Your search keyword '"ECOPATH"' showing total 568 results

1. Study on the structure and energy flow of the salt marsh wetland ecosystem in Liaohe Estuary based on the Ecopath model.

Author

Daowei Yuan, Ming Qiu, Xushen Zhou, Yan Zhang, and Jianhua Zhao

Abstract

Salt marshes are one of the three blue carbon ecosystems recognized by the Intergovernmental Panel on Climate Change (IPCC). However, coastal salt marshes in China are facing the risk of degradation. To reveal the status of the salt marsh wetland ecosystem in Liaohe Estuary, an Ecopath model composed of 14 functional groups was constructed based on the 2019 ecological survey data. A comprehensive analysis of the system’s food web structure, energy flow processes, and overall ecosystem characteristics was conducted. The results show that the energy flow in the Liaohe Estuary salt marsh wetland ecosystem is mainly distributed in three integrated trophic levels. The utilization rates of trophic levels II and III are low, easily causing blockages in the lower trophic levels of the ecosystem’s energy flow. The total system throughput of the Liaohe Estuary salt marsh wetland ecosystem is 49,099.039 t·km²·a−1 ;. The system connectivity index and the system omnivory index are 0.207 and 0.109, respectively. Compared with other wetland systems, the ecosystem has a larger scale, but the overall ecosystem characteristic index reveals lower stability and complexity of the Liaohe Estuary salt marsh wetland system. [ABSTRACT FROM AUTHOR]

Published

2024

2. Sea Ice Dynamics and Planktonic Adaptations: A Study of Terra Nova Bay's Mesozooplanktonic Community during the Austral Summer.

Author

Guida, Alessandro, Povero, Paolo, Castellano, Michela, Magozzi, Sarah, Paoli, Chiara, Novellino, Antonio, Donnarumma, Luigia, Appolloni, Luca, and Vassallo, Paolo

Subjects

*SEA ice, *MARINE ecology, *SUMMER, *FOOD chains, *ALGAL blooms, ANTARCTIC climate

Abstract

Phytoplankton and zooplanktonic communities form the base of the Antarctic food web. This study examines the evolution of the mesozooplanktonic system in Terra Nova Bay during the austral summer (December–February), focusing on the impact of sea ice dynamics and the resulting phytoplankton blooms. Terra Nova Bay (Ross Sea) offers a valuable context given its high productivity and ecological variability. Using a diachronic approach, we analyzed data spanning twelve years to understand how the system's structure and functionality change over time. A novel key metric, Days since Sea Ice Melting, was employed to track shifts in phytoplankton community development and trophic dynamics. The results indicate that the system enters the summer season increasing primary productivity and creating the support for the development of a more complex and organized system during the season. The phytoplankton bloom recorded during mid-season, coped by an increase in biomass, is followed by the establishment of a well-organized grazing system. A secondary phytoplankton bloom is observed towards the end of the summer, but it does not significantly affect mesozooplankton communities. Overall, this study highlights the dynamic nature of Terra Nova Bay's mesozooplanktonic community and evaluates the influence of climate change on Antarctic marine ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

3. Impacts of El Niño–Southern Oscillation (ENSO) Events on Trophodynamic Structure and Function in Taiwan Bank Marine Ecosystem.

Author

Hsiao, Po-Yuan, Lan, Kuo-Wei, Lee, Wen-Hao, Liang, Ting-Yu, Liao, Cheng-Hsin, and Su, Nan-Jay

Subjects

*SKIPJACK tuna, *YELLOWFIN tuna, *KEYSTONE species, EL Nino, LA Nina

Abstract

Taiwan Bank (TB) is located in the southern Taiwan Strait (TS). The uplifted continental slope and bottom currents in this area result in the formation of upwelling areas, which serve as crucial fishing grounds. Climate-induced fluctuations in fish populations occur in the TS. However, how predation and competition affect the interspecies relationships in the TB ecosystem warrants clarification. In this study, we collected high-grid-resolution data on fishery activity (2013–2019) and constructed ecosystem models using Ecopath with Ecosim (EwE). Three mass-balanced models for determining the influence of El Niño–Southern Oscillation (ENSO) events on the TB ecosystem were constructed using EwE. A range of groups, including representative pelagic, benthic, and reef species, were collected for analyzing the relationship between migratory and sedentary species in terms of ecosystem structure variation due to climate change. The results demonstrated that the total system throughput (TST) was 10,556–11,122 t km−2 year−1, with an average transfer efficiency of 12.26%. According to the keystoneness index, calculated through mixed trophic impact analysis, Polydactylus sextarius and Scomber japonicus were the key species with top–down control and relatively high impact on the ecosystem in normal years. The keystone species also shifted to the predator fish Thunnus albacares and Katsuwonus pelamis during El Niño and La Niña events, respectively. Moreover, total biomass, TST, consumption, and respiration were noted to increase during ENSO events. However, during La Niña events, the diversity and connectance indexes were relatively low but pelagic species' biomass was relatively high, whereas the biomass of most benthic and reef species was relatively high during El Niño events. [ABSTRACT FROM AUTHOR]

Published

2024

4. Ecosystem structure and function of the North Water Polynya

Author

Andrea Bryndum-Buchholz, Jennifer L. Herbig, Gérald Darnis, Maxime Geoffroy, and Tyler D. Eddy

Subjects

North Water Polynya, food web, ecopath, ecosystem modelling, Arctic Ocean, Environmental sciences, GE1-350, Environmental engineering, TA170-171

Abstract

The North Water Polynya is one of the most productive Arctic regions on Earth, sustaining the world's northernmost Inuit communities for millennia. The polynya is a large and persistent region of open water surrounded by sea ice and exhibits high primary productivity, is a biodiversity hotspot, and is a key habitat and migration corridor for Arctic species. Many aspects of the ecosystem structure and the role of resident species in the North Water Polynya remain uncertain. To shed light on these, we developed the first representation of the North Water Polynya food web using the Ecopath modelling framework. Modelled trophic flows indicated that pelagic and benthic communities were primarily connected by Age 1+ Arctic cod (Boreogadus saida), walrus (Odobenus rosmarus), and ringed seal (Pusa hispida). Large copepods, Age 1+ Arctic cod, and bivalves were key prey species. Overall productivity in the North Water Polynya was higher compared to Western Baffin Bay and Western Greenland, corroborating expectations of relatively high productivity within the polynya. This model provides a baseline description of the North Water Polynya ecosystem structure and function prior to future climate-driven food web changes and the emergence of large-scale commercial fisheries.

Published

2024

5. 基于 Ecopath 模型的鄱阳湖生态系统“十年禁渔”效果评估.

