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13 results on '"Jason C. Leppi"'

1. Broad Whitefish (Coregonus nasus) isotopic niches: Stable isotopes reveal diverse foraging strategies and habitat use in Arctic Alaska

Author

Jason C. Leppi, Daniel J. Rinella, Mark S. Wipfli, and Matthew S. Whitman

Subjects
Medicine, Science
Abstract

Understanding the ecological niche of some fishes is complicated by their frequent use of a broad range of food resources and habitats across space and time. Little is known about Broad Whitefish (Coregonus nasus) ecological niches in Arctic landscapes even though they are an important subsistence species for Alaska’s Indigenous communities. We investigated the foraging ecology and habitat use of Broad Whitefish via stable isotope analyses of muscle and liver tissue and otoliths from mature fish migrating in the Colville River within Arctic Alaska. The range of δ13C (-31.8– -21.9‰) and δ15N (6.6–13.1‰) across tissue types and among individuals overlapped with isotope values previously observed in Arctic lakes and rivers, estuaries, and nearshore marine habitat. The large range of δ18O (4.5–10.9‰) and δD (-237.6– -158.9‰) suggests fish utilized a broad spectrum of habitats across elevational and latitudinal gradients. Cluster analysis of muscle δ13Cˈ, δ15N, δ18O, and δD indicated that Broad Whitefish occupied four different foraging niches that relied on marine and land-based (i.e., freshwater and terrestrial) food sources to varying degrees. Most individuals had isotopic signatures representative of coastal freshwater habitat (Group 3; 25%) or coastal lagoon and delta habitat (Group 1; 57%), while individuals that mainly utilized inland freshwater (Group 4; 4%) and nearshore marine habitats (Group 2; 14%) represented smaller proportions. Otolith microchemistry confirmed that individuals with more enriched muscle tissue δ13Cˈ, δD, and δ18O tended to use marine habitats, while individuals that mainly used freshwater habitats had values that were less enriched. The isotopic niches identified here represent important foraging habitats utilized by Broad Whitefish. To preserve access to these diverse habitats it will be important to limit barriers along nearshore areas and reduce impacts like roads and climate change on natural flow regimes. Maintaining these diverse connected habitats will facilitate long-term population stability, buffering populations from future environmental and anthropogenic perturbations.

Published
2022

2. Strontium isotopes reveal diverse life history variations, migration patterns, and habitat use for Broad Whitefish (Coregonus nasus) in Arctic, Alaska

Author

Jason C. Leppi, Daniel J. Rinella, Mark S. Wipfli, Randy J. Brown, Karen J. Spaleta, and Matthew S. Whitman

Subjects
Medicine, Science
Abstract

Conservation of Arctic fish species is challenging partly due to our limited ability to track fish through time and space, which constrains our understanding of life history diversity and lifelong habitat use. Broad Whitefish (Coregonus nasus) is an important subsistence species for Alaska’s Arctic Indigenous communities, yet little is known about life history diversity, migration patterns, and freshwater habitat use. Using laser ablation Sr isotope otolith microchemistry, we analyzed Colville River Broad Whitefish 87Sr/86Sr chronologies (n = 61) to reconstruct movements and habitat use across the lives of individual fish. We found evidence of at least six life history types, including three anadromous types, one semi-anadromous type, and two nonanadromous types. Anadromous life history types comprised a large proportion of individuals sampled (collectively, 59%) and most of these (59%) migrated to sea between ages 0–2 and spent varying durations at sea. The semi-anadromous life history type comprised 28% of samples and entered marine habitat as larvae. Nonanadromous life history types comprised the remainder (collectively, 13%). Otolith 87Sr/86Sr data from juvenile and adult freshwater stages suggest that habitat use changed in association with age, seasons, and life history strategies. This information on Broad Whitefish life histories and habitat use across time and space will help managers and conservation planners better understand the risks of anthropogenic impacts and help conserve this vital subsistence resource.

