Modelling the progression of bird migration with conditional autoregressive models applied to ringing data.

Roberto Ambrosini,Robert A Robinson,Wolfgang Fiedler,Riccardo Borgoni,Nicola Saino,Stephen R Baillie,Franz Bairlein,Fernando Spina,Diego Rubolini,Beatrice Sicurella,Jacquie A Clark

doi:10.1371/journal.pone.0102440

Abstract

Migration is a fundamental stage in the life history of several taxa, including birds, and is under strong selective pressure. At present, the only data that may allow for both an assessment of patterns of bird migration and for retrospective analyses of changes in migration timing are the databases of ring recoveries. We used ring recoveries of the Barn Swallow Hirundo rustica collected from 1908–2008 in Europe to model the calendar date at which a given proportion of birds is expected to have reached a given geographical area (‘progression of migration’) and to investigate the change in timing of migration over the same areas between three time periods (1908–1969, 1970–1990, 1991–2008). The analyses were conducted using binomial conditional autoregressive (CAR) mixed models. We first concentrated on data from the British Isles and then expanded the models to western Europe and north Africa. We produced maps of the progression of migration that disclosed local patterns of migration consistent with those obtained from the analyses of the movements of ringed individuals. Timing of migration estimated from our model is consistent with data on migration phenology of the Barn Swallow available in the literature, but in some cases it is later than that estimated by data collected at ringing stations, which, however, may not be representative of migration phenology over large geographical areas. The comparison of median migration date estimated over the same geographical area among time periods showed no significant advancement of spring migration over the whole of Europe, but a significant advancement of autumn migration in southern Europe. Our modelling approach can be generalized to any records of ringing date and locality of individuals including those which have not been recovered subsequently, as well as to geo-referenced databases of sightings of migratory individuals.

Highlights

Migration is widespread in nature and several taxa, from insects to fishes, amphibians, birds and mammals, undertake annual ‘‘incredible journeys’’ that represent key stages in their yearly cycle [1,2,3]
The datasets used to model migration in the British Isles consist of 1983 ring recoveries during spring migration (March-June) and 8429 ring recoveries during autumn migration (August-October), while those used for Western Europe and North Africa consist of 11918 ring recoveries collected during spring migration (February-June) and 28832 during autumn migration (August-November)
Temporal variation in migration phenology We investigated whether median migration dates varied over time and whether changes in the timing of migration differed among geographical areas [31]

Summary

Introduction

Migration is widespread in nature and several taxa, from insects to fishes, amphibians, birds and mammals, undertake annual ‘‘incredible journeys’’ that represent key stages in their yearly cycle [1,2,3]. Birds are the taxon where migratoriness is most widespread, and on which the majority of migration studies have focused [2]. As a fundamental feature in the life-history of birds, migration is under strong selective pressures [1]. A large amount of genetic variability in migratoriness, timing of migration, and migration strategies exists in bird populations. Individuals show a high degree of phenotypic plasticity in migration strategy [4]. Genetic variability and phenotypic plasticity allow birds to adjust their migration strategies according to changes in climate and ecological conditions. Changes in the timing (phenology) of migration are considered signals of the impact of current climate changes on the biosphere [5,6,7]

Methods

Results

Conclusion