Author

杨舒帆, 叶少文, 徐军, 黎明政, and 刘焕章

Abstract

Copyright of Journal of Hydrobiology is the property of Editorial Department of Journal of Hydrobiology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

6. Modeling food web and fisheries dynamics in Lake Baringo, Kenya.

Author

Walumona, Jacques Riziki, Kaunda‐Arara, Boaz, Ogombe Odoli, Cyprian, Masilya Mulungula, Pascal, Philip, Raburu, Kondowe, Benjamin Nelson, Kobingi, Nyakeya, Murakaru, Mugo James, Mulongaibalu, Mbalassa, and Amisi Muvundja, Fabrice

Subjects

*FOOD chains, *WATER quality management, *FISHERIES, *KEYSTONE species, *TOP predators, *MARINE parks & reserves

Abstract

Lakes are important in supporting ecosystem services and livelihoods. However, their food webs and ecological functioning are continuously threatened by anthropogenic influences. Food web models have been widely used in studying trophodynamics, fisheries impacts, and ecological functioning of temperate lakes, but less often in Afrotropical lake systems. We used Ecopath mass‐balanced trophic models annually in 1999, 2010, and 2020 to assess trends in ecosystem function, and the impact of fisheries on the Lake Baringo Ecosystem, a shallow freshwater lake in Kenya. Pre‐balance (PREBAL) and Pedigree analyses supplemented Ecopath models. Model input data were from field sampling, published and gray literature. Food web trophic models indicated a bottom‐up grazer and detrital food chains in all 3 years. Odum's ecosystem development indicators (total productivity to total biomass and total respiration ratios; TPP/TB and TPP/TR) showed that the lake was in a low to intermediate developmental stage, with room for bio‐manipulation, and a highly reduced mean transfer efficiency (TE) (6.4%–0.49%) indicated low trophic transfer of internal production. System omnivory (SOI) and connectance (CI) indices that varied among years indicated temporal variation in food web complexity. Indices of system resilience (overhead and ascendency) indicated an increasing potential for the lake to recover from perturbations. The mean trophic level of the catch (MTLc) increased from 1999 to 2010 and decreased in 2020, by fishing down the food chain as fishing pressure increased. Oreochromis niloticus, an endemic cichlid, was the keystone species (KSi >0) controlling community structure, while the lungfish Protopterus aethiopicus, the top predator in the lake, was not a keystone species (KSi <0). We recommend an integrated approach to lake management that incorporates watershed regulations, regulates fishing effort on the keystone species (O. niloticus), and monitors water quality for sustainable management of the Lake Baringo ecosystem. [ABSTRACT FROM AUTHOR]

Published

2024

7. Ecosystem health of Sasthamkotta Lake, a Ramsar site from India based on food web analysis and ecological indicators.

Author

Nandana, U. S., Sreekanth, G. B., and Ranjeet, K.

Subjects

BIOINDICATORS, ECOSYSTEM health, FOOD chemistry, ECOLOGICAL disturbances, FOOD chains, ECOSYSTEMS

Abstract

Water abstraction and subsequent lowering of water table in Sasthamkotta, the largest freshwater lake in South West coast of India raised serious concerns on its management and future implications to terrestrial and aquatic associated fauna. Though a designated Ramsar site, Sasthamkotta Lake has been exposed to various anthropogenic stressors, which in recent years have caused a sudden decrease in its productivity. The study therefore aimed to delineate the present ecological health of the lake in terms of its trophic dynamics and ecosystem efficiency using ecosystem modeling approach. The estimated trophic level (TL) of the lake ranged between 1 (detritus) to 3.76 (fish-eating birds), indicating a skewed structure towards lower carnivorous groups. The ecosystem maturity indices (connectance index, and system omnivory index) revealed the lake to be immature and in the developing stage, though the origin of the lake has been traced back to the quaternary era. The higher value of system overhead (66%) denotes that this ecosystem has been resisting ecological perturbations, in spite of its age is noteworthy. Though the study indicates that the lake's trophic structure is well-established, a variety of anthropogenic stressors reduce ground water levels and diminish aquifer recharge into the lake. This would significantly reduce the lake's catchment area, affecting the entire biota. The results presented here is a pioneering attempt to understand the current ecological condition and impact of future possible stressors that need to be monitored for ensuring ecosystem integrity of the lake. [ABSTRACT FROM AUTHOR]

Published

2024

8. Evaluating the Effects and Mechanisms of the Eco–Substrate in Aquaculture Environment Restoration from an Ecosystem Perspective via the Ecopath Model.

Author

Zhang, Kai, Jiang, Junxian, Li, Zhifei, Yu, Ermeng, Gong, Wangbao, Xia, Yun, Tian, Jingjing, Li, Hongyan, Xie, Wenping, Xie, Jun, and Wang, Guangjun

Abstract

Aquaculture supplies high-quality and healthy proteins. With the increasing human demand for aquaculture production, intensive pond aquaculture developed rapidly and results in environmental deterioration. To solve this problem, the eco-substrate (ES), which is the biofilm carrier, has been utilized in aquaculture ponds. Studying the ecological mechanisms of ES from the perspective of the ecosystem may be conducive to the sustainable development of aquaculture. In this study, it was evaluated how ES makes a difference to the trophic structure, energy flow, and system characteristics of two different aquaculture pond ecosystems via the ecopath model. Three aquaculture ponds with ES were designed as the treatment ecosystem and three aquaculture ponds without ES were designed as the control ecosystem. There were 13 and 14 functional groups in the control and treatment ecosystems, respectively. The results showed that (1) the macrozooplankton and microzooplankton showed strong effects on the ecosystem in the keystoneness index; (2) energy transfer pathways in the treatment system with ES increased by 26.23% compared to the control system; (3) the ES improved the utilization rate of detritus, which was 14.91% higher than that of the control ecosystem; (4) the material and energy flow index and network information characteristics demonstrated the ES enhanced the complexity and stability of the treatment system. To improve the energy utilization efficiency, filter feeders can be introduced to ES ponds. Overall, the ES can alter the trophic structure, improve the energy utilization efficiency, and enhance the stability and maturity of aquaculture ecosystems, representing a sustainable practice. Considering the total area of aquaculture ponds on the earth reaching more than 5 million hectares, the application prospect of ES is broad. [ABSTRACT FROM AUTHOR]

Published

2024

9. Sea Ice Dynamics and Planktonic Adaptations: A Study of Terra Nova Bay’s Mesozooplanktonic Community during the Austral Summer

Author

Alessandro Guida, Paolo Povero, Michela Castellano, Sarah Magozzi, Chiara Paoli, Antonio Novellino, Luigia Donnarumma, Luca Appolloni, and Paolo Vassallo

Subjects

Ross Sea, Antarctica, Ecopath, Network Analysis, diachronic analysis, Biology (General), QH301-705.5

Abstract

Phytoplankton and zooplanktonic communities form the base of the Antarctic food web. This study examines the evolution of the mesozooplanktonic system in Terra Nova Bay during the austral summer (December–February), focusing on the impact of sea ice dynamics and the resulting phytoplankton blooms. Terra Nova Bay (Ross Sea) offers a valuable context given its high productivity and ecological variability. Using a diachronic approach, we analyzed data spanning twelve years to understand how the system’s structure and functionality change over time. A novel key metric, Days since Sea Ice Melting, was employed to track shifts in phytoplankton community development and trophic dynamics. The results indicate that the system enters the summer season increasing primary productivity and creating the support for the development of a more complex and organized system during the season. The phytoplankton bloom recorded during mid-season, coped by an increase in biomass, is followed by the establishment of a well-organized grazing system. A secondary phytoplankton bloom is observed towards the end of the summer, but it does not significantly affect mesozooplankton communities. Overall, this study highlights the dynamic nature of Terra Nova Bay’s mesozooplanktonic community and evaluates the influence of climate change on Antarctic marine ecosystems.

