Grappling with uncertainty in ecological projections: a case study using the migratory monarch butterfly

Neupane, Naresh; Zipkin, Elise F.; Saunders, Sarah P.; Ries, Leslie

doi:10.1002/ecs2.3874

Cited by 11 publications

(11 citation statements)

References 71 publications

(121 reference statements)

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“…As forecast lead time increases, however, so does the relative contribution of climate uncertainty, primarily due to large variations in climate projections across emissions scenarios during 2080–2100 (Hawkins & Sutton, 2009). Uncertainty in population forecasts will always increase with forecast lead time, and there are limited options for reducing climate uncertainty other than selecting a subset of available GCMs for projections based on their ability to accurately model historical values of relevant climate variables within the geographic region of interest (Neupane et al, 2022). However, parameter uncertainty can be reduced, over the near and long term, by collecting targeted data to better understand mechanistic links between breeding‐season temperatures and precipitation and local monarch abundance (Iles & Jenouvrier, 2019).…”

Section: Resultsmentioning

confidence: 99%

“…We used coupled atmosphere–ocean general circulation models (GCMs), under a range of emissions scenarios, to project spring and summer climate variables into three future periods: early (2023–2043), middle (2050–2070), and end (2080–2100) of the twenty‐first century. We used a systematic approach to select an ensemble of GCMs from a set of candidate models, with the goal of excluding models that were not well‐suited for the region of interest, while retaining a sufficient number of models to adequately characterize present and future climate conditions and uncertainty (Cavanagh et al, 2017; Harris et al, 2014; Karmalkar et al, 2019; Neupane et al, 2022). For this, we compared observed temperatures and precipitation (data from Daymet) with modeled values from 23 GCMs acquired from the sixth iteration of the Coupled Model Intercomparison Project (CMIP6; Eyring et al, 2016; Table S1) for each year in a validation period that spanned from 1980 (the first year Daymet data are available) to 2014 (the latest year hindcasts are available for GCMs from CMIP6).…”

Section: Methodsmentioning

confidence: 99%

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Multi‐season climate projections forecast declines in migratory monarch butterflies

Zylstra

Neupane

Zipkin

2022

Global Change Biology

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Multi‐season climate projections forecast declines in migratory monarch butterflies

Zylstra

Neupane

Zipkin

2022

Global Change Biology

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“…When this complexity of human impacts meets complex natural systems, where different interacting species are differently affected by environmental drivers, it becomes imperative to understand key pathways through which environmental change can alter natural communities [3–5]. Understanding these pathways allows us to define more nuanced ecological forecasting, proposing different scenarios under which populations remain viable in the future, when they go locally extinct, or when they invade new habitats [6–8].…”

Section: Demographic Determinants Of Species Responses To Environment...mentioning

confidence: 99%

“…imperative to understand key pathways through which environmental change can alter natural communities [3][4][5]. Understanding these pathways allows us to define more nuanced ecological forecasting, proposing different scenarios under which populations remain viable in the future, when they go locally extinct, or when they invade new habitats [6][7][8].…”

mentioning

confidence: 99%

Pathways to global-change effects on biodiversity: new opportunities for dynamically forecasting demography and species interactions

et al. 2023

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In structured populations, persistence under environmental change may be particularly threatened when abiotic factors simultaneously negatively affect survival and reproduction of several life cycle stages, as opposed to a single stage. Such effects can then be exacerbated when species interactions generate reciprocal feedbacks between the demographic rates of the different species. Despite the importance of such demographic feedbacks, forecasts that account for them are limited as individual-based data on interacting species are perceived to be essential for such mechanistic forecasting—but are rarely available. Here, we first review the current shortcomings in assessing demographic feedbacks in population and community dynamics. We then present an overview of advances in statistical tools that provide an opportunity to leverage population-level data on abundances of multiple species to infer stage-specific demography. Lastly, we showcase a state-of-the-art Bayesian method to infer and project stage-specific survival and reproduction for several interacting species in a Mediterranean shrub community. This case study shows that climate change threatens populations most strongly by changing the interaction effects of conspecific and heterospecific neighbours on both juvenile and adult survival. Thus, the repurposing of multi-species abundance data for mechanistic forecasting can substantially improve our understanding of emerging threats on biodiversity.

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“…High precision on estimates of covariate effects is critical for prediction, since forecast errors will magnify over time. Thus, when parameter precision is poor, forecasts will be rendered effectively useless ( [89] demonstrate this point with climate predictions). However, by increasing the amount of data available for inference via integrated modeling techniques, it is possible to improve the precision of demographic parameters and their relationships to covariates and thus alleviate some uncertainty in species' projections [3,90].…”

Section: Challenge 4: Forecastingmentioning

confidence: 99%

Integrated Population Models: Achieving Their Potential

Frost

McCrea

King

et al. 2022

J Stat Theory Pract

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Precise and accurate estimates of abundance and demographic rates are primary quantities of interest within wildlife conservation and management. Such quantities provide insight into population trends over time and the associated underlying ecological drivers of the systems. This information is fundamental in managing ecosystems, assessing species conservation status and developing and implementing effective conservation policy. Observational monitoring data are typically collected on wildlife populations using an array of different survey protocols, dependent on the primary questions of interest. For each of these survey designs, a range of advanced statistical techniques have been developed which are typically well understood. However, often multiple types of data may exist for the same population under study. Analyzing each data set separately implicitly discards the common information contained in the other data sets. An alternative approach that aims to optimize the shared information contained within multiple data sets is to use a “model-based data integration” approach, or more commonly referred to as an “integrated model.” This integrated modeling approach simultaneously analyzes all the available data within a single, and robust, statistical framework. This paper provides a statistical overview of ecological integrated models, with a focus on integrated population models (IPMs) which include abundance and demographic rates as quantities of interest. Four main challenges within this area are discussed, namely model specification, computational aspects, model assessment and forecasting. This should encourage researchers to explore further and develop new practical tools to ensure that full utility can be made of IPMs for future studies.

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Grappling with uncertainty in ecological projections: a case study using the migratory monarch butterfly

Cited by 11 publications

References 71 publications

Multi‐season climate projections forecast declines in migratory monarch butterflies

Multi‐season climate projections forecast declines in migratory monarch butterflies

Pathways to global-change effects on biodiversity: new opportunities for dynamically forecasting demography and species interactions

Integrated Population Models: Achieving Their Potential

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