Your search keyword '"Fachon, Evangeline"' showing total 11 results

1. Species-specific responses of macrophyte production to the increasing CO2 environment with potential ecosystem implications involved in the Baltic Sea

Author

Pajusalu, Liina, Albert, Gerli, Fachon, Evangeline, Hepburn, Christopher D., Kotta, Jonne, Kõivupuu, Anneliis, Paalme, Tiina, Pritchard, Daniel W., Põllumäe, Arno, Torn, Kaire, and Martin, Georg

Published

2024

2. HARMFUL ALGAL BLOOMS IN THE ALASKAN ARCTIC : AN EMERGING THREAT AS THE OCEAN WARMS

Author

Anderson, Donald M., Fachon, Evangeline, Hubbard, Katherine, Lefebvre, Kathi A., Lin, Peigen, Pickart, Robert, Richlen, Mindy, Sheffield, Gay, and Van Hemert, Caroline

Published

2022

3. Gambierdiscus species diversity and community structure in St. Thomas, USVI and the Florida Keys, USA

Author

Richlen, Mindy L., Horn, Kali, Uva, Victoria, Fachon, Evangeline, Heidmann, Sarah L., Smith, Tyler B., Parsons, Michael L., and Anderson, Donald M.

Published

2024

4. Evidence for massive and recurrent toxic blooms of Alexandrium catenella in the Alaskan Arctic

Author

Anderson, Donald M., Fachon, Evangeline, Pickart, Robert S., Lin, Peigen, Fischer, Alexis D., Richlen, Mindy L., Uva, Victoria, Brosnahan, Michael L., McRaven, Leah, Bahr, Frank, Lefebvre, Kathi, Grebmeier, Jacqueline M., Danielson, Seth L., Lyu, Yihua, and Fukai, Yuri

Published

2021

5. Ocean acidification may threaten a unique seaweed community and associated industry in the Baltic Sea

Author

Pajusalu, Liina, Albert, Gerli, Fachon, Evangeline, Hepburn, Christopher D., Kotta, Jonne, Liversage, Kiran, Paalme, Tiina, Peterson, Anneliis, Pritchard, Daniel W., Põllumäe, Arno, Torn, Kaire, and Martin, Georg

Published

2020

6. Species-specific responses of macrophyte production to the increasing CO2 environment with potential ecosystem implications involved in the Baltic Sea.

Author

Pajusalu, Liina, Albert, Gerli, Fachon, Evangeline, Hepburn, Christopher D., Kotta, Jonne, Kõivupuu, Anneliis, Paalme, Tiina, Pritchard, Daniel W., Põllumäe, Arno, Torn, Kaire, and Martin, Georg

Abstract

Macrophytes vary in their ability to utilize carbon in the form of HCO3− and/or CO2 for photosynthesis. Some functional groups that solely use CO2 for photosynthesis could receive competitive advantages from the predicted increase in CO2 compared to groups with efficient carbon acquisition strategies of HCO3−. The aim of this study was to identify carbon use strategies in the common macrophytes (macroalgae, charophytes, seagrass, and other angiosperms) that represent a broad range of functional traits to CO2 concentrations in the northeastern Baltic Sea. Mechanistic assessment of the carbon physiology of macrophytes was used to predict productivity and competitive interactions between different functional groups under future climate. Carbon use strategies in macrophytes were determined by analysing the carbon isotopes (δ13C), pH drift experiments, and photosynthesis versus dissolved inorganic carbon. In addition, habitat mapping data was used to interpret the potential implications of the elevated CO2 to this coastal ecosystem. The results suggested that the primary productivity of macrophytes is often limited by carbon availability, and the increasing CO2 concentrations in the brackish Baltic Sea are expected to enhance photosynthetic production. While all species tested showed evidence of carbon concentrating mechanisms (CCMs), differential levels of CCM activity indicate varying levels of competitive fitness in a future high-CO2 environment. Overall, macrophytes which inhabit the shallowest and deepest parts of the vegetated zone are expected to experience physiological benefits under future CO2 conditions, while intermediate communities dominated by the perennial brown alga Fucus vesiculosus may experience loss of fitness. These fitness differences have implications for competitive interaction and species range under future climate. [ABSTRACT FROM AUTHOR]

Published

2024

7. Optimizing marine macrophyte capacity to locally ameliorate ocean acidification under variable light and flow regimes: Insights from an experimental approach.

Author

Ricart, Aurora M., Honisch, Brittney, Fachon, Evangeline, Hunt, Christopher W., Salisbury, Joseph, Arnold, Suzanne N., and Price, Nichole N.