Published

2024

10. Impacts of El Niño–Southern Oscillation (ENSO) Events on Trophodynamic Structure and Function in Taiwan Bank Marine Ecosystem

Author

Po-Yuan Hsiao, Kuo-Wei Lan, Wen-Hao Lee, Ting-Yu Liang, Cheng-Hsin Liao, and Nan-Jay Su

Subjects

Taiwan bank, Taiwan strait, Ecopath, ENSO, ecosystem function, upwelling, Biology (General), QH301-705.5

Abstract

Taiwan Bank (TB) is located in the southern Taiwan Strait (TS). The uplifted continental slope and bottom currents in this area result in the formation of upwelling areas, which serve as crucial fishing grounds. Climate-induced fluctuations in fish populations occur in the TS. However, how predation and competition affect the interspecies relationships in the TB ecosystem warrants clarification. In this study, we collected high-grid-resolution data on fishery activity (2013–2019) and constructed ecosystem models using Ecopath with Ecosim (EwE). Three mass-balanced models for determining the influence of El Niño–Southern Oscillation (ENSO) events on the TB ecosystem were constructed using EwE. A range of groups, including representative pelagic, benthic, and reef species, were collected for analyzing the relationship between migratory and sedentary species in terms of ecosystem structure variation due to climate change. The results demonstrated that the total system throughput (TST) was 10,556–11,122 t km−2 year−1, with an average transfer efficiency of 12.26%. According to the keystoneness index, calculated through mixed trophic impact analysis, Polydactylus sextarius and Scomber japonicus were the key species with top–down control and relatively high impact on the ecosystem in normal years. The keystone species also shifted to the predator fish Thunnus albacares and Katsuwonus pelamis during El Niño and La Niña events, respectively. Moreover, total biomass, TST, consumption, and respiration were noted to increase during ENSO events. However, during La Niña events, the diversity and connectance indexes were relatively low but pelagic species’ biomass was relatively high, whereas the biomass of most benthic and reef species was relatively high during El Niño events.

Published

2024

11. Long-term response of trophic structure and function to dam removal in a subtropical mountain stream

Author

An-Cheng Lin and Hsing-Juh Lin

Subjects

Connectance, Dam removal, Ecopath, Floods, Oncorhynchus masou formosanus, Vitality, Ecology, QH540-549.5

Abstract

Although dam removal has been considered a viable strategy to mitigate habitat fragmentation within a stream, long-term ecosystem effects after dam removal have rarely been discussed. In an effort to enhance the resilience of the critically endangered Formosan salmon (Oncorhynchus masou formosanus) in response to climate change, a 15-m-high check dam in a subtropical high-mountain stream was half-removed. The aim of this study was to analyze the long-term response of trophic structure and function to dam removal by constructing Ecopath models upstream and downstream of the removed dam at different times. Field surveys for model parameters were conducted for a complete seasonal cycle 1 year before dam removal, 1 and 2 years (short-term) after dam removal and 7 and 8 years (long-term) after dam removal. Both upstream and downstream systems moved toward maturity after dam removal. In the short term after dam removal, more energy can be transferred further up in the food webs. The vitality and diversity of both systems also increased. In the long term after dam removal, although the transfer efficiencies of both systems generally showed a decreasing pattern, the resilience increased. Compared to the upstream system, the effects of dam removal on the downstream system were more evident. In the downstream system, dam removal enhanced the vitality of the Formosan salmon and thus the top-down control. The dominance of detritivory flow in the food web also shifted toward the dominance of herbivory flow. Consequently, the downstream system reached more maturity, and the food web was more closely linked. The ecosystem attributes of the upstream and downstream systems converged, suggesting that the decoupling between upstream and downstream systems resulting from damming disappeared 8 years after dam removal.

Published

2023

12. Impacts of regime shift on the fishery ecosystem in the coastal area of Kyoto prefecture, Sea of Japan, assessed using the Ecopath model.

Author

Inoue, Hiroshi, Watari, Shingo, Sawada, Hideki, Lavergne, Edouard, and Yamashita, Yoh

Subjects

*FISHERIES, *SUSTAINABLE fisheries, *OVERFISHING, *DOMINATING set, *PRODUCTION losses

Abstract

The present study assessed the impact of regime shifts on the ecosystems that support fisheries in the coastal area of Kyoto Prefecture, the Sea of Japan. Ecopath models were constructed during cold (1985) and warm (2013) regime periods, when the fishery structures were different. Both models evaluated by pre-balance diagnostics were reliably constructed. Multiple ecosystem indicator values were compared between the two periods to assess changes in the ecosystem structure and the impact of fisheries on the ecosystem. The major change in catches in the coastal area of Kyoto Prefecture between 1985 and 2013 was that the Japanese sardine drastically declined and Spanish mackerel increased. The primary production requirements of fisheries (%PPR) were higher in 1985, reflecting the greater impact of sardine. The mean trophic level of catch and system omnivory index suggested that stability of trophic network increased after the sharp decline in sardine biomass. The %PPR, the loss of secondary production due to fisheries exploitation and probability analysis of fishery sustainability suggested that the fishery structure in 2013, which was dominated by set nets, contributed to a more sustainable fishery than the structure in 1985, when fishery was dominated by purse seines and set nets. [ABSTRACT FROM AUTHOR]

Published

2023

13. Lake food web structure in Teici Nature reserve, Latvia: fish presence shapes functioning of pristine bog lake food webs

Author

Zagars, Matiss, Christoffersen, Kirsten S., and Cremona, Fabien

Published

2024

14. An Ecopath perspective on the maximum sustainable yield of a macrophyte infested wetland in Eastern India

Author

Prajna Ritambhara Swain, Pranaya Kumar Parida, Preetha Panikkar, Basanta Kumar Das, Lianthuamluaia, Gunjan Karnatak, Aparna Roy, Shreya Bhattacharya, Sangeeta Chakraborty, Purna Chandra, Bijay Kumar Behera, Arun Pandit, and Kausik Mondal

Subjects

Wetland, Ecopath, Eichhornia infestation, Grass carp, Ecological network analysis, Ecology, QH540-549.5

Abstract

Wetlands are recognized as one of the most productive aquatic ecosystems. This high productivity supports its enormous biodiversity, aiding a scope for the small scale fisheries within it. Basically, these wetlands act as platforms for culture-based fisheries (CBF) i.e practice of stocking fish seeds and harvesting the grow out fishes at later. Often in tropical wetlands, the high nutrient load and high temperature enable the luxurious growth of macrophytes. Moreover, this macrophyte infestation is considered as a bottleneck for wetland managers. Facing a similar situation our studied Beledanga wetland is a macrophyte-infested wetland and the invasive Eichhornia crassipes is the most dominant macrophyte species. Owing to the macrophyte problem, Grass carp have been stocked in it as a biocontrol agent, as grass carp is a known biocontrol agent for the macrophyte infestation situation and simultaneously it will raise the fish production. To ensure maximum sustainable production from the wetland by harnessing with the available resources, it is necessary to acquire knowledge about the system’s ecological status and its ecological networks. Thus, the Ecopath based mass-balanced model is one of the best suitable tools to know about the ecological organization of this Beledanga wetland. Considering the available data (observational and literature data), this study has constructed a mass-balanced Ecopath model with 14 functional groups including all fish groups, birds, plankton, benthos and detritus. It has been found that the zooplankton and benthos are the most utilized group and the birds are the keystone group in this wetland system. This wetland possesses a lower transfer efficiency as well as a low Finn’s cycling index (0.224%). The system is found as an immature system with moderate ascendancy and system reserve (overhead). Moreover, concerning the ecologically sustainable production from this wetland more virtual mass-balanced models were developed (i) to evaluate the optimum grass carp stocking to manage the macrophyte population and (ii) to assess the impact of the Eichhornia on the system functioning. The results show that the system can harbour 1.5 times more grass carp biomass than the present without hampering sustainability. Concerning the impact of Eichhornia, it has been noticed that this macrophyte affects the maturity and transfer process of the system. Moreover, its huge biomass only accumulates more detritus in the ecosystem.

