Evolution of chain migration in an aerial insectivorous bird, the common swift Apus apus

Susanne Åkesson; Phil W. Atkinson; Ana Bermejo; Javier de la Puente; Mauro Ferri; Chris M. Hewson; Jan Holmgren; Erich Kaiser; Lyndon Kearsley; Raymond H.G. Klaassen; Heikki Kolunen; Gittan Matsson; Fausto Minelli; Gabriel Norevik; Hannu Pietiäinen; Navinder J. Singh; Fernando Spina; Lukas Viktora; Anders Hedenström

doi:10.1111/evo.14093

Evolution of chain migration in an aerial insectivorous bird, the common swift Apus apus

Susanne Åkesson^*, Phil W. Atkinson, Ana Bermejo, Javier de la Puente, Mauro Ferri, Chris M. Hewson, Jan Holmgren, Erich Kaiser, Lyndon Kearsley, Raymond H.G. Klaassen, Heikki Kolunen, Gittan Matsson, Fausto Minelli, Gabriel Norevik, Hannu Pietiäinen, Navinder J. Singh, Fernando Spina, Lukas Viktora, Anders Hedenström

^*Corresponding author for this work

Both group - Global Change Ecology

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Spectacular long-distance migration has evolved repeatedly in animals enabling exploration of resources separated in time and space. In birds, these patterns are largely driven by seasonality, cost of migration, and asymmetries in competition leading most often to leapfrog migration, where northern breeding populations winter furthest to the south. Here, we show that the highly aerial common swift Apus apus, spending the nonbreeding period on the wing, instead exhibits a rarely found chain migration pattern, where the most southern breeding populations in Europe migrate to wintering areas furthest to the south in Africa, whereas the northern populations winter to the north. The swifts concentrated in three major areas in sub-Saharan Africa during the nonbreeding period, with substantial overlap of nearby breeding populations. We found that the southern breeding swifts were larger, raised more young, and arrived to the wintering areas with higher seasonal variation in greenness (Normalized Difference Vegetation Index) earlier than the northern breeding swifts. This unusual chain migration pattern in common swifts is largely driven by differential annual timing and we suggest it evolves by prior occupancy and dominance by size in the breeding quarters and by prior occupancy combined with diffuse competition in the winter.

Original language	English
Pages (from-to)	2377-2391
Number of pages	15
Journal	Evolution
Volume	74
Issue number	10
DOIs	https://doi.org/10.1111/evo.14093
Publication status	Published - 1-Oct-2020

Keywords

Annual timing
chain migration
common swift
diffuse competition
dominance by size
prior occupancy

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Evolution of chain migration in an aerial insectivorous bird, the common swift Apus apusFinal publisher's version, 1.67 MBLicence: CC BY-NC-ND

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Åkesson, S., Atkinson, P. W., Bermejo, A., de la Puente, J., Ferri, M., Hewson, C. M., Holmgren, J., Kaiser, E., Kearsley, L., Klaassen, R. H. G., Kolunen, H., Matsson, G., Minelli, F., Norevik, G., Pietiäinen, H., Singh, N. J., Spina, F., Viktora, L., & Hedenström, A. (2020). Evolution of chain migration in an aerial insectivorous bird, the common swift Apus apus. Evolution, 74(10), 2377-2391. https://doi.org/10.1111/evo.14093

@article{b79ea25f12df49da857b318261592ef5,

title = "Evolution of chain migration in an aerial insectivorous bird, the common swift Apus apus",

