Lost: on what level should we aim to understand animal navigation?

Wynn, Joe; Liedvogel, Miriam

doi:10.1242/jeb.245441

Cited by 2 publications

(2 citation statements)

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“…For actual migration systems, this has only been assessed for migration based on correlated random walks—per definition less directed than compass courses—with supplemental navigational abilities based on geomagnetic information [ 38 ]. While gradient-based navigation using innate or early-learned information offers the possibility to correct for imprecision or displacement [ 88 ], e.g., by currents, it could also produce inefficient migrations when gradients in field components are closely aligned [ 9 , 29 , 38 , 90 ]. Our results suggest that constant-heading migration modulated by magnetic signposts could be sufficiently robust to variable and changing geomagnetic fields, at least given suitable compass precision and intrinsic variability in inherited headings.…”

Section: Discussionmentioning

confidence: 99%

“…While global patterns of avian migration can be explained as efficient energy acquisition of seasonal resources [ 91 ], enabling hindcasts of prehistoric migration routes [ 22 , 77 ], little is understood regarding the population consequences of how migratory orientation is transmitted across generations [ 43 , 88 , 89 ]. Using an evolutionary algorithm approach enables population-level assessments of how inherited migratory orientation programs can both mediate and constrain adaptation of historic and novel migration routes.…”

Section: Discussionmentioning

confidence: 99%

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Gauge-and-compass migration: inherited magnetic headings and signposts can adapt to changing geomagnetic landscapes

2023

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Background For many migratory species, inexperienced (naïve) individuals reach remote non-breeding areas independently using one or more inherited compass headings and, potentially, magnetic signposts to gauge where to switch between compass headings. Inherited magnetic-based migration has not yet been assessed as a population-level process, particularly across strong geomagnetic gradients or where long-term geomagnetic shifts (hereafter, secular variation) could create mismatches with magnetic headings. Therefore, it remains unclear whether inherited magnetic headings and signposts could potentially adapt to secular variation under natural selection. Methods To address these unknowns, we modelled migratory orientation programs using an evolutionary algorithm incorporating global geomagnetic data (1900–2023). Modelled population mixing incorporated both natal dispersal and trans-generational inheritance of magnetic headings and signposts, including intrinsic (stochastic) variability in inheritance. Using the model, we assessed robustness of trans-hemispheric migration of a migratory songbird whose Nearctic breeding grounds have undergone rapid secular variation (mean 34° clockwise drift in declination, 1900–2023), and which travels across strong geomagnetic gradients via Europe to Africa. Results Model-evolved magnetic-signposted migration was overall successful throughout the 124-year period, with 60–90% mean successful arrival across a broad range in plausible precision in compass headings and gauging signposts. Signposted migration reduced trans-Atlantic flight distances and was up to twice as successful compared with non-signposted migration. Magnetic headings shifted plastically in response to the secular variation (mean 16°–17° among orientation programs), whereas signpost latitudes were more constrained (3°–5° mean shifts). This plasticity required intrinsic variability in inheritance (model-evolved σ ≈ 2.6° standard error), preventing clockwise secular drift from causing unsustainable open-ocean flights. Conclusions Our study supports the potential long-term viability of inherited magnetic migratory headings and signposts, and illustrates more generally how inherited migratory orientation programs can both mediate and constrain evolution of routes, in response to global environmental change.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Gauge-and-compass migration: inherited magnetic headings and signposts can adapt to changing geomagnetic landscapes

2023

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ECR Spotlight – Joe Wynn

2023

Journal of Experimental Biology

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ECR Spotlight is a series of interviews with early-career authors from a selection of papers published in Journal of Experimental Biology and aims to promote not only the diversity of early-career researchers (ECRs) working in experimental biology during our centenary year but also the huge variety of animals and physiological systems that are essential for the ‘comparative’ approach. Joe Wynn is an author on ‘ Lost: on what level should we aim to understand animal navigation?’, published in JEB. Joe conducted the research described in this article while a DPhil student in Prof. Tim Guilford's lab at the University of Oxford, UK. He is now a post-doctoral researcher in the lab of Prof. Miriam Liedvogel and Dr Sandra Bouwhuis at Institut für Vogelforschung, Germany, investigating the mechanisms of bird migration, and how these mechanisms evolve through time.

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Lost: on what level should we aim to understand animal navigation?

Cited by 2 publications

References 91 publications

Gauge-and-compass migration: inherited magnetic headings and signposts can adapt to changing geomagnetic landscapes

Gauge-and-compass migration: inherited magnetic headings and signposts can adapt to changing geomagnetic landscapes

ECR Spotlight – Joe Wynn

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