Published

2023

15. Randall's Threadfin Bream (Nemipterus randalli , Russell 1986) Poses a Potential Threat to the Northeastern Mediterranean Sea Food Web.

Author

Akgun, Yagmur and Akoglu, Ekin

Subjects

*FOOD chains, *SEAFOOD, *MEDITERRANEAN cooking, *SEBASTES marinus, *ECOLOGICAL disturbances, *INDIGENOUS children, *ECOSYSTEMS

Abstract

The eastern Mediterranean Sea is one of the most invaded marine ecosystems due to the introduction of Lessepsian species, which migrated from the Red Sea to the Mediterranean Sea following the construction of the Suez Canal. Some of these species may initially appear to be beneficial for fisheries by providing additional income sources for fishers; however, this usually occurs at the expense of negatively impacted native species and, thus, the ecosystem, which leads to greater economic losses for the fisheries in the long term. Therefore, this study aims to quantify the impact of N. randalli, which is one of the Lessepsian species with increasing commercial importance for the fisheries, on the food web dynamics in a coastal ecosystem in the northeastern Mediterranean Sea using a mass-balance food web modelling approach by capitalising on field data obtained from trawl samplings conducted within the scope of the study. Results showed that the ecosystem was in a developmental stage and experienced an autotrophic succession. The keystone fish group with a structuring role in the food web was sea breams and porgies. Although N. randalli had positive impacts on certain commercially exploited indigenous demersal fish species by mitigating the negative impact of another Lessepsian species, i.e., Saurida undosquamis (Richardson, 1848), in the food web, it had a negative impact on the keystone group of the food web, i.e., sea breams and porgies. Therefore, N. randalli poses a potential threat to the ecosystem's structure, and the interactions of N. randalli with other species in the food web may instigate an ecosystem reorganisation in the future. We suggest targeted fisheries exploitation and incentives for the fishery of N. randalli as management strategies to mitigate its negative impacts. However, the mitigating role of N. randalli in regulating the negative impacts of S. undosquamis could be adversely affected by its increasing exploitation; therefore, future modelling studies should consider scenario simulations to test such effects. [ABSTRACT FROM AUTHOR]

Published

2023

16. Trophic fingerprinting of a pristine but rapidly deteriorating downstream region of a Western Ghats River.

Author

Sandra, Siby Mariya, Sreekanth, G. B., and Ranjeet, K.

Subjects

FOOD chains, SALINE waters, ENERGY transfer, ECOSYSTEM health, DETRITUS

Abstract

Chalakudy River is renowned for its pristine waters and rich ichthyofaunal biodiversity. The downstream area of the river is confronting a series of risks, including pollution, saline water ingression, sand mining, illegal and intensified fishing practices, and invasion of exotic and alien species. A mass balanced ecosystem model was constructed for the downstream region of Chalakudy River (DCR) using Ecopath with Ecosim (EWE), incorporating 12 functional groups to delineate the food web and network flow indices for the period 2020 to 2021. The trophic level (TL) of the ecosystem network ranged from TL-1 (detritus) to TL-3.4 (birds). High fishing pressure is one possible cause for the high ecotrophic efficiency values as evidenced by the fish groups. Both the grazing food chain and detritus food chain (detritivory: herbivory ratio 0.94) contributed more or less equal to the energy transfer between TL. Network analysis of the model indicated a mean transfer efficiency of 12%, with shares from primary producers (14%) and detritus (11%). A mixed trophic impact analysis demonstrated a strong positive impact of primary producers and detritus groups on most of the other ecological groups at higher trophic levels. The DCR model showed a high system throughput (32,464.7 t km−2 year−1), low system omnivory (0.09), low connectance index (0.36), low Finn's cycling index (4.9), and mean path length (2.8), low relative ascendency (37.5%), and high system overhead (62.5%). These indices propound that DCR is an immature and developing ecosystem with moderate strength in reserve to resist external perturbations. [ABSTRACT FROM AUTHOR]

Published

2023

17. Integrating the local knowledge of fishers into an ecological model for the sustainable management of a protected coastal lagoon area in Uruguay.

Author

Malfatti, Francisco, Lercari, Diego, and Bergamino, Leandro

Subjects

*ECOLOGICAL models, *COASTAL zone management, *LOCAL knowledge, *SCIENTIFIC knowledge, *TOP predators, *FISH populations, *ECOSYSTEMS, *PARALICHTHYS

Abstract

This study uses the local knowledge of artisanal fishers to assess ecosystem structure, functioning, and fishing impacts within a coastal lagoon in Uruguay. To this end, we used an Ecopath with Ecosim modelling approach based on fishers' knowledge and scientific data. The model considered 23 functional groups, while three fleets represented fishing activities targeting different species. The model output shows a foodweb which spans four trophic levels, including fish species as top predators, such as the flatfish Paralichthys orbignyanus and the tararira Hoplias malabaricus. Furthermore, according to fishers' knowledge, gastropods, polychaetes, and bivalves constitute primary consumers, while detritus and phytoplankton represent the primary food sources. The trophic impact analysis shows that the fish Mugil spp. and Odontesthes spp. generate important positive and negative impacts on most other ecosystem components, while fishing impacts occur at moderate exploitation levels on the targeted fish species. The indicators of the ecosystem effects of fishing including The Trophic Level of the Catch ranging from 2.4 to 2.6, the Primary Production Required showing relative low values of 2.3% and low probability of an ecosystem being sustainably fished alert us to the risk of ecosystem-level overfishing. The vast potential of fishers' knowledge in research can allow the co-creation of new insights into ecosystem structure and function. By including fishers in research, local communities can be empowered and benefit from management decisions through their trust in science. [ABSTRACT FROM AUTHOR]

Published

2023

18. Evolution of the Food Web in Bandon Bay, the Gulf of Thailand: Ten Years of the Blue Swimming Crab Stocking Programme.

Author

Sawusdee, Amonsak, Koolkalya, Sontaya, Thapanand, Thanitha, and Jutagate, Tuantong

Subjects

*PORTUNIDAE, *BLUE crab, *CRAB populations, *STOMATOPODA, *FOOD chains, *BIOMASS conversion

Abstract

The ecosystem of Bandon Bay, in the Gulf of Thailand (GoT), has been impacted since 2007 by the continued stocking of larval blue swimming crab Portunus pelagicus, also called a crab bank. In this study, the food web in the Bay was modelled using Ecopath software to compare the trophic status, interaction and energy flow among the components in the system in 2007 and 2016 (i.e., before and 10 years after the crab bank intervention). The models were based on data collected from trawling. Twenty fish and shellfish components were used in the 2007 model, while 22 were used in the 2016 model. A significant increase in biomass was found in blue swimming crab, but biomass declined for other demersal fishes, cephalopods, and Penaeid shrimps. The production/biomass ratios of most components were higher in 2016 but the consumption/biomass ratios were relatively unchanged. The ecotrophic efficiency indicated that shellfishes were more exploited than fishes. Changes in most of the ecological indices revealed higher maturity and stability after 10 years of crab bank operation. The mixed trophic impact indicated bottom-up regulation, and that the increase of blue swimming crab negatively impacted only Mantis shrimp. Overall, the results indicate positive impacts of the crab bank intervention. [ABSTRACT FROM AUTHOR]

Published

2023

19. Assessing the carrying capacity of Mercenaria mercenaria using a steady linear food web model in two pond‐culture ecosystems.