abstract = "Spectacular long-distance migration has evolved repeatedly in animals enabling exploration of resources separated in time and space. In birds, these patterns are largely driven by seasonality, cost of migration, and asymmetries in competition leading most often to leapfrog migration, where northern breeding populations winter furthest to the south. Here, we show that the highly aerial common swift Apus apus, spending the nonbreeding period on the wing, instead exhibits a rarely found chain migration pattern, where the most southern breeding populations in Europe migrate to wintering areas furthest to the south in Africa, whereas the northern populations winter to the north. The swifts concentrated in three major areas in sub-Saharan Africa during the nonbreeding period, with substantial overlap of nearby breeding populations. We found that the southern breeding swifts were larger, raised more young, and arrived to the wintering areas with higher seasonal variation in greenness (Normalized Difference Vegetation Index) earlier than the northern breeding swifts. This unusual chain migration pattern in common swifts is largely driven by differential annual timing and we suggest it evolves by prior occupancy and dominance by size in the breeding quarters and by prior occupancy combined with diffuse competition in the winter.",

keywords = "Annual timing, chain migration, common swift, diffuse competition, dominance by size, prior occupancy",

author = "Susanne {\AA}kesson and Atkinson, {Phil W.} and Ana Bermejo and {de la Puente}, Javier and Mauro Ferri and Hewson, {Chris M.} and Jan Holmgren and Erich Kaiser and Lyndon Kearsley and Klaassen, {Raymond H.G.} and Heikki Kolunen and Gittan Matsson and Fausto Minelli and Gabriel Norevik and Hannu Pieti{\"a}inen and Singh, {Navinder J.} and Fernando Spina and Lukas Viktora and Anders Hedenstr{\"o}m",

