Your search keyword '"Hansen, Gretchen J. A."' showing total 8 results

1. Environmental DNA storage and extraction method affects detectability for multiple aquatic invasive species

Author

García, Samantha M., primary, Chun, Chan Lan, additional, Dumke, Josh, additional, Hansen, Gretchen J. A., additional, Quebedeaux, Kathleen B., additional, Rounds, Christopher, additional, Totsch, Anna, additional, and Larson, Eric R., additional

Published

2024

2. Predicting responses to climate change using a joint species, spatially dependent physiologically guided abundance model.

Author

Custer, Christopher A., North, Joshua S., Schliep, Erin M., Verhoeven, Michael R., Hansen, Gretchen J. A., and Wagner, Tyler

Subjects

GLOBAL warming, INDEPENDENT variables, TEMPERATURE distribution, CLIMATE change, COLD-blooded animals

Abstract

Predicting the effects of warming temperatures on the abundance and distribution of organisms under future climate scenarios often requires extrapolating species–environment correlations to climatic conditions not currently experienced by a species, which can result in unrealistic predictions. For poikilotherms, incorporating species' thermal physiology to inform extrapolations under novel thermal conditions can result in more realistic predictions. Furthermore, models that incorporate species and spatial dependencies may improve predictions by capturing correlations present in ecological data that are not accounted for by predictor variables. Here, we present a joint species, spatially dependent physiologically guided abundance (jsPGA) model for predicting multispecies responses to climate warming. The jsPGA model uses a basis function approach to capture both species and spatial dependencies. We apply the jsPGA model to predict the response of eight fish species to projected climate warming in thousands of lakes in Minnesota, USA. By the end of the century, the cold‐adapted species was predicted to have high probabilities of extirpation across its current range—with 10% of lakes currently inhabited by this species having an extirpation probability >0.90. The remaining species had varying levels of predicted changes in abundance, reflecting differences in their thermal physiology. Though the model did not identify many strong species dependencies, the variation in estimated spatial dependence across species suggested that accounting for both dependencies was important for predicting the abundance of these fishes. The jsPGA model provides a new tool for predicting changes in the abundance, distribution, and extirpation probability of poikilotherms under novel thermal conditions. [ABSTRACT FROM AUTHOR]

Published

2024

3. Nine Lessons about Aquatic Invasive Species from the North Temperate Lakes Long-Term Ecological Research (NTL-LTER) Program.

Author

Zanden, M Jake Vander, Gorsky, Adrianna, Hansen, Gretchen J A, Johnson, Pieter T J, Latzka, Alexander W, Mikulyuk, Alison, Rohwer, Robin R, Spear, Michael J, and Walsh, Jake R

Subjects

NUMBERS of species, INTRODUCED species, MICROBIAL communities, FRESH water, LAKES, BIOLOGICAL invasions

Abstract

Freshwater ecosystems can serve as model systems that reveal insights into biological invasions. In this article, we summarize nine lessons about aquatic invasive species from the North Temperate Lakes Long-Term Ecological Research program and affiliated projects. The lessons about aquatic invasive species are as follows: Invasive species are more widespread than has been documented; they are usually at low abundance; they can irrupt from low-density populations in response to environmental triggers; they can occasionally have enormous and far-reaching impacts; they can affect microbial communities; reservoirs act as invasive species hotspots; ecosystem vulnerability to invasion can be estimated; invasive species removal can produce long-term benefits; and the impacts of invasive species control may be greater than the impacts of the invasive species. This synthesis highlights how long-term research on a freshwater landscape can advance our understanding of invasions. [ABSTRACT FROM AUTHOR]

Published

2024

4. Improving species distribution forecasts by measuring and communicating uncertainty: An invasive species case study

Author

Thomas, Shyam M., primary, Verhoeven, Michael R., additional, Walsh, Jake R., additional, Larkin, Daniel J., additional, and Hansen, Gretchen J. A., additional

Published

2024

5. Accounting for spatiotemporal sampling variation in joint species distribution models.

Author

North, Joshua S., Schliep, Erin M., Hansen, Gretchen J. A., Kundel, Holly, Custer, Christopher A., McLaughlin, Paul, and Wagner, Tyler

Subjects

SPECIES distribution, FRESHWATER biodiversity, INFERENCE (Logic), FRESHWATER fishes, FUNCTION spaces, WATER temperature