Author

Feng, Jie, Zhang, Tao, Song, Hao, Yu, Zheng‐lin, Yang, Mei‐jie, Hu, Zhi, Zhou, Cong, Shi, Pu, Zhao, Wei, Zhao, Liang, Hu, Peng‐peng, Ma, Pei‐zhen, Tian, Xiang‐li, Liang, Jian, Guo, Yong‐jun, Li, Hai‐zhou, Li, Wei‐dong, and Bai, Tao

Subjects

*NORTHERN quahog, *FOOD chains, *ENERGY transfer, *ENERGY consumption, *BIOMASS

Abstract

The Ecopath model was used to construct energy flow models of two pond ecosystems: Mercenaria mercenaria–fish–halophyte polyculture and M. mercenaria monoculture. Carrying capacities (CCs) of M. mercenaria were evaluated using energy flow models. Lateolabrax maculatus and M. mercenaria showed the highest biomass in the polyculture and monoculture ecosystems, respectively, and zoobenthos represented the highest trophic levels (TLs) in both ecosystems. Energy transfer efficiency between TLs I and II, total system throughput, and primary production were significantly higher under polyculture than under monoculture. Imported food strongly affected the energy flow structure of polyculture ecosystem. The dominant food chains in the polyculture and monoculture ecosystems were detritus and predatory food chains, respectively. The ecological and production CC under polyculture (1458.84 and 1632.51 g m−2, respectively) were 10.14‐ and 8.25‐fold higher than those under monoculture (143.87 and 197.99 g m−2, respectively). Polyculture is better suited for M. mercenaria than monoculture because of higher resource utilization efficiency and M. mercenaria CC. Estimating the CC of M. mercenaria using Ecopath models can help improve the aquaculture management; however, it should be considered that the Ecopath model cannot simulate inorganic processes, so caution should be exercised while using the estimated CC‐based Ecopath model. [ABSTRACT FROM AUTHOR]

Published

2022

20. Bonifacio strait natural reserve (BSNR): Investigating ecosystem functioning through comparative modelling of marine protected areas.

Author

Vanalderweireldt, Lucie, Albouy, Camille, Le Loc'h, François, Libralato, Simone, Millot, Rémi, Garcia, Jessica, Santoni, Marie-Catherine, Culioli, Jean-Michel, de Bettignies, Thibaut, and Durieux, Éric D.H.

Subjects

MARINE parks & reserves, BOTTLENOSE dolphin, MARINE resources, FOOD chains, FISHING nets, SMALL-scale fisheries

Abstract

The Bonifacio Straits Natural Reserve (BSNR) is a Mediterranean Marine Protected Area (MPA) located in Corsica, characterized by rocky coasts, steep bathymetry, and regulated exploitation of marine resources. In this study, we updated the BSNR Ecopath model from 2010, providing a re-evaluation of the MPA's impact 13 years after the reserve's establishment and incorporating improved catch estimates, particularly for recreational fisheries. The model encompassed four primary producer groups, fourteen invertebrate groups, two Chondrichthyes groups, sixteen teleost groups, one seabird group, and one cetacean group. The BSNR model depicted a Mediterranean ecosystem where piscivorous fishes and cephalopods link primary producers to top predators (Tursiops truncatus , Dentex dentex and Epinephelus marginatus), emphasizing complex trophic relationships. Although the ecosystem faced moderate fishing pressure, the model revealed uneven pressure among groups, with rays, for example, being particularly vulnerable to fishing nets. Additionally, a mixed trophic impact analysis revealed an absence of competition among fishing fleets for resources, suggesting that, overall, recreational and artisanal fisheries do not impact each other. By comparing MPA models across the Mediterranean Sea, our research suggests that MPA establishment might enhance the overall biomass of ecosystems within their boundaries. This abundance can spill over into adjacent areas, thereby increasing biomass and diversity in those regions. In more exploited MPAs, higher values for the Finn cycling index and the consumption to total system throughput ratio indicated that fishing activities increased pressure on prey resources by diminishing the system's energy, pushing the ecosystem to optimize recycling. • The modelled Bonifacio MPA showed a high degree of development as a mature system. • Fishing pressure, though low, disproportionately affected different functional groups. • The protection level of MPAs impacted biomass fluxes being recycled in the ecosystem. • Our study emphasizes the role of strictly regulated areas in coastal strategies. [ABSTRACT FROM AUTHOR]

Published

2024

21. Fisheries impact on the Sea of Marmara ecosystem structure and functioning during the last three decades

Author

İsmet Saygu, Ekin Akoglu, Güzin Gül, Dalida Bedikoğlu, and Nazli Demirel

Subjects

Ecopath, ecological network analyses, food web, trophic flow, ecosystem approach to fisheries (EAF), data-poor region, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

The Sea of Marmara (SoM), without doubt, is one of the most disturbed marine ecosystems of the Mediterranean basin. As a semi-enclosed and a recognized eutrophic basin, it has a unique natural characteristic by permanent stratification at ~25 m depth. The SoM ecosystem is under threat by multiple stressors from excessive nutrient enrichment, overfishing, invasive species, habitat loss to the climate change. Within this study, an assessment on the SoM ecosystem structure and functioning and its changes over time have been achieved. Hence, we firstly evaluate the SoM ecosystem over a period of three decades from the 1990s to the 2010s by using three mass-balance Ecopath models, secondly, we delineate the prevailing ecosystem structure and functioning in each period, thirdly we determine how the fishing impact contributed to the changes in the SoM since the 1990s and finally establish a baseline for the management and future studies of the ecosystem. The comparison of the models’ results for three consecutive time periods of the SoM showed that the energetic capacity of the ecosystem decreased significantly over the three decades while the decrease in cycling indices indicated that the SoM ecosystem became fragile to anthropogenic disturbances. According to ecosystem theory indices, the SoM is an immature ecosystem at a stage of autotrophic succession, with a very high total primary production, much more above unity that greatly exceeds total respiration. Our results highlighted that the SoM ecosystem was under bottom-up control exerted by mesozooplankton; however, anchovy was a bottleneck in energy transfers to higher trophic levels creating also a wasp-waist control in the food-web. The bycatch of demersal species with long life span, sharks and rays, brought them to the brink of going commercial extinction. Overall, the changes in the SoM ecosystem were due to the trophic cascades exerted by fisheries exploitation in addition to the changes in the productivity of the system. We conclude that the concomitant impacts of stressors on the SoM have been so diverse that an immediate action plan is required. Therefore, we propose a tentative outlook that will help in ecosystem monitoring and better management of the SoM.