Subjects

OCEAN acidification, FUCUS vesiculosus, MACROPHYTES, ZOSTERA marina, CARBON dioxide, ULVA, SEAWATER

Abstract

The urgent need to remediate ocean acidification has brought attention to the ability of marine macrophytes (seagrasses and seaweeds) to take up carbon dioxide (CO2) and locally raise seawater pH via primary production. This physiological process may represent a powerful ocean acidification mitigation tool in coastal areas. However, highly variable nearshore environmental conditions pose uncertainty in the extent of the amelioration effect. We developed experiments in aquaria to address two interconnected goals. First, we explored the individual capacities of four species of marine macrophytes (Ulva lactuca, Zostera marina, Fucus vesiculosus and Saccharina latissima) to ameliorate seawater acidity in experimentally elevated pCO2. Second, we used the most responsive species (i.e., S. latissima) to assess the effects of high and low water residence time on the amelioration of seawater acidity in ambient and simulated future scenarios of climate change across a gradient of irradiance. We measured changes in dissolved oxygen, pH, and total alkalinity, and derived resultant changes to dissolved inorganic carbon (DIC) and calcium carbonate saturation state (Ω). While all species increased productivity under elevated CO2, S. latissima was able to remove DIC and alter pH and Ω more substantially as CO2 increased. Additionally, the amelioration of seawater acidity by S. latissima was optimized under high irradiance and high residence time. However, the influence of water residence time was insignificant under future scenarios. Finally, we applied predictive models as a function of macrophyte biomass, irradiance, and residence time conditions in ambient and future climatic scenarios to allow projections at the ecosystem level. This research contributes to understanding the biological and physical drivers of the coastal CO2 system. [ABSTRACT FROM AUTHOR]

Published

2023

8. Spatiotemporal transitions in Pseudo-nitzschia species assemblages and domoic acid along the Alaska coast.

Author

Hubbard, Katherine A., Villac, Maria Célia, Chadwick, Christina, DeSmidt, Alexandra A., Flewelling, Leanne, Granholm, April, Joseph, Molly, Wood, Taylor, Fachon, Evangeline, Brosnahan, Michael L., Richlen, Mindy, Pathare, Mrunmayee, Stockwell, Dean, Lin, Peigen, Bouchard, Josée N., Pickart, Robert, and Anderson, Donald M.

Subjects

WATER masses, DOMOIC acid, SPECIES, PSEUDO-nitzschia, ECOSYSTEM health, SPECIES distribution

Abstract

The toxic diatom genus Pseudo-nitzschia is distributed from equatorial to polar regions and is comprised of >57 species, some capable of producing the neurotoxin domoic acid (DA). In the Pacific Arctic Region spanning the Bering, Chukchi, and Beaufort seas, DA is recognized as an emerging human and ecosystem health threat, yet little is known about the composition and distribution of Pseudo-nitzschia species in these waters. This investigation characterized Pseudo-nitzschia assemblages in samples collected in 2018 during summer (August) and fall (October-November) surveys as part of the Distributed Biological Observatory and Arctic Observing Network, encompassing a broad geographic range (57.8° to 73.0°N, -138.9° to -169.9°W) and spanning temperature (-1.79 to 11.7°C) and salinity (22.9 to 32.9) gradients associated with distinct water masses. Species were identified using a genus-specific Automated Ribosomal Intergenic Spacer Analysis (ARISA). Seventeen amplicons were observed; seven corresponded to temperate, sub-polar, or polar Pseudo-nitzschia species based on parallel sequencing efforts (P. arctica, P. delicatissima, P. granii, P. obtusa, P. pungens, and two genotypes of P. seriata), and one represented Fragilariopsis oceanica. During summer, particulate DA (pDA; 4.0 to 130.0 ng L-1) was observed in the Bering Strait and Chukchi Sea where P. obtusa was prevalent. In fall, pDA (3.3 to 111.8 ng L-1) occurred along the Beaufort Sea shelf coincident with one P. seriata genotype, and south of the Bering Strait in association with the other P. seriata genotype. Taxa were correlated with latitude, longitude, temperature, salinity, pDA, and/or chlorophyll a, and each had a distinct distribution pattern. The observation of DA in association with different species, seasons, geographic regions, and water masses underscores the significant risk of Amnesic Shellfish Poisoning (ASP) and DA-poisoning in Alaska waters. [ABSTRACT FROM AUTHOR]

Published

2023

9. Impact of Sea‐Ice Dynamics on the Spatial Distribution of Diatom Resting Stages in Sediments of the Pacific Arctic Region.

Author

Fukai, Yuri, Matsuno, Kohei, Fujiwara, Amane, Suzuki, Koji, Richlen, Mindy L., Fachon, Evangeline, and Anderson, Donald M.

