Linking environmental variability to long‐term demographic change of an endangered species using integrated population models

Understanding how species populations change with environmental conditions is important for implementing effective habitat management and conservation strategies. Challenges to evaluating population‐level responses to environmental conditions arise when data are sparse or not spatiotemporally aligne...

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Bibliographic Details
Published in:The Journal of applied ecology Vol. 62; no. 5; pp. 1137 - 1151
Main Authors: Martinez, Marisa T., D'Acunto, Laura E., Romañach, Stephanie S.
Format: Journal Article
Language:English
Published: Oxford Blackwell Publishing Ltd 01.05.2025
Subjects:
adults
Ammospiza maritima mirabilis
applied ecology
Bayesian
Bayesian analysis
Bayesian theory
Breeding seasons
Cape Sable seaside sparrow
Demographics
Demography
ecosystems
Endangered & extinct species
Endangered species
Environmental changes
Environmental conditions
Environmental factors
Fecundity
Fires
Florida
Growth rate
habitat conservation
hydrology
integrated population model
juveniles
Mathematical models
Passeriformes
Population decline
Population dynamics
Population growth
Population studies
Predation
Shallow water
species
Subpopulations
Survival
Variability
Water depth
wetland management
Florida
ISSN:0021-8901, 1365-2664
Online Access:Get full text
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Summary:Understanding how species populations change with environmental conditions is important for implementing effective habitat management and conservation strategies. Challenges to evaluating population‐level responses to environmental conditions arise when data are sparse or not spatiotemporally aligned, especially for at‐risk species with small, declining numbers. We synthesized 30 years (1992–2021) of three partially aligned data sets to build a Bayesian integrated population model (IPM) and evaluate demographic and environmental drivers of growth rates for six separately managed ‘subpopulations’ (A–F) of the federally endangered Cape Sable seaside sparrow endemic to the Florida Everglades. We found that juvenile survival peaked at inundation periods (hydroperiods) around 100–220 days and dropped sharply outside those values, while adult survival increased with longer periods of water depth <20 cm, but not with longer periods of water depth >20 cm. Fecundity increased when water depths were more stable, more area was dry, intervals between fires were longer and less area was burned. Changes in population growth rates tended to occur in years that juvenile and adult survival were associated with hydroperiod, especially in the two largest subpopulations B and E. Population growth rates were also associated with hydrologic conditions during the breeding season and fire dynamics through changes in fecundity, most notably in the smaller subpopulations A, C/F and D. Synthesis and applications. Our IPM represents the first long‐term population analysis of the Cape Sable seaside sparrow connecting demographic processes to environmental factors. Our results suggest that sustaining periods of shallow water year‐round may enhance Cape Sable seaside sparrow survival and population growth. Also, limiting water depth variability and maintaining dry conditions during the breeding season and inhibiting fires in consecutive years may increase fecundity and population growth. Identifying the mechanistic links between environmental and population dynamics could inform how species are expected to respond to management decisions and anticipated ecosystem changes. Our integrated population model represents the first long‐term population analysis of the Cape Sable seaside sparrow connecting demographic processes to environmental factors. Our results suggest that sustaining periods of shallow water year‐round may enhance Cape Sable seaside sparrow survival and population growth. Also, limiting water depth variability and maintaining dry conditions during the breeding season and inhibiting fires in consecutive years may increase fecundity and population growth. Identifying the mechanistic links between environmental and population dynamics could inform how species are expected to respond to management decisions and anticipated ecosystem changes.
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ISSN:0021-8901
1365-2664
DOI:10.1111/1365-2664.70038