our biogeographical analyses identify a Eurasian origin for stem trogons and a crown clade arising from ancestors broadly distributed across Laurasia and Africa. The pantropical ranges of trogons are relicts of a broader Afro-Laurasian distribution that was fragmented across Africa, Asia and the New World in near coincident fashion during the Oligocene-Miocene transition by global cooling and changing habitats along the Beringian land bridge and North Africa.

Published

2019

18. Earth history and the passerine superradiation

Author

Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Keith Barker, F., Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Terry Chesser, R., Claramunt, Santiago, Cracraft, Joel, Cuervo, Andrés M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Townsend Peterson, A., Robbins, Mark B., Sheldon, Frederick H., Silveira, Luís Fábio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., Faircloth, Brant C., Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Keith Barker, F., Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Terry Chesser, R., Claramunt, Santiago, Cracraft, Joel, Cuervo, Andrés M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Townsend Peterson, A., Robbins, Mark B., Sheldon, Frederick H., Silveira, Luís Fábio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., and Faircloth, Brant C.

Abstract

Avian diversification has been influenced by global climate change, plate tectonic movements, and mass extinction events. However, the impact of these factors on the diversification of the hyperdiverse perching birds (passerines) is unclear because family level relationships are unresolved and the timing of splitting events among lineages is uncertain. We analyzed DNA data from 4,060 nuclear loci and 137 passerine families using concatenation and coalescent approaches to infer a comprehensive phylogenetic hypothesis that clarifies relationships among all passerine families. Then, we calibrated this phylogeny using 13 fossils to examine the effects of different events in Earth history on the timing and rate of passerine diversification. Our analyses reconcile passerine diversification with the fossil and geological records; suggest that passerines originated on the Australian landmass ∼47 Ma; and show that subsequent dispersal and diversification of passerines was affected by a number of climatological and geological events, such as Oligocene glaciation and inundation of the New Zealand landmass. Although passerine diversification rates fluctuated throughout the Cenozoic, we find no link between the rate of passerine diversification and Cenozoic global temperature, and our analyses show that the increases in passerine diversification rate we observe are disconnected from the colonization of new continents. Taken together, these results suggest more complex mechanisms than temperature change or ecological opportunity have controlled macroscale patterns of passerine speciation.

Published

2019

19. Earth history and the passerine superradiation

Author

Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Keith Barker, F., Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Terry Chesser, R., Claramunt, Santiago, Cracraft, Joel, Cuervo, Andrés M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Townsend Peterson, A., Robbins, Mark B., Sheldon, Frederick H., Silveira, Luís Fábio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., Faircloth, Brant C., Oliveros, Carl H., Field, Daniel J., Ksepka, Daniel T., Keith Barker, F., Aleixo, Alexandre, Andersen, Michael J., Alström, Per, Benz, Brett W., Braun, Edward L., Braun, Michael J., Bravo, Gustavo A., Brumfield, Robb T., Terry Chesser, R., Claramunt, Santiago, Cracraft, Joel, Cuervo, Andrés M., Derryberry, Elizabeth P., Glenn, Travis C., Harvey, Michael G., Hosner, Peter A., Joseph, Leo, Kimball, Rebecca T., Mack, Andrew L., Miskelly, Colin M., Townsend Peterson, A., Robbins, Mark B., Sheldon, Frederick H., Silveira, Luís Fábio, Smith, Brian Tilston, White, Noor D., Moyle, Robert G., and Faircloth, Brant C.

Abstract

Avian diversification has been influenced by global climate change, plate tectonic movements, and mass extinction events. However, the impact of these factors on the diversification of the hyperdiverse perching birds (passerines) is unclear because family level relationships are unresolved and the timing of splitting events among lineages is uncertain. We analyzed DNA data from 4,060 nuclear loci and 137 passerine families using concatenation and coalescent approaches to infer a comprehensive phylogenetic hypothesis that clarifies relationships among all passerine families. Then, we calibrated this phylogeny using 13 fossils to examine the effects of different events in Earth history on the timing and rate of passerine diversification. Our analyses reconcile passerine diversification with the fossil and geological records; suggest that passerines originated on the Australian landmass ∼47 Ma; and show that subsequent dispersal and diversification of passerines was affected by a number of climatological and geological events, such as Oligocene glaciation and inundation of the New Zealand landmass. Although passerine diversification rates fluctuated throughout the Cenozoic, we find no link between the rate of passerine diversification and Cenozoic global temperature, and our analyses show that the increases in passerine diversification rate we observe are disconnected from the colonization of new continents. Taken together, these results suggest more complex mechanisms than temperature change or ecological opportunity have controlled macroscale patterns of passerine speciation.