note = "Funding Information: We thank K. {\"A}rlebrant, R. Benassi, P. Carlsson, C. D. Buyzer, G. D. Smet, W. D. Smet, G. Kaiser, G. Rossi, S. Sirotti, G. Spanoghe, H. Verkade, M. Villani, C. Vennstr{\"o}m, and B. Wennstr{\"o}m and volunteers who assisted in catching of common swifts at the breeding locations. Numerous local collaborators helped in Spain with field work: J. C. del Moral, C. Mart{\'i}nez, B. Molina, A. Leal, E. Escudero, J. M. de la Pe{\~n}a, Q. Marcelo, F. Bustamante, M. Moreno, and E. Navarro in Madrid; H. Asti{\'a}rraga, B. Fuertes, J. Garc{\'i}a, F. de la Calzada, F. Ortega, I. Roa, N. Rodr{\'i}guez, L. A. Ramos, D. Migu{\'e}lez (GIA-Le{\'o}n), G. Molina, and J. Ortega in Le{\'o}n; J. M. Hern{\'a}ndez in Ciudad Real; R. Elosegui and J. Belzunce in Ir{\'u}n; M. Otero and {\'O}. Rivas (Numenius) in Lugo; P. Moreno, A. Pestana, P. Requena, C. Flores, F. S{\'a}nchez, and D. S{\'a}nchez (Epops ringing group) in C{\'o}rdoba; E. Casaux, F. S{\'a}nchez, {\'A}. E. Casaux, J. Llorente, and A. D{\'i}ez (Atthis ringing group) in Segovia; R. Jugl{\`a}, C. Teixidor, J. Roquet, I. Roquet, X. Rif{\`a}, B. Font, H. Rif{\`a}, A. Soler, J. M. P{\'e}rez, and J. Aymerich (GACO) in Barcelona. J. M. Hern{\'a}ndez, E. Casaux, and J. Aymerich provided information on breeding swifts in Ciudad Real, Barcelona, and Segovia. We are grateful to D. Winkler and two anonymous referees for valuable comments on the manuscript. Funding for instrumentation and fieldwork was provided by research grants to (S{\AA}) from the Trygger's Foundation (CTS 12:563) and the Swedish Research Council (621-2007-5930; 621-2010-5584; 621-2013-4361). Cost for geolocators in the United Kingdom was financed by the British Thrust for Ornithology via a grant from Action to Swifts. Geolocators used in Belgium and the Netherlands (3 + 1) were covered by LK from Belora vzw. Geolocators and fieldwork were financed by Fundaci{\'o}n Ibedrola Espa{\~n}a in Spain. The Government of the Basque Country financed the tagging with geolocators of 20 common swifts. This study received support from the Centre for Animal Movement Research (CAnMove) funded by a Linnaeus grant from the Swedish Research Council (349-2007-8690) and Lund University. This is report number 315 from Ottenby Bird Observatory. Permission to attach geolocators to common swifts in Sweden was given by Malm{\"o}-Lunds djurf{\"o}rs{\"o}ksetiska n{\"a}mnd (M112-09, M470-12). Funding Information: We thank K. {\"A}rlebrant, R. Benassi, P. Carlsson, C. D. Buyzer, G. D. Smet, W. D. Smet, G. Kaiser, G. Rossi, S. Sirotti, G. Spanoghe, H. Verkade, M. Villani, C. Vennstr{\"o}m, and B. Wennstr{\"o}m and volunteers who assisted in catching of common swifts at the breeding locations. Numerous local collaborators helped in Spain with field work: J. C. del Moral, C. Mart{\'i}nez, B. Molina, A. Leal, E. Escudero, J. M. de la Pe{\~n}a, Q. Marcelo, F. Bustamante, M. Moreno, and E. Navarro in Madrid; H. Asti{\'a}rraga, B. Fuertes, J. Garc{\'i}a, F. de la Calzada, F. Ortega, I. Roa, N. Rodr{\'i}guez, L. A. Ramos, D. Migu{\'e}lez (GIA‐Le{\'o}n), G. Molina, and J. Ortega in Le{\'o}n; J. M. Hern{\'a}ndez in Ciudad Real; R. Elosegui and J. Belzunce in Ir{\'u}n; M. Otero and {\'O}. Rivas (Numenius) in Lugo; P. Moreno, A. Pestana, P. Requena, C. Flores, F. S{\'a}nchez, and D. S{\'a}nchez (Epops ringing group) in C{\'o}rdoba; E. Casaux, F. S{\'a}nchez, {\'A}. E. Casaux, J. Llorente, and A. D{\'i}ez (Atthis ringing group) in Segovia; R. Jugl{\`a}, C. Teixidor, J. Roquet, I. Roquet, X. Rif{\`a}, B. Font, H. Rif{\`a}, A. Soler, J. M. P{\'e}rez, and J. Aymerich (GACO) in Barcelona. J. M. Hern{\'a}ndez, E. Casaux, and J. Aymerich provided information on breeding swifts in Ciudad Real, Barcelona, and Segovia. We are grateful to D. Winkler and two anonymous referees for valuable comments on the manuscript. Funding for instrumentation and fieldwork was provided by research grants to (S{\AA}) from the Trygger's Foundation (CTS 12:563) and the Swedish Research Council (621‐2007‐5930; 621‐2010‐5584; 621‐2013‐4361). Cost for geolocators in the United Kingdom was financed by the British Thrust for Ornithology via a grant from Action to Swifts. Geolocators used in Belgium and the Netherlands (3 + 1) were covered by LK from Belora vzw. Geolocators and fieldwork were financed by Fundaci{\'o}n Ibedrola Espa{\~n}a in Spain. The Government of the Basque Country financed the tagging with geolocators of 20 common swifts. This study received support from the Centre for Animal Movement Research (CAnMove) funded by a Linnaeus grant from the Swedish Research Council (349‐2007‐8690) and Lund University. This is report number 315 from Ottenby Bird Observatory. Permission to attach geolocators to common swifts in Sweden was given by Malm{\"o}‐Lunds djurf{\"o}rs{\"o}ksetiska n{\"a}mnd (M112‐09, M470‐12). Permission to trap and ring common swifts in Sweden was given by the Swedish Ringing Office (nr 440) to S{\AA}. Permission to ring and work with swifts in Italy was given by ISPRA (INSF) and Provincia di Modena (Prot. n. 18185/19.02.2015) to FM. Permissions to catch and log swifts in Finland and to ring swifts in Germany were provided by the National Ringing Offices. Permit to capture, ring, and track swifts in the Czech Republic (nr. 671) was issued by the Bird‐ringing Station of the National Museum Prague. In Belgium (Flanders), the license was issued by the Agency for Nature and Forest—number ANB/BL‐FF/VERG/11‐00316. Tagging and tracking were carried out under licenses of the Animal Experimental Committee of the KNAW ( www.knaw.nl ), The Netherlands (protocol NIOO 10.07). Work in the United Kingdom was carried out under license from the Special Marks Technical Panel of the British trust for Ornithology's ringing scheme. In Spain, the regional governments of Andalusia, Castilla y Le{\'o}n, Castilla‐La Mancha, Catalonia, Galicia, Madrid, and Gipuzkoa provided permits for ringing and attachment geolocators in the birds in their respective regions. Publisher Copyright: {\textcopyright} 2020 The Authors. Evolution {\textcopyright} 2020 The Society for the Study of Evolution.",