Subjects

DIATOMS, SEA ice, SEDIMENTS, PHYTOPLANKTON

Abstract

The Pacific Arctic region is characterized by seasonal sea‐ice, the spatial extent and duration of which varies considerably. In this region, diatoms are the dominant phytoplankton group during spring and summer. To facilitate survival during periods that are less favorable for growth, many diatom species produce resting stages that settle to the seafloor and can serve as a potential inoculum for subsequent blooms. Since diatom assemblage composition is closely related to sea‐ice dynamics, detailed studies of biophysical interactions are fundamental to understanding the lower trophic levels of ecosystems in the Pacific Arctic. One way to explore this relationship is by comparing the distribution and abundance of diatom resting stages with patterns of sea‐ice coverage. In this study, we quantified viable diatom resting stages in sediments collected during summer and autumn 2018 and explored their relationship to sea‐ice extent during the previous winter and spring. Diatom assemblages were clearly dependent on the variable timing of the sea‐ice retreat and accompanying light conditions. In areas where sea‐ice retreated earlier, open‐water species such as Chaetoceros spp. and Thalassiosira spp. were abundant. In contrast, proportional abundances of Attheya spp. and pennate diatom species that are commonly observed in sea‐ice were higher in areas where diatoms experienced higher light levels and longer day length in/under the sea‐ice. This study demonstrates that sea‐ice dynamics are an important determinant of diatom species composition and distribution in the Pacific Arctic region. Plain Language Summary: The Pacific Arctic region is characterized by seasonal sea‐ice, and there is considerable interannual variation in the timing and quality of ice presence. In this region, diatoms are the dominant phytoplankton group during spring and summer. Under conditions unfavorable for growth, such as low light or limiting nutrients, many diatom species produce resting stages that are similar to "seeds" of plants. These resting stages settle to the seafloor and can reflect the diatom assemblages in the overlying water column. Since diatom species distribution is closely related to sea‐ice dynamics, detailed studies of this relationship are fundamental to understanding the basis of marine ecosystems in the Pacific Arctic region. In this study, we explored the relationship by comparing the distribution of diatom resting stage assemblages with patterns of sea‐ice coverage. Diatom assemblages detected in sediments were dependent on the variable timing of the sea‐ice retreat and accompanying light conditions. In areas where sea‐ice retreated earlier, open‐water species were abundant, while proportional abundances of ice‐associated diatoms were higher in areas where diatoms experience favorable light conditions in/under the sea‐ice. This study demonstrates that sea‐ice dynamics are an important determinant of diatom composition in the Pacific Arctic region. Key Points: Diatom resting stage assemblages were quantified and their relationship to the sea‐ice dynamics in the Pacific Arctic region was exploredDiatom composition follows spatial patterns that depend upon the variable timing of sea‐ice retreat and accompanying light conditionsAbundance of resting stage diatom cells in sediments varied by several orders of magnitude across the study region [ABSTRACT FROM AUTHOR]

Published

2021

10. Paralytic shellfish toxins in Alaskan Arctic food webs during the anomalously warm ocean conditions of 2019 and estimated toxin doses to Pacific walruses and bowhead whales.

Author

Lefebvre, Kathi A., Fachon, Evangeline, Bowers, Emily K., Kimmel, David G., Snyder, Jonathan A., Stimmelmayr, Raphaela, Grebmeier, Jacqueline M., Kibler, Steve, Ransom Hardison, D., Anderson, Donald M., Kulis, David, Murphy, Jim, Gann, Jeanette C., Cooper, Dan, Eisner, Lisa B., Duffy-Anderson, Janet T., Sheffield, Gay, Pickart, Robert S., Mounsey, Anna, and Willis, Maryjean L.

Subjects

*SHELLFISH, *PARALYTIC shellfish toxins, *WALRUS, *GYMNODINIUM, *MARINE mammals, *PARALYTIC shellfish poisoning, *FOOD chains, *ALGAL toxins

