Consequences of the genetic threshold model for observing partial migration under climate change scenarios
Authored by Marleen M P Cobben, Noordwijk Arie J van
Date Published: 2017
DOI: 10.1002/ece3.3357
Sponsors:
Netherlands Organization for Scientific Research (NWO)
Platforms:
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Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
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Abstract
Migration is a widespread phenomenon across the animal kingdom as a
response to seasonality in environmental conditions. Partially migratory
populations are populations that consist of both migratory and
residential individuals. Such populations are very common, yet their
stability has long been debated. The inheritance of migratory activity
is currently best described by the threshold model of quantitative
genetics. The inclusion of such a genetic threshold model for migratory
behavior leads to a stable zone in time and space of partially migratory
populations under a wide range of demographic parameter values, when
assuming stable environmental conditions and unlimited genetic
diversity. Migratory species are expected to be particularly sensitive
to global warming, as arrival at the breeding grounds might be
increasingly mistimed as a result of the uncoupling of long-used cues
and actual environmental conditions, with decreasing reproduction as a
consequence. Here, we investigate the consequences for migratory
behavior and the stability of partially migratory populations under five
climate change scenarios and the assumption of a genetic threshold value
for migratory behavior in an individual-based model. The results show a
spatially and temporally stable zone of partially migratory populations
after different lengths of time in all scenarios. In the scenarios in
which the species expands its range from a particular set of starting
populations, the genetic diversity and location at initialization
determine the species' colonization speed across the zone of partial
migration and therefore across the entire landscape. Abruptly changing
environmental conditions after model initialization never caused a
qualitative change in phenotype distributions, or complete extinction.
This suggests that climate change-induced shifts in species' ranges as
well as changes in survival probabilities and reproductive success can
be met with flexibility in migratory behavior at the species level,
which will reduce the risk of extinction.
Tags
Individual-based model
Adaptation
Evolution
behavior
Genetic diversity
Spatially explicit
Bird population
Passerines
Selection landscape