year = "2020",

month = oct,

day = "1",

doi = "10.1111/evo.14093",

language = "English",

volume = "74",

pages = "2377--2391",

journal = "Evolution",

issn = "0014-3820",

publisher = "Wiley",

number = "10",

}

Åkesson, S, Atkinson, PW, Bermejo, A, de la Puente, J, Ferri, M, Hewson, CM, Holmgren, J, Kaiser, E, Kearsley, L, Klaassen, RHG, Kolunen, H, Matsson, G, Minelli, F, Norevik, G, Pietiäinen, H, Singh, NJ, Spina, F, Viktora, L & Hedenström, A 2020, 'Evolution of chain migration in an aerial insectivorous bird, the common swift Apus apus', Evolution, vol. 74, no. 10, pp. 2377-2391. https://doi.org/10.1111/evo.14093

TY - JOUR

T1 - Evolution of chain migration in an aerial insectivorous bird, the common swift Apus apus

AU - Åkesson, Susanne

AU - Atkinson, Phil W.

AU - Bermejo, Ana

AU - de la Puente, Javier

AU - Ferri, Mauro

AU - Hewson, Chris M.

AU - Holmgren, Jan

AU - Kaiser, Erich

AU - Kearsley, Lyndon

AU - Klaassen, Raymond H.G.

AU - Kolunen, Heikki

AU - Matsson, Gittan

AU - Minelli, Fausto

AU - Norevik, Gabriel

AU - Pietiäinen, Hannu

AU - Singh, Navinder J.