Abstract

• Algal toxins were present in all Alaskan Arctic Seas sampled • Algal toxins were present in all layers of Arctic food webs tested • Clams had the highest toxin concentrations in Arctic food webs • Walruses appear to consume higher toxin doses than bowhead whales • Toxin doses to walruses are near those known to poison humans Climate change-related ocean warming and reduction in Arctic sea ice extent, duration and thickness increase the risk of toxic blooms of the dinoflagellate Alexandrium catenella in the Alaskan Arctic. This algal species produces neurotoxins that impact marine wildlife health and cause the human illness known as paralytic shellfish poisoning (PSP). This study reports Paralytic Shellfish Toxin (PST) concentrations quantified in Arctic food web samples that include phytoplankton, zooplankton, benthic clams, benthic worms, and pelagic fish collected throughout summer 2019 during anomalously warm ocean conditions. PSTs (saxitoxin equivalents, STX eq.) were detected in all trophic levels with concentrations above the seafood safety regulatory limit (80 μg STX eq. 100 g−1) in benthic clams collected offshore on the continental shelf in the Beaufort, Chukchi, and Bering Seas. Most notably, toxic benthic clams (Macoma calcarea) were found north of Saint Lawrence Island where Pacific walruses (Odobenus rosmarus) are known to forage for a variety of benthic species, including Macoma. Additionally, fecal samples collected from 13 walruses harvested for subsistence purposes near Saint Lawrence Island during March to May 2019, all contained detectable levels of STX, with fecal samples from two animals (78 and 72 μg STX eq. 100 g−1) near the seafood safety regulatory limit. In contrast, 64% of fecal samples from zooplankton-feeding bowhead whales (n = 9) harvested between March and September 2019 in coastal waters of the Beaufort Sea near Utqiaġvik (formerly Barrow) and Kaktovik were toxin-positive, and those levels were significantly lower than in walruses (max bowhead 8.5 μg STX eq. 100 g−1). This was consistent with the lower concentrations of PSTs found in regional zooplankton prey. Maximum ecologically-relevant daily toxin doses to walruses feeding on clams and bowhead whales feeding on zooplankton were estimated to be 21.5 and 0.7 μg STX eq. kg body weight−1 day−1, respectively, suggesting that walruses had higher PST exposures than bowhead whales. Average and maximum STX doses in walruses were in the range reported previously to cause illness and/or death in humans and humpback whales, while bowhead whale doses were well below those levels. These findings raise concerns regarding potential increases in PST/STX exposure risks and health impacts to Arctic marine mammals as ocean warming and sea ice reduction continue. [ABSTRACT FROM AUTHOR]

Published

2022

11. Development of fluorescence in situ hybridization (FISH) probes to detect and enumerate Gambierdiscus species.

Author

Pitz, Kathleen J., Richlen, Mindy L., Fachon, Evangeline, Smith, Tyler B., Parsons, Michael L., and Anderson, Donald M.

Subjects

*FLUORESCENCE in situ hybridization, *MOLECULAR probes, *CORAL reef fishes, *RIBOSOMAL RNA, *SPECIES, *CELL determination, *FISH populations

Abstract

• FISH probes developed to detect Caribbean and Pacific species of Gambierdiscus in field samples. • Multiple Gambierdiscus species shown to co-occur in natural populations in the Caribbean and the Pacific. • FISH probes detected temporal changes in Gambierdiscus community composition in the Florida Keys. Ciguatera poisoning (CP) is a syndrome caused by the bioaccumulation of lipophilic ciguatoxins in coral reef fish and invertebrates, and their subsequent consumption by humans. These phycotoxins are produced by Gambierdiscus spp. , tropical epiphytic dinoflagellates that live on a variety of macrophytes, as well as on dead corals and sand. Recent taxonomic studies have identified novel diversity within the Gambierdiscus genus, with at least 18 species and several sub-groups now identified, many of which co-occur and differ significantly in toxicity. The ability to accurately and quickly distinguish Gambierdiscus species in field samples and determine community composition and abundance is central to assessing CP risk, yet most Gambierdiscus species are indistinguishable using light microscopy, and other enumeration methods are semi-quantitative. In order to investigate the spatial and temporal dynamics of Gambierdiscus species and community toxicity, new tools for species identification and enumeration in field samples are needed. Here, fluorescence in situ hybridization (FISH) probes were designed for seven species commonly found in the Caribbean Sea and Pacific Ocean, permitting their enumeration in field samples using epifluorescence microscopy. This technique enables the assessment of community composition and accurate determination of cell abundances of individual species. Molecular probes detecting G. australes, G. belizeanus, G. caribaeus, G. carolinianus, G. carpenteri, and the G. silvae/G. polynesiensis clade were designed using alignments of large subunit ribosomal RNA (rRNA) sequences. These probes were tested for specificity and cross-reactivity through experiments in which field samples were spiked with known concentrations of Gambierdiscus cultures, and analyzed to confirm that Gambierdiscus can be successfully detected and enumerated by FISH in the presence of detritus and other organisms. These probes were then used to characterize Gambierdiscus community structure in field samples collected from the Florida Keys and Hawai'i, USA. The probes revealed the co-occurrence of multiple species at each location. Time-series FISH analyses of samples collected from the Florida Keys quantified seasonal shifts in community composition as well as fluctuations in overall Gambierdiscus cell abundance. Application of species-specific FISH probes provides a powerful new tool to those seeking to target individual Gambierdiscus species, including significant toxin-producers, in field populations. Moving forward, analysis of Gambierdiscus community composition across multiple environments and over time will also allow species dynamics to be linked to environmental parameters, improving our ability to understand and manage the current and changing risks of CP worldwide. Image, graphical abstract [ABSTRACT FROM AUTHOR]

Published

2021