Published

2019

20. Comprehensive molecular phylogeny of the grassbirds and allies (Locustellidae) reveals extensive non-monophyly of traditional genera, and a proposal for a new classification

Author

Alström, Per, Cibois, Alice, Irestedt, Martin, Zuccon, Dario, Gelang, Magnus, Fjeldså, Jon, Andersen, Michael J., Moyle, Robert G., Pasquet, Eric, Olsson, Urban, Alström, Per, Cibois, Alice, Irestedt, Martin, Zuccon, Dario, Gelang, Magnus, Fjeldså, Jon, Andersen, Michael J., Moyle, Robert G., Pasquet, Eric, and Olsson, Urban

Abstract

The widespread Old World avian family Locustellidae (‘grassbirds and allies’) comprises 62 extant species in 11 genera. In the present study, we used one mitochondrial and, for most species, four nuclear loci to infer the phylogeny of this family. We analysed 59 species, including the five previously unsampled genera plus two genera that had not before been analysed in a densely sampled dataset. This study revealed extensive disagreement with current taxonomy; the genera Bradypterus, Locustella, Megalurus, Megalurulus and Schoenicola were all found to be non-monophyletic. Non-monophyly was particularly pronounced for Megalurus, which was widely scattered across the tree. Three of the five monotypic genera (Amphilais, Buettikoferella and Malia) were nested within other genera; one monotypic genus (Chaetornis) formed a clade with one of the two species of Schoenicola; whereas the position of the fifth monotypic genus (Elaphrornis) was unresolved. Robsonius was confirmed as sister to the other genera. We propose a phylogenetically informed revision of genus-level taxonomy, including one new generic name. Finally, we highlight several non-monophyletic species complexes and deep intra-species divergences that point to conflict in taxonomy and suggest an underestimation of current species diversity in this group.

Published

2018

21. Mutations in different pigmentation genes are associated with parallel melanism in island flycatchers

Author

Uy, J. Albert C., Cooper, Elizabeth A., Cutie, Stephen, Concannon, Moira R., Poelstra, Jelmer W., Moyle, Robert G., Filardi, Christopher E., Uy, J. Albert C., Cooper, Elizabeth A., Cutie, Stephen, Concannon, Moira R., Poelstra, Jelmer W., Moyle, Robert G., and Filardi, Christopher E.

Abstract

The independent evolution of similar traits across multiple taxa provides some of the most compelling evidence of natural selection. Little is known, however, about the genetic basis of these convergent or parallel traits: are they mediated by identical or different mutations in the same genes, or unique mutations in different genes? Using a combination of candidate gene and reduced representation genomic sequencing approaches, we explore the genetic basis of and the evolutionary processes that mediate similar plumage colour shared by isolated populations of the Monarcha castaneiventris flycatcher of the Solomon Islands. A genome-wide association study (GWAS) that explicitly controlled for population structure revealed that mutations in known pigmentation genes are the best predictors of parallel plumage colour. That is, entirely black or melanic birds from one small island share an amino acid substitution in the melanocortin-1 receptor (MC1R), whereas similarly melanic birds from another small island over 100 km away share an amino acid substitution in a predicted binding site of agouti signalling protein (ASIP). A third larger island, which separates the two melanic populations, is inhabited by birds with chestnut bellies that lack the melanic MC1R and ASIP allelic variants. Formal F-STs outlier tests corroborated the results of the GWAS and suggested that strong, directional selection drives the near fixation of the MC1R and ASIP variants across islands. Our results, therefore, suggest that selection acting on different mutations with large phenotypic effects can drive the evolution of parallel melanism, despite the relatively small population size on islands.

Published

2016

22. Historical biogeography of an Indo-Pacific passerine bird family (Pachycephalidae):different colonization patterns in the Indonesian and Melanesian archipelagos

Author

Jønsson, Knud Andreas, Bowie, Rauri C. K., Moyle, Robert G., Christidis, Les, Norman, Janette A, Benz, Brett W., Fjeldså, Jon, Jønsson, Knud Andreas, Bowie, Rauri C. K., Moyle, Robert G., Christidis, Les, Norman, Janette A, Benz, Brett W., and Fjeldså, Jon

Published

2010

23. Phylogeny and biogeography of Oriolidae (Aves: Passeriformes)

Author

Jønsson, Knud Andreas, Bowie, Rauri C.K., Moyle, Robert G., Irestedt, Martin, Christidis, Les, Norman, Janette A., Fjeldså, Jon, Jønsson, Knud Andreas, Bowie, Rauri C.K., Moyle, Robert G., Irestedt, Martin, Christidis, Les, Norman, Janette A., and Fjeldså, Jon