Published
2022

4. Strontium isotopes reveal diverse life history variations, migration patterns, and habitat use for Broad Whitefish (Coregonus nasus) in Arctic, Alaska

Author

Matthew S. Whitman, Karen J. Spaleta, Randy J. Brown, Mark S. Wipfli, Daniel J. Rinella, and Jason C. Leppi

Subjects
Fish migration, Multidisciplinary, biology, Ecology, Marine habitats, Broad whitefish, biology.organism_classification, Life history theory, Strontium Isotopes, Geography, medicine.anatomical_structure, Arctic, Habitat, medicine, Animals, Coregonus, Life History Traits, Alaska, Ecosystem, Salmonidae, Otolith
Abstract

Conservation of Arctic fish species is challenging partly due to our limited ability to track fish through time and space, which constrains our understanding of life history diversity and lifelong habitat use. Broad Whitefish (Coregonus nasus) is an important subsistence species for Alaska’s Arctic Indigenous communities, yet little is known about life history diversity, migration patterns, and freshwater habitat use. Using laser ablation Sr isotope otolith microchemistry, we analyzed Colville River Broad Whitefish 87Sr/86Sr chronologies (n = 61) to reconstruct movements and habitat use across the lives of individual fish. We found evidence of at least six life history types, including three anadromous types, one semi-anadromous type, and two nonanadromous types. Anadromous life history types comprised a large proportion of individuals sampled (collectively, 59%) and most of these (59%) migrated to sea between ages 0–2 and spent varying durations at sea. The semi-anadromous life history type comprised 28% of samples and entered marine habitat as larvae. Nonanadromous life history types comprised the remainder (collectively, 13%). Otolith 87Sr/86Sr data from juvenile and adult freshwater stages suggest that habitat use changed in association with age, seasons, and life history strategies. This information on Broad Whitefish life histories and habitat use across time and space will help managers and conservation planners better understand the risks of anthropogenic impacts and help conserve this vital subsistence resource.

Published
2022

5. Observations and first reports of saprolegniosis in Aanaakłiq, broad whitefish (Coregonus nasus), from the Colville River near Nuiqsut, Alaska

Author

Raphaela Stimmelmayr, Maureen K. Purcell, Todd Sformo, Jason C. Leppi, Jayde A. Ferguson, Joseph H. Welch, John C. George, Leah M. Ellis, Billy Adams, and John C. Seigle

Subjects
0301 basic medicine, Ecology, biology, Fishing, Water mold, Subsistence agriculture, Broad whitefish, 030108 mycology & parasitology, Aquatic Science, biology.organism_classification, Inupiaq, language.human_language, Fishery, 03 medical and health sciences, Saprolegniosis, language, General Earth and Planetary Sciences, Coregonus, Ecology, Evolution, Behavior and Systematics, Molecular identification
Abstract

We report the first confirmed cases (2013–2016) of saprolegniosis caused by water mold from the genus Saprolegnia in Aanaakliq, broad whitefish ( Coregonus nasus ), from the Colville River near Nuiqsut, Alaska. While this mold is known to be worldwide, these instances represent the first cases in Nuiqsut and only the second instance on a single fish on the North Slope, occurring in 1980. We describe the collaborative work on monitoring this emerging disease. Because fish constitute a critical component of the diet in Nuiqsut and fishing is an integral part of Inupiaq nutritional and cultural subsistence activities overall, individual subsistence fishers, local governmental entities, and Alaska Native organizations representing Nuiqsut requested an examination of affected fish and information on possible drivers of this emerging disease. The collaborative work described here ranges from recording fishermen observations, acquiring fish and mold specimens, histopathology, and molecular identification of the mold. This work, not currently grant-funded, begins with Native observation that incorporates western scientific methods and involves local, state, and federal departments as well as for-profit and non-profit organizations. Additionally, we report the more recent (2016) observation of this disease in a second species of whitefish, Pikuktuuq, humpback whitefish ( Coregonus pidschain ).

Published
2017

6. In Search of Arctic Bonefish

Author

Dan Rinella, Jason C. Leppi, Michael J. Lunde, and Mark S. Wipfli

Subjects
Fishery, Bonefish, Arctic, biology, Environmental science, %22">Fish , Aquatic Science, biology.organism_classification, Nature and Landscape Conservation
Abstract

Fisheries technician Mike Lunde prepares to check a floating gill net on the middle Colville River. Photo credit: Jason C. Leppi.In the cold waters of Alaska's Arctic swims a mysterious fish with l...