AU - Spina, Fernando

AU - Viktora, Lukas

AU - Hedenström, Anders

N1 - Funding Information: We thank K. Ärlebrant, R. Benassi, P. Carlsson, C. D. Buyzer, G. D. Smet, W. D. Smet, G. Kaiser, G. Rossi, S. Sirotti, G. Spanoghe, H. Verkade, M. Villani, C. Vennström, and B. Wennström and volunteers who assisted in catching of common swifts at the breeding locations. Numerous local collaborators helped in Spain with field work: J. C. del Moral, C. Martínez, B. Molina, A. Leal, E. Escudero, J. M. de la Peña, Q. Marcelo, F. Bustamante, M. Moreno, and E. Navarro in Madrid; H. Astiárraga, B. Fuertes, J. García, F. de la Calzada, F. Ortega, I. Roa, N. Rodríguez, L. A. Ramos, D. Miguélez (GIA-León), G. Molina, and J. Ortega in León; J. M. Hernández in Ciudad Real; R. Elosegui and J. Belzunce in Irún; M. Otero and Ó. Rivas (Numenius) in Lugo; P. Moreno, A. Pestana, P. Requena, C. Flores, F. Sánchez, and D. Sánchez (Epops ringing group) in Córdoba; E. Casaux, F. Sánchez, Á. E. Casaux, J. Llorente, and A. Díez (Atthis ringing group) in Segovia; R. Juglà, C. Teixidor, J. Roquet, I. Roquet, X. Rifà, B. Font, H. Rifà, A. Soler, J. M. Pérez, and J. Aymerich (GACO) in Barcelona. J. M. Hernández, E. Casaux, and J. Aymerich provided information on breeding swifts in Ciudad Real, Barcelona, and Segovia. We are grateful to D. Winkler and two anonymous referees for valuable comments on the manuscript. Funding for instrumentation and fieldwork was provided by research grants to (SÅ) from the Trygger's Foundation (CTS 12:563) and the Swedish Research Council (621-2007-5930; 621-2010-5584; 621-2013-4361). Cost for geolocators in the United Kingdom was financed by the British Thrust for Ornithology via a grant from Action to Swifts. Geolocators used in Belgium and the Netherlands (3 + 1) were covered by LK from Belora vzw. Geolocators and fieldwork were financed by Fundación Ibedrola España in Spain. The Government of the Basque Country financed the tagging with geolocators of 20 common swifts. This study received support from the Centre for Animal Movement Research (CAnMove) funded by a Linnaeus grant from the Swedish Research Council (349-2007-8690) and Lund University. This is report number 315 from Ottenby Bird Observatory. Permission to attach geolocators to common swifts in Sweden was given by Malmö-Lunds djurförsöksetiska nämnd (M112-09, M470-12). Funding Information: We thank K. Ärlebrant, R. Benassi, P. Carlsson, C. D. Buyzer, G. D. Smet, W. D. Smet, G. Kaiser, G. Rossi, S. Sirotti, G. Spanoghe, H. Verkade, M. Villani, C. Vennström, and B. Wennström and volunteers who assisted in catching of common swifts at the breeding locations. Numerous local collaborators helped in Spain with field work: J. C. del Moral, C. Martínez, B. Molina, A. Leal, E. Escudero, J. M. de la Peña, Q. Marcelo, F. Bustamante, M. Moreno, and E. Navarro in Madrid; H. Astiárraga, B. Fuertes, J. García, F. de la Calzada, F. Ortega, I. Roa, N. Rodríguez, L. A. Ramos, D. Miguélez (GIA‐León), G. Molina, and J. Ortega in León; J. M. Hernández in Ciudad Real; R. Elosegui and J. Belzunce in Irún; M. Otero and Ó. Rivas (Numenius) in Lugo; P. Moreno, A. Pestana, P. Requena, C. Flores, F. Sánchez, and D. Sánchez (Epops ringing group) in Córdoba; E. Casaux, F. Sánchez, Á. E. Casaux, J. Llorente, and A. Díez (Atthis ringing group) in Segovia; R. Juglà, C. Teixidor, J. Roquet, I. Roquet, X. Rifà, B. Font, H. Rifà, A. Soler, J. M. Pérez, and J. Aymerich (GACO) in Barcelona. J. M. Hernández, E. Casaux, and J. Aymerich provided information on breeding swifts in Ciudad Real, Barcelona, and Segovia. We are grateful to D. Winkler and two anonymous referees for valuable comments on the manuscript. Funding for instrumentation and fieldwork was provided by research grants to (SÅ) from the Trygger's Foundation (CTS 12:563) and the Swedish Research Council (621‐2007‐5930; 621‐2010‐5584; 621‐2013‐4361). Cost for geolocators in the United Kingdom was financed by the British Thrust for Ornithology via a grant from Action to Swifts. Geolocators used in Belgium and the Netherlands (3 + 1) were covered by LK from Belora vzw. Geolocators and fieldwork were financed by Fundación Ibedrola España in Spain. The Government of the Basque Country financed the tagging with geolocators of 20 common swifts. This study received support from the Centre for Animal Movement Research (CAnMove) funded by a Linnaeus grant from the Swedish Research Council (349‐2007‐8690) and Lund University. This is report number 315 from Ottenby Bird Observatory. Permission to attach geolocators to common swifts in Sweden was given by Malmö‐Lunds djurförsöksetiska nämnd (M112‐09, M470‐12). Permission to trap and ring common swifts in Sweden was given by the Swedish Ringing Office (nr 440) to SÅ. Permission to ring and work with swifts in Italy was given by ISPRA (INSF) and Provincia di Modena (Prot. n. 18185/19.02.2015) to FM. Permissions to catch and log swifts in Finland and to ring swifts in Germany were provided by the National Ringing Offices. Permit to capture, ring, and track swifts in the Czech Republic (nr. 671) was issued by the Bird‐ringing Station of the National Museum Prague. In Belgium (Flanders), the license was issued by the Agency for Nature and Forest—number ANB/BL‐FF/VERG/11‐00316. Tagging and tracking were carried out under licenses of the Animal Experimental Committee of the KNAW ( www.knaw.nl ), The Netherlands (protocol NIOO 10.07). Work in the United Kingdom was carried out under license from the Special Marks Technical Panel of the British trust for Ornithology's ringing scheme. In Spain, the regional governments of Andalusia, Castilla y León, Castilla‐La Mancha, Catalonia, Galicia, Madrid, and Gipuzkoa provided permits for ringing and attachment geolocators in the birds in their respective regions. Publisher Copyright: © 2020 The Authors. Evolution © 2020 The Society for the Study of Evolution.