Published

2010

24. Endemic avifaunal biodiversity and tropical forest loss in Makira, a mountainous Pacific island

Author

Danielsen, Finn, Filardi, Christopher E., Jønsson, Knud Andreas, Kohaia, Victor, Krabbe, Niels Kaare, Kristensen, Jan Bolding, Moyle, Robert G., Pikacha, Patrick, Poulsen, Michael K., Sørensen, Mikael K., Tatahu, Charles, Waihuru, Joseph, Fjeldså, Jon, Danielsen, Finn, Filardi, Christopher E., Jønsson, Knud Andreas, Kohaia, Victor, Krabbe, Niels Kaare, Kristensen, Jan Bolding, Moyle, Robert G., Pikacha, Patrick, Poulsen, Michael K., Sørensen, Mikael K., Tatahu, Charles, Waihuru, Joseph, and Fjeldså, Jon

Published

2010

25. Historical biogeography of an Indo-Pacific passerine bird family (Pachycephalidae):different colonization patterns in the Indonesian and Melanesian archipelagos

Author

Jønsson, Knud Andreas, Bowie, Rauri C. K., Moyle, Robert G., Christidis, Les, Norman, Janette A, Benz, Brett W., Fjeldså, Jon, Jønsson, Knud Andreas, Bowie, Rauri C. K., Moyle, Robert G., Christidis, Les, Norman, Janette A, Benz, Brett W., and Fjeldså, Jon

Published

2010

26. Endemic avifaunal biodiversity and tropical forest loss in Makira, a mountainous Pacific island

Author

Danielsen, Finn, Filardi, Christopher E., Jønsson, Knud Andreas, Kohaia, Victor, Krabbe, Niels Kaare, Kristensen, Jan Bolding, Moyle, Robert G., Pikacha, Patrick, Poulsen, Michael K., Sørensen, Mikael K., Tatahu, Charles, Waihuru, Joseph, Fjeldså, Jon, Danielsen, Finn, Filardi, Christopher E., Jønsson, Knud Andreas, Kohaia, Victor, Krabbe, Niels Kaare, Kristensen, Jan Bolding, Moyle, Robert G., Pikacha, Patrick, Poulsen, Michael K., Sørensen, Mikael K., Tatahu, Charles, Waihuru, Joseph, and Fjeldså, Jon

Published

2010

27. Phylogeny and biogeography of Oriolidae (Aves: Passeriformes)

Author

Jønsson, Knud Andreas, Bowie, Rauri C.K., Moyle, Robert G., Irestedt, Martin, Christidis, Les, Norman, Janette A., Fjeldså, Jon, Jønsson, Knud Andreas, Bowie, Rauri C.K., Moyle, Robert G., Irestedt, Martin, Christidis, Les, Norman, Janette A., and Fjeldså, Jon

Published

2010

28. Observations on the ecology, distribution and biogeography of forest birds in Sabah, Malaysia

Author

Sheldon, Frederick H., Haw, Chuan Lim, Jamili Nais, Maklarin Lakim, Augustine Tuuga, Peter Malim, Jaffit Majuakim, Lo, Albert, Schilthuizen, Menno, Hosner, Peter A., Moyle, Robert G., Sheldon, Frederick H., Haw, Chuan Lim, Jamili Nais, Maklarin Lakim, Augustine Tuuga, Peter Malim, Jaffit Majuakim, Lo, Albert, Schilthuizen, Menno, Hosner, Peter A., and Moyle, Robert G.

Abstract

From January 2004 to July 2008, we surveyed and collected birds at 15 sites in Sabah, Malaysian Borneo. This work was designed to (1) document bird occurrence in areas and habitats that had been poorly surveyed in the past, (2) provide specimens for molecular genetic studies of bird evolution in Borneo, and (3) examine the occurrence of forest birds in agricultural and industrial tree plantations. The research disclosed new elevational, habitat, and breeding records for numerous species. It also provided insight into the biogeography of lowland endemic species in Sabah and montane endemic species in Borneo. The hypotheses formulated from these biogeographic discoveries should serve as useful frameworks for future phylogeographic work on Bornean birds. © National University of Singapore.

Published

2009

29. Molecular phylogenetics and diversification within one of the most geographically variable bird species complexes (Pachycephala pectoralis/melanura)

Author

Jønsson, Knud Andreas, Bowie, Rauri CK, Moyle, Robert G., Christidis, L., Filardi, C., Norman, J., Fjeldså, Jon, Jønsson, Knud Andreas, Bowie, Rauri CK, Moyle, Robert G., Christidis, L., Filardi, C., Norman, J., and Fjeldså, Jon

Published

2008

30. Molecular phylogenetics and diversification within one of the most geographically variable bird species complexes (Pachycephala pectoralis/melanura)

Author

Jønsson, Knud Andreas, Bowie, Rauri CK, Moyle, Robert G., Christidis, L., Filardi, C., Norman, J., Fjeldså, Jon, Jønsson, Knud Andreas, Bowie, Rauri CK, Moyle, Robert G., Christidis, L., Filardi, C., Norman, J., and Fjeldså, Jon

Published

2008