Published
2017

7. Wild, connected, and diverse: building a more resilient system of protected areas

Author

Clinton N. Jenkins, Jason C. Leppi, G. Hugh Irwin, Peter S. McKinley, Matthew S. Dietz, Gregory H. Aplet, R. Travis Belote, and Timothy J. Fullman

Subjects
0106 biological sciences, Conservation of Natural Resources, Geospatial analysis, 010504 meteorology & atmospheric sciences, Climate Change, Biodiversity, Geographic Mapping, Climate change, computer.software_genre, 010603 evolutionary biology, 01 natural sciences, Ecosystem, Ecosystem diversity, 0105 earth and related environmental sciences, Ecology, business.industry, Environmental resource management, Biota, United States, Geography, Habitat, Protected area, business, computer
Abstract

Current systems of conservation reserves may be insufficient to sustain biodiversity in the face of climate change and habitat losses. Consequently, calls have been made to protect Earth's remaining wildlands and complete the system of protected areas by establishing conservation reserves that (1) better represent ecosystems, (2) increase connectivity to facilitate biota movement in response to stressors including climate change, and (3) promote species persistence within intact landscapes. Using geospatial data, we conducted an assessment for expanding protected areas within the contiguous United States to include the least human-modified wildlands, establish a connected network, and better represent ecosystem diversity and hotspots of biodiversity. Our composite map highlights areas of high value to achieve these goals in the western United States, where existing protected areas and lands with high ecological integrity are concentrated. We also identified important areas in the East rich in species and containing ecosystems that are poorly represented in the existing protected area system. Expanding protection to these priority areas is ultimately expected to create a more resilient system for protecting the nation's biological heritage. This expectation should be subject to rigorous testing prior to implementation, and regional monitoring will ensure areas and actions are adjusted over time.

Published
2017

8. Summer temperature regimes in southcentral Alaska streams: watershed drivers of variation and potential implications for Pacific salmon

Author

Jason C. Leppi, Sue Mauger, Rebecca Shaftel, and Daniel J. Rinella

Subjects
Watershed, 010504 meteorology & atmospheric sciences, Ecology, 0208 environmental biotechnology, 02 engineering and technology, STREAMS, Aquatic Science, 01 natural sciences, 020801 environmental engineering, Variation (linguistics), Environmental science, Physical geography, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences
Abstract

Climate is changing fastest in high-latitude regions, focusing our research on understanding rates and drivers of changing temperature regimes in southcentral Alaska streams and implications for salmon populations. We collected continuous water and air temperature data during open-water periods from 2008 to 2012 in 48 nonglacial salmon streams across the Cook Inlet basin spanning a range of watershed characteristics. The most important predictors of maximum temperatures, expressed as mean July temperature, maximum weekly average temperature, and maximum weekly maximum temperature (MWMT), were mean elevation and wetland cover, while thermal sensitivity (slope of the stream–air temperature relationship) was best explained by mean elevation and area. Although maximum stream temperatures varied widely between years and across sites (8.4 to 23.7 °C), MWMT at most sites exceeded established criterion for spawning and incubation (13 °C), above which chronic and sublethal effects become likely, every year of the study, which suggests salmon are already experiencing thermal stress. Projections of MWMT over the next ∼50 years suggest these criteria will be exceeded at more sites and by increasing margins.

Published
2017

9. Mapping Conservation Strategies under a Changing Climate

Author

Carlos Carroll, R. Travis Belote, Jason C. Leppi, Gregory H. Aplet, Matthew S. Dietz, Peter S. McKinley, Timothy J. Fullman, Dean L. Urban, Anne A. Carlson, and Clinton N. Jenkins

Subjects
0106 biological sciences, Geography, Viewpoint, 010504 meteorology & atmospheric sciences, MEDLINE, General Agricultural and Biological Sciences, 010603 evolutionary biology, 01 natural sciences, Data science, 0105 earth and related environmental sciences
Published
2017

10. Impacts of climate change on August stream discharge in the Central-Rocky Mountains

Author

Jason C. Leppi, Thomas H. DeLuca, Steven W. Running, and Solomon W. Harrar

Subjects
Hydrology, Atmospheric Science, Global and Planetary Change, Discharge, Snowmelt, Streamflow, Climate change, Environmental science, STREAMS, Vegetation, Arid, Pacific decadal oscillation
Abstract