PY - 2020/10/1

Y1 - 2020/10/1

N2 - Spectacular long-distance migration has evolved repeatedly in animals enabling exploration of resources separated in time and space. In birds, these patterns are largely driven by seasonality, cost of migration, and asymmetries in competition leading most often to leapfrog migration, where northern breeding populations winter furthest to the south. Here, we show that the highly aerial common swift Apus apus, spending the nonbreeding period on the wing, instead exhibits a rarely found chain migration pattern, where the most southern breeding populations in Europe migrate to wintering areas furthest to the south in Africa, whereas the northern populations winter to the north. The swifts concentrated in three major areas in sub-Saharan Africa during the nonbreeding period, with substantial overlap of nearby breeding populations. We found that the southern breeding swifts were larger, raised more young, and arrived to the wintering areas with higher seasonal variation in greenness (Normalized Difference Vegetation Index) earlier than the northern breeding swifts. This unusual chain migration pattern in common swifts is largely driven by differential annual timing and we suggest it evolves by prior occupancy and dominance by size in the breeding quarters and by prior occupancy combined with diffuse competition in the winter.

AB - Spectacular long-distance migration has evolved repeatedly in animals enabling exploration of resources separated in time and space. In birds, these patterns are largely driven by seasonality, cost of migration, and asymmetries in competition leading most often to leapfrog migration, where northern breeding populations winter furthest to the south. Here, we show that the highly aerial common swift Apus apus, spending the nonbreeding period on the wing, instead exhibits a rarely found chain migration pattern, where the most southern breeding populations in Europe migrate to wintering areas furthest to the south in Africa, whereas the northern populations winter to the north. The swifts concentrated in three major areas in sub-Saharan Africa during the nonbreeding period, with substantial overlap of nearby breeding populations. We found that the southern breeding swifts were larger, raised more young, and arrived to the wintering areas with higher seasonal variation in greenness (Normalized Difference Vegetation Index) earlier than the northern breeding swifts. This unusual chain migration pattern in common swifts is largely driven by differential annual timing and we suggest it evolves by prior occupancy and dominance by size in the breeding quarters and by prior occupancy combined with diffuse competition in the winter.

KW - Annual timing

KW - chain migration

KW - common swift

KW - diffuse competition

KW - dominance by size

KW - prior occupancy

UR - http://www.scopus.com/inward/record.url?scp=85090766761&partnerID=8YFLogxK

U2 - 10.1111/evo.14093

DO - 10.1111/evo.14093

M3 - Article

C2 - 32885859

AN - SCOPUS:85090766761

SN - 0014-3820

VL - 74

SP - 2377

EP - 2391

JO - Evolution

JF - Evolution

IS - 10

ER -

Evolution of chain migration in an aerial insectivorous bird, the common swift Apus apus

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