Abstract

Estimating relative abundance is critical for informing conservation and management efforts and for making inferences about the effects of environmental change on populations. Freshwater fisheries span large geographic regions, occupy diverse habitats and consist of varying species assemblages. Monitoring schemes used to sample these diverse populations often result in populations being sampled at different times and under different environmental conditions. Varying sampling conditions can bias estimates of abundance when compared across time, location and species, and properly accounting for these biases is critical for making inferences.We develop a joint species distribution model (JSDM) that accounts for varying sampling conditions due to the environment and time of sampling when estimating relative abundance. The novelty of our JSDM is that we explicitly model sampling effort as the product of known quantities based on time and gear type and an unknown functional relationship to capture seasonal variation in species life history.We use the model to study relative abundance of six freshwater fish species across the state of Minnesota, USA. Our model enables estimates of relative abundance to be compared both within and across species and lakes, and captures the inconsistent sampling present in the data. We discuss how gear type, water temperature and day of the year impact catchability for each species at the lake level and throughout a year. We compare our estimates of relative abundance to those obtained from a model that assumes constant catchability to highlight important differences within and across lakes and species.Synthesis and applications: Our method illustrates that assumptions relating indices of abundance to observed catch data can greatly impact model inferences derived from JSDMs. Specifically, not accounting for varying sampling conditions can bias inference of relative abundance, restricting our ability to detect responses to management interventions and environmental change. While our focus is on freshwater fisheries, this model architecture can be adopted to other systems where catchability may vary as a function of space, time and species. [ABSTRACT FROM AUTHOR]

Published

2024

6. Novel thermal habitat in lakes

Author

Hansen, Gretchen J. A.

Abstract

Lakes are warming globally at variable rates with important consequences for species survival. Now, research quantifies change in thermal habitat of lakes around the world and shows that season or depth restrictions on species responses may increase thermal habitat change threefold.

Published

2024

7. Aquatic invasive species exhibit contrasting seasonal detectability patterns based on environmental DNA: Implications for monitoring.

Author

Rounds, Christopher I., Arnold, Todd W., Chun, Chan Lan, Dumke, Josh, Totsch, Anna, Keppers, Adelle, Edblad, Katarina, García, Samantha M., Larson, Eric R., Nelson, Jenna K. R., and Hansen, Gretchen J. A.

Subjects

*LIFE history theory, *ZEBRA mussel, *CARP, *POLYMERASE chain reaction, *SPRING, *CRAYFISH

Abstract

Aquatic invasive species (AIS) are a global threat to freshwater biodiversity and ecosystem services. Documenting AIS prevalence at broad spatial scales is critical to effective management and early detection. However, conventional monitoring for AIS is costly and is rarely applied at the resolution and scale required for effective management. Monitoring of AIS using environmental DNA (eDNA) has the potential to enable broadscale surveillance at a fraction of the cost of conventional methods, but key questions must first be addressed related to how eDNA detection probability varies among environments, seasons, and multiple species with different life histories. To quantify spatiotemporal variation in the detection probability of AIS using eDNA sampling, we surveyed 20 lakes with known populations of four aquatic invasive species: common carp (Cyprinus carpio), rusty crayfish (Faxonius rusticus), spiny waterflea (Bythotrephes longimanus), and zebra mussels (Dreissena polymorpha). We collected water samples at 10 locations per lake, five times throughout the open water season resulting in a total of 1,000 water samples. Quantitative polymerase chain reaction was used with species‐specific assays to determine the presence of each species' eDNA in water samples. With Bayesian occupancy models, we quantified the effects of lake and site characteristics and Julian date on eDNA detection probability. The probability of eDNA detection varied seasonally, and the seasonal variation was species‐specific and related to species life histories. Zebra mussel eDNA was generally the most detectable among the species we targeted, and detection probability peaked in midsummer when only six water samples were required to achieve a 95% probability of detection (80% Bayesian credible interval: 3–12 samples). Spiny waterflea eDNA detections also peaked in mid to late summer, but were overall the most difficult species to detect, requiring 160 samples for a 95% probability of detection (80% Bayesian credible interval: 67–1,616 samples). Common carp eDNA was most detectable in the spring and rusty crayfish eDNA was most detectable in the early autumn, corresponding to key life history events. Sampling for eDNA during the optimal time of the year for each species decreased the number of samples required to reach a 95% probability of detection by an order of magnitude or more. Our results are relevant for decision makers interested in using eDNA as a multi‐species monitoring tool and highlight the importance of life history in the efficacy of eDNA monitoring. [ABSTRACT FROM AUTHOR]

Published

2024

8. Nine Lessons about Aquatic Invasive Species from the North Temperate Lakes Long-Term Ecological Research (NTL-LTER) Program.

Author

Vander Zanden MJ, Gorsky A, Hansen GJA, Johnson PTJ, Latzka AW, Mikulyuk A, Rohwer RR, Spear MJ, and Walsh JR

Abstract

Freshwater ecosystems can serve as model systems that reveal insights into biological invasions. In this article, we summarize nine lessons about aquatic invasive species from the North Temperate Lakes Long-Term Ecological Research program and affiliated projects. The lessons about aquatic invasive species are as follows: Invasive species are more widespread than has been documented; they are usually at low abundance; they can irrupt from low-density populations in response to environmental triggers; they can occasionally have enormous and far-reaching impacts; they can affect microbial communities; reservoirs act as invasive species hotspots; ecosystem vulnerability to invasion can be estimated; invasive species removal can produce long-term benefits; and the impacts of invasive species control may be greater than the impacts of the invasive species. This synthesis highlights how long-term research on a freshwater landscape can advance our understanding of invasions., (© The Author(s) 2024. Published by Oxford University Press on behalf of the American Institute of Biological Sciences.)

Published

2024