In the snowmelt dominated hydrology of arid western US landscapes, late summer low streamflow is the most vulnerable period for aquatic ecosystem habitats and trout populations. This study analyzes mean August discharge at 153 streams throughout the Central Rocky Mountains of North America (CRMs) for changes in discharge from 1950–2008. The purpose of this study was to determine if: (1) Mean August stream discharge values have decreased over the last half-century; (2) Low discharge values are occurring more frequently; (3) Climatic variables are influencing August discharge trends. Here we use a strict selection process to characterize gauging stations based on amount of anthropogenic impact in order to identify heavily impacted rivers and understand the relationship between climatic variables and discharge trends. Using historic United States Geologic Survey discharge data, we analyzed data for trends of 40–59 years. Combining of these records along with aerial photos and water rights records we selected gauging stations based on the length and continuity of discharge records and categorized each based on the amount of diversion. Variables that could potentially influence discharge such as change in vegetation and Pacific Decadal Oscillation (PDO) were examined, but we found that that both did not significantly influence August discharge patterns. Our analyses indicate that non-regulated watersheds are experiencing substantial declines in stream discharge and we have found that 89% of all non-regulated stations exhibit a declining slope. Additionally our results here indicate a significant (α ≤ 0.10) decline in discharge from 1951–2008 for the CRMs. Correlations results at our pristine sites show a negative relationship between air temperatures and discharge and these results coupled with increasing air temperature trends pose serious concern for aquatic ecosystems in CRMs.

Published
2011

11. Linking climate change projections for an Alaskan watershed to future coho salmon production

Author

Wendy M. Loya, Ryan R. Wilson, Jason C. Leppi, and Daniel J. Rinella

Subjects
Male, Watershed, Climate Change, Population, Fisheries, Climate change, Models, Biological, Hydrology (agriculture), Rivers, Water Movements, Environmental Chemistry, Animals, Precipitation, education, General Environmental Science, Hydrology, Global and Planetary Change, education.field_of_study, Ecology, biology, Reproduction, Temperature, Oncorhynchus kisutch, biology.organism_classification, Fishery, Habitat, Population model, Oncorhynchus, Environmental science, Female, Seasons, Alaska
Abstract

Climate change is predicted to dramatically change hydrologic processes across Alaska, but estimates of how these impacts will influence specific watersheds and aquatic species are lacking. Here, we linked climate, hydrology, and habitat models within a coho salmon (Oncorhynchus kisutch) population model to assess how projected climate change could affect survival at each freshwater life stage and, in turn, production of coho salmon smolts in three subwatersheds of the Chuitna (Chuit) River watershed, Alaska. Based on future climate scenarios and projections from a three-dimensional hydrology model, we simulated coho smolt production over a 20-year span at the end of the century (2080-2100). The direction (i.e., positive vs. negative) and magnitude of changes in smolt production varied substantially by climate scenario and subwatershed. Projected smolt production decreased in all three subwatersheds under the minimum air temperature and maximum precipitation scenario due to elevated peak flows and a resulting 98% reduction in egg-to-fry survival. In contrast, the maximum air temperature and minimum precipitation scenario led to an increase in smolt production in all three subwatersheds through an increase in fry survival. Other climate change scenarios led to mixed responses, with projected smolt production increasing and decreasing in different subwatersheds. Our analysis highlights the complexity inherent in predicting climate-change-related impacts to salmon populations and demonstrates that population effects may depend on interactions between the relative magnitude of hydrologic and thermal changes and their interactions with features of the local habitat.

Published
2013

12. Predicting Late Winter Dissolved Oxygen Levels in Arctic Lakes Using Morphology and Landscape Metrics

Author

Jason C. Leppi, Christopher D. Arp, and Matthew S. Whitman

Subjects
North Slope, Conservation of Natural Resources, Arctic lakes, 0208 environmental biotechnology, Forest management, 02 engineering and technology, Article, Dissolved oxygen, Littoral zone, Animals, Ecosystem, Ice Cover, 14. Life underwater, Overwintering fish habitat, Overwintering, Global and Planetary Change, biology, Ecology, Arctic Regions, Fishes, 15. Life on land, biology.organism_classification, Snow, Pollution, 6. Clean water, 020801 environmental engineering, Oxygen, Lakes, Habitat, Arctic, 13. Climate action, National Petroleum Reserve-Alaska, Freshwater fish, Environmental science, Physical geography, Seasons, Alaska
Abstract

Overwintering habitat for Arctic freshwater fish is essential, such that understanding the distribution of winter habitat quality at the landscape-scale is warranted. Adequate dissolved oxygen (DO) is a major factor limiting habitat quality in the Arctic region where ice cover can persist for 8 months each year. Here we use a mixed-effect model developed from 20 lakes across northern Alaska to assess which morphology and landscape attributes can be used to predict regional overwintering habitat quality. Across all lakes, we found that the majority of the variations in late winter DO can be explained by lake depth and littoral area. In shallow lakes (

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