Published

2023

22. Comparison of three modelling frameworks for aquatic ecosystems: practical aspects and applicability.

Author

Patonai, Katalin and Fábián, Virág Adrienn

Subjects

FOOD chains, ECOSYSTEMS, FRESH water

Abstract

Freshwater ecosystems are under multiple stressors and it is crucial to find methods to better describe, manage, and sustain aquatic ecosystems. Ecosystem modelling has become an important tool in integrating trophic relationships into food webs, assessing important nodes using network analysis, and making predictions via simulations. Fortunately, several modelling techniques exist, but the question is which approach is relevant and applicable when? In this study, we compare three modelling frameworks (Ecopath, Loop Analysis in R, STELLA software) using a case study of a small aquatic network (8 nodes). The choice of framework depends on the research question and data availability. We approach this topic from a methodological aspect by describing the data requirements and by comparing the applicability and limitations of each modelling approach. Each modelling framework has its specific focus, but some functionalities and outcomes can be compared. The predictions of Loop Analysis as compared to Ecopath's Mixed Trophic Impact plot are in good agreement at the top and bottom trophic levels, but the middle trophic levels are less similar. This suggests that further comparisons are needed of networks of varying resolution and size. Generally, when data are limiting, Loop Analysis can provide qualitative predictions, while the other two methods provide quantitative results, yet rely on more data. [ABSTRACT FROM AUTHOR]

Published

2022

23. Unveiling the wasp-waist structure of the Falkland shelf ecosystem: the role of Doryteuthis gahi as a keystone species and its trophic influences

Author

Beauchene Fishing, European Commission, German Federal Agency for Nature Conservation, Büring, Tobias, van der Grient, Jesse, Pierce, Graham J., Bustamante, Paco, Scotti, Marco, Jones, Jessica B., Rocha, Francisco, Arkhipkin, A., Beauchene Fishing, European Commission, German Federal Agency for Nature Conservation, Büring, Tobias, van der Grient, Jesse, Pierce, Graham J., Bustamante, Paco, Scotti, Marco, Jones, Jessica B., Rocha, Francisco, and Arkhipkin, A.

Abstract

The Falkland Shelf is a highly productive ecosystem in the Southwest Atlantic Ocean. It is characterized by upwelling oceanographic dynamics and displays a wasp-waist structure, with few intermediate trophic-level species and many top predators that migrate on the shelf for feeding. One of these resident intermediate trophic-level species, the Patagonian longfin-squid Doryteuthis gahi, is abundant and plays an important role in the ecosystem. We used two methods to estimate the trophic structure of the Falkland Shelf food web, focusing on the trophic niche of D. gahi and its impacts on other species and functional groups to highlight the importance of D. gahi in the ecosystem. First, stable isotope measurements served to calculate trophic levels based on an established nitrogen baseline. Second, an Ecopath model was built to corroborate trophic levels derived from stable isotopes and inform about trophic interactions of D. gahi with other functional groups. The results of both methods placed D. gahi in the centre of the ecosystem with a trophic level of ~ 3. The Ecopath model predicted high impacts and therefore a high keystoneness for both seasonal cohorts of D. gahi. Our results show that the Falkland Shelf is not only controlled by species feeding at the top and the bottom of the trophic chain. The importance of species feeding at the third trophic level (e.g. D. gahi and Patagonotothen ramsayi) and observed architecture of energy flows confirm the ecosystem's wasp-waist structure with middle-out control mechanisms at play

Published

2024

24. The impact of multiple stressors on coastal biodiversity and associated ecosystem services

Author

Watson, Stephen C. L. and Paterson, David M.

Subjects

577.7, Climate change, Marine systems, Multiple stressors, Biodiversity, Ecosystem services, Ecosystem health, Resilience, Nutrient stress, Ecopath, Ecological indices, Macro-invertebrates, Demersal fish, Waterbirds, QC903.W2, Coastal biodiversity, Climatic change, Nature--Effect of human beings on

Abstract

Marine and coastal ecosystems are subject to diverse and increasingly intensive anthropogenic activities, making understanding cumulative effects critically important. However, accurately accounting for the cumulative effects of human impacts can be difficult, with the possibility of multiple stressors interacting and having greater impacts than expected, compounding direct and indirect effects on individuals, populations, communities and ecosystems. Assessment of multiple stressors therefore requires extensive scientific research that directly tests how single or multiple ecological components are affected by stressors, both singly and when combined, and as a consequence, cumulative effects assessments are now increasingly included in environmental assessments. Currently, there is a need to assess these at larger spatial scales, with additional research also urgently needed on the responses of ecological components, processes and functions to single and cumulative stressors. As cumulative environmental impacts could be better addressed by regional stressor effects assessments that combine methods for predicting multiple pressures on ecosystem recovery alongside degradation, this study used several separate approaches that can be used in parallel to give support for local management measures. I tested four completely different methods - a range of multi-metric indices, a food web model (Ecopath), a predictive model (Ecosim) and a Bayesian Belief Network model. Each approach was tested and compared in two shallow water estuarine systems, in Scotland and England, initially concerning the impact of nutrient enrichment and subsequent recovery and was followed by an investigation of how the addition of multiple stressors (nutrient levels, temperature and river-flow rates) would impact the future state of each system. The response to stressors was highly context dependent, varying between and within geographic locations. Overall, each of the four different approaches complemented each other and gave strong support for the need to make big reductions in the pressures and to consider trade-offs between impacting pressures. The models and tools also indicate that in order to reach an improved overall environmental state of each ecosystem, a focus on nutrient reductions are likely to be the most effective of the controls on stressors explored and that cumulative effects of the management of nutrient inputs and increased water temperatures and river-flow are likely to exist.

Published

2017

25. Randall’s Threadfin Bream (Nemipterus randalli, Russell 1986) Poses a Potential Threat to the Northeastern Mediterranean Sea Food Web

Author

Yagmur Akgun and Ekin Akoglu

Subjects

alien fish species, Ecopath, food web modelling, ecological impact, Randall’s threadfin bream, Biology (General), QH301-705.5, Genetics, QH426-470

Abstract

The eastern Mediterranean Sea is one of the most invaded marine ecosystems due to the introduction of Lessepsian species, which migrated from the Red Sea to the Mediterranean Sea following the construction of the Suez Canal. Some of these species may initially appear to be beneficial for fisheries by providing additional income sources for fishers; however, this usually occurs at the expense of negatively impacted native species and, thus, the ecosystem, which leads to greater economic losses for the fisheries in the long term. Therefore, this study aims to quantify the impact of N. randalli, which is one of the Lessepsian species with increasing commercial importance for the fisheries, on the food web dynamics in a coastal ecosystem in the northeastern Mediterranean Sea using a mass-balance food web modelling approach by capitalising on field data obtained from trawl samplings conducted within the scope of the study. Results showed that the ecosystem was in a developmental stage and experienced an autotrophic succession. The keystone fish group with a structuring role in the food web was sea breams and porgies. Although N. randalli had positive impacts on certain commercially exploited indigenous demersal fish species by mitigating the negative impact of another Lessepsian species, i.e., Saurida undosquamis (Richardson, 1848), in the food web, it had a negative impact on the keystone group of the food web, i.e., sea breams and porgies. Therefore, N. randalli poses a potential threat to the ecosystem’s structure, and the interactions of N. randalli with other species in the food web may instigate an ecosystem reorganisation in the future. We suggest targeted fisheries exploitation and incentives for the fishery of N. randalli as management strategies to mitigate its negative impacts. However, the mitigating role of N. randalli in regulating the negative impacts of S. undosquamis could be adversely affected by its increasing exploitation; therefore, future modelling studies should consider scenario simulations to test such effects.

Published

2023

26. Temporal Dynamics in Energy Fluxes and Trophic Structure of a Portunus trituberculatus Polyculture Ecosystem During Different Culture Periods

Author

Jie Feng, Xiang-Li Tian, Shuang-Lin Dong, Rui-Peng He, Kai Zhang, Dong-Xu Zhang, and Qing-Qi Zhang

Subjects

Portunus trituberculatus, polyculture, trophic structure, dynamics, Ecopath, ecological network analysis, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

Swimming crab (Portunus trituberculatus) are an important aquaculture species in eastern coastal areas of China. To improve the understanding of P. trituberculatus culture ecosystem functioning, the dynamics of energy flow and trophic structure of a P. trituberculatus polyculture system (co-culture with white shrimp Litopenaeus vannamei and short-necked clam Ruditapes philippinarum) were investigated in this study. Three Ecopath models representing the early, middle, and late culture periods of a P. trituberculatus polyculture ecosystem, respectively, were constructed to compare ecosystem traits at different culture periods. The results demonstrated that detritus was the main energy source in this polyculture ecosystem, and most of the total system throughput occurred at trophic levels I and II. Artificial food input and consumption by the culture organisms increased from early to middle and late periods, which produced marked impacts on biomass structure and primary production. R. philippinarum was considered to have a dominant influence on phytoplankton community dynamics which changed from nano- to pico-phytoplankton predominance, from the middle to the late period. Considering the low utilization efficiency of pico-phytoplankton production, large amounts of detritus accumulated in the sediment in the late period, which may constitute a potential risk for the ecosystem. Ecological network analyses indicated that the total energy flow and level of system organization increased from the early to the middle and late periods, whereas food web complexity and system resilience decreased from early to middle and late periods, which may indicate a trend of decreasing ecosystem stability. The system may be further optimized by increased stocking density of R. philippinarum and by introducing macro-algae at a suitable biomass to increase ecosystem stability, energy utilization efficiency, and aquaculture production.

Published

2022

27. Comparison of Marine Ecosystems of Haizhou Bay and Lvsi Fishing Ground in China Based on the Ecopath Model.

Author

Gao, Shike, Chen, Ze, Lu, Yanan, Li, Zhen, Zhang, Shuo, and Yu, Wenwen

Subjects

GROUNDFISHES, FISHERY resources, FISHERY management, FOOD chains, FISHERY laws, MARINE resources conservation, MARINE ecology, FISH conservation

Abstract

Recently, under the impacts of environmental shifts and human activities, marine ecosystem conservation and recovery have become increasingly important for the management and sustainable development of fishery resources. We construct two Ecopath models to describe and compare the similarities and differences in the structure and function of the ecosystems in Haizhou Bay (HZB) for 2020–2021 and Lvsi Fishing Ground (LSFG) for 2018–2019 in this study. Our results highlight the similarities of the two ecosystems in which plankton (e.g., zooplankton and phytoplankton) are important functional groups with bottom-up effect control and congers control the top-down effect. The differences between the two ecosystems indicate that the HZB ecosystem is relatively mature due to higher Finn's cycling index (FCI), Finn's mean path length (FMPL), Connectance Index (CI), System Omnivory Index (SOI), and Ascendency/capacity (A/C). However the food web structure in the LSFG is more diverse and stable with higher Overhead/capacity (O/C) and Overhead/capacity (H). The differences are possibly due to the low trophic level (TL) species composition in the two ecosystems. Therefore, we suggest that stock enhancement and release methods should be deployed to release high TL species into designated water areas to increase food web complexity and ecosystem maturity in HZB and LSFG. This study will help inform ecosystem and fishery regulations in different ways and facilitate discussion towards the establishment of strategic conservation planning and adaptive management. [ABSTRACT FROM AUTHOR]

Published

2022

28. The significance of riparian communities in the energy flow of subtropical stream ecosystems.

Author

Liao, Yi-Chang, Lin, An-Cheng, Tsai, Han-Ni, Yen, Yu-Ting, Tzeng, Chyng-Shyan, Yang, Man-Miao, and Lin, Hsing-Juh

Subjects

*STREAMFLOW, *RIVER conservation, *AQUATIC insects, *RIPARIAN areas, *ECOSYSTEMS, *FOOD chains

Abstract

There is a frequent energy flow connection between streams and riparian zones. However, riparian communities have been limited in studies of stream ecosystems. To understand the significance of riparian communities in the energy flow of stream ecosystems, we compared two trophic models in a small forest tributary (the Feifong Stream) and the mainstream (the Houlong Stream) that possessed high and low biomasses of riparian vegetation and arthropods, respectively. There were 25 functional groups classified into 3 integer trophic levels in the two trophic models. Arthropods, mostly insects, were the main carrier of the energy flow between aquatic and riparian habitats. The feeding connections were more extensive and intensive in the tributary than in the mainstream, as riparian arthropods were more abundant in the tributary. When including the riparian community in the tributary, the trophic model became more mature, as the values of system omnivory index and trophic transfer efficiency and the ascendency: capacity ratio were higher, but the connectance index value and overhead: capacity ratio were lower in the model with riparian groups than in the model without riparian groups. In the tributary, the ecotrophic efficiency (EE) values of aquatic insect groups increased largely if the riparian community was included in the model. In the mainstream, however, most of the ecosystem attributes and the EE values of aquatic insect groups did not obviously change if the model included the riparian community. This study highlights the significance of riparian communities in the energy flow of subtropical stream ecosystems. Aquatic and riparian systems should be considered together as a mature ecosystem for the planning of stream conservation. The loss or degradation of one habitat may have more detrimental effects on the other community than we have previously recognized, particularly in a small forest stream. [ABSTRACT FROM AUTHOR]

Published

2022

29. Using Ecopath Models to Explore Differences in Ecosystem Characteristics Between an Artificial Reef and a Nearby Natural Reef on the Coast of the North Yellow Sea, China

Author

Rongliang Zhang, Qianqian Zhang, Jianmin Zhao, Zhongxin Wu, Hui Liu, Lu Shou, Yibo Liao, Qinghe Liu, Yanbin Tang, and Jiangning Zeng

Subjects

artificial reefs, natural reefs, Ecopath, trophic structure, energy flow, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

The comparison of trophic structure and energy flow between natural and artificial reefs is imperative to evaluate whether these man-made structures work similarly to comparable natural reefs. Here, to characterize the potential difference in functioning between two types of reef ecosystems, two trophic models (Ecopath) at an artificial reef and an adjacent natural reef on the coast of the north Yellow Sea, China, were established. Both Ecopath models were divided into 18 functional groups from primary producers (algae and phytoplankton) and detritus to predatory species (e.g., Sebastes schlegelii). Model outputs showed that the ecosystem scale was smaller in the artificial reef (total system throughput (TPP) = 6,455.47 t·km−2·year−1) relative to its natural counterpart (TPP = 9,490.48 t·km−2·year−1). At both reef types, a large proportion of energy occurred at trophic levels I and II, and most of the primary production was utilized through a detritus pathway. This result implies a bottom-up energy flow control for both cases. However, two types of reef systems were behaving in a reasonable manner, as mean transfer efficiencies were similar to the Lindeman efficiency (10%). The ecosystem maturity of the artificial reef is not comparable to that of the natural reef for its inferior value of total primary production/total respiration (TPP/TR). Moreover, both the connectance index (CI) and system omnivory index (SOI) were slightly higher at the artificial reef relative to the natural reef as well as other coastal systems with parallel latitudes, suggesting that the current artificial system has formed complicated interspecies relations and high-level stability. This work updates our knowledge about the functioning evolvement of established artificial reefs and provides a baseline for the efficient management of coastal zones and further investigations.

Published

2022

30. Pollution in the Arctic Ocean: An overview of multiple pressures and implications for ecosystem services.

Author

Townhill, Bryony L., Reppas-Chrysovitsinos, Efstathios, Sühring, Roxana, Halsall, Crispin J., Mengo, Elena, Sanders, Tina, Dähnke, Kirsten, Crabeck, Odile, Kaiser, Jan, and Birchenough, Silvana N. R.

Subjects

*MARINE pollution, *BIOLOGICAL systems, *ECOSYSTEMS, *RESOURCE exploitation, *ECOSYSTEM services, *POLLUTANTS, *SEA ice, *CLIMATE change

Abstract

The Arctic is undergoing unprecedented change. Observations and models demonstrate significant perturbations to the physical and biological systems. Arctic species and ecosystems, particularly in the marine environment, are subject to a wide range of pressures from human activities, including exposure to a complex mixture of pollutants, climate change and fishing activity. These pressures affect the ecosystem services that the Arctic provides. Current international policies are attempting to support sustainable exploitation of Arctic resources with a view to balancing human wellbeing and environmental protection. However, assessments of the potential combined impacts of human activities are limited by data, particularly related to pollutants, a limited understanding of physical and biological processes, and single policies that are limited to ecosystem-level actions. This manuscript considers how, when combined, a suite of existing tools can be used to assess the impacts of pollutants in combination with other anthropogenic pressures on Arctic ecosystems, and on the services that these ecosystems provide. Recommendations are made for the advancement of targeted Arctic research to inform environmental practices and regulatory decisions. [ABSTRACT FROM AUTHOR]

Published

2022

31. Trophic dynamics and properties of the marine ecosystem of Campeche Bank, Mexico.

Author

Chi-Espínola, Ariel Adriano and Vega-Cendejas, María Eugenia

Subjects

*MARINE ecology, *FISHERY resources, *GASTROINTESTINAL contents, *FLUORESCENCE in situ hybridization, *CAPACITY building, *PREDATION, *BIODIVERSITY

Abstract

Campeche Bank located in the Yucatan Peninsula, Mexico is characterized by particular oceanographic and physiographic conditions that promote great biodiversity, including abundant fishery resources. Systematic sampling through oceanographic campaigns (November 2015, April 2016), produced high-quality data to generate a trophic model balance using Ecopath software. The goal of this study is to know the baseline of the structure and functioning of this important marine area. The predator/prey matrix was drawn up from the stomach content analysis of 186 fish species integrated into 47 families. The schematic representation exemplifies a complex trophic interaction of 22 trophic groups, including 10 fish groups, 8 invertebrate, zooplankton, phytoplankton, benthic producers, and detritus. Production and consumption of biomass and ecotrophic efficiency values were calculated for each of the trophic groups. The Total System Throughput was of 319.514 t/km2/year. The Ascendency, system Overhead, and Development Capacity were of 476.4, 673.1, and 1150.0 flow bits, respectively. Campeche Bank is an oligotrophic system with an intermediate state of resilience to environmental variations, growth potential intermediate, and greatly influenced by loop and Caribbean currents. These properties together with indicators of overfishing in the system and pollution (hydrocarbons), highlight the requirement of controlling fishery pressures and monitor hydrocarbons industry in the area to maintain its function and biodiversity. [ABSTRACT FROM AUTHOR]

Published

2022

32. Trophic gauntlet effects on fisheries recovery: a case study in Sansha Bay, China.

Author

Xie, Bin, Huang, Cheng, Wang, Ya, Zhou, Xijie, Peng, Guogan, Tao, Yancheng, Huang, Jiaju, Lin, Xiaoqing, and Huang, Lingfeng

Subjects

LARIMICHTHYS, BIOLOGICAL productivity, GROUNDFISHES, FISHERIES, FISHERY closures, ALGAL blooms, MARINE zooplankton, ALGAL growth

Abstract

Low biological productivity causes ecosystem energy deficiency. Sansha Bay is an important spawning and nursery ground for migratory fish in the East China Sea (ECS). There is significant mariculture in this area, but stock enhancement programs and seasonal fishery closures have failed to recover populations of the commercially important species, Larimichthys crocea. We want to figure out the potential reason of unsuccessful L. crocea resource in recent 30 years. In this study, the trophic status of L. crocea, the food source proportions of L. crocea and zooplankton, and the food web structure and functioning of Sansha Bay was analyzed. A high nutrient low chlorophyll phenomenon was observed: this prevented harmful algal blooms, and phytoplankton growth was restrained by intensive macroalgal culture, resulting in a low abundance of zooplankton in Sansha Bay. Phytoplankton was the most important food source of zooplankton, and zooplankton was the greatest food source of juvenile L. crocea. Analyzed L. crocea suffered from starvation. Crucially, most of the phytoplankton was not used efficiently in the Sansha Bay ecosystem. This study suggests that trophic bottleneck, caused by food limitation, is a potential reason for unsuccessful fishery recovery in enclosed bay with macroalgal culture. [ABSTRACT FROM AUTHOR]

Published

2021

33. Seasonal Variation of Food Web Structure and Stability of a Typical Artificial Reef Ecosystem in Bohai Sea, China

Author

Shengpeng Li, Ruyue Wang, Yueming Jiang, Yanyu Li, Lin Zhu, and Jianfeng Feng

Subjects

Bohai Sea, Ecopath, feedback loop, food web, stability, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

The last 30 years have witnessed the degradation and loss of function in the ecosystem of the Bohai Sea, China. Great efforts, such as artificial reefs, have been used to restore the ecosystem of the Bohai Sea in recent years. In this study, we examined the seasonal variation of food webs in artificial reefs of Juehua Island by the Ecopath model. Results showed that the number of species, range of trophic level, energy cycle proportion, energy complexity, nutrition transfer efficiency, and ecosystem maturity have increased from summer to autumn. However, the food web stability of artificial reefs has no obvious change from summer to autumn. Loop analysis revealed that the heaviest feedback loops are the interactions among benthos, zooplankton, and phytoplankton, and the predator-prey negative interaction strength between zooplankton and phytoplankton dominated the stability of the artificial reef, whether in summer or autumn. This study suggests that stability is a more robust indicator for ecosystem assessment and could provide useful information in future restoration plans of the marine ecosystem.

Published

2022

34. Modeling impacts of invasive sharp tooth African catfish Clarias gariepinus (Burchell 1822) and Mozambique tilapia Oreochromis mossambicus (Peters, 1852) on the ecosystem of a tropical reservoir ecosystem in India.

Author

Khan, Mohamed Feroz, Panikkar, Preetha, Salim, Sibina Mol, Leela, Ramya Vijayakumar, Sarkar, Uttam Kumar, Das, Basanta Kumar, and Eregowda, Vijayakumar Muttenahalli

Subjects

CLARIAS gariepinus, MOZAMBIQUE tilapia, FISHERY management, CATFISHES, WATER birds, INTRODUCED species

Abstract

Invasive species exert a strong impact on the trophic structure and functioning of the ecosystem they occupy. A modeling software globally used to assess these impacts is Ecopath with Ecosim. This study measures the effects of two invasive species, African catfish Clarias gariepinus, in the food web of the Karapuzha reservoir ecosystem in India. The findings show that the two invasive species directly and indirectly influence several ecosystem elements. The high level of niche overlap (92%) and strong competition for similar resources was exhibited by C. gariepinus. The adverse effects of African catfish on all fish and crustaceans in the reservoir were revealed by mixed trophic impact. Oreochromis mossambicus impacts were both positive and negative. It had a beneficial impact on its predator aquatic birds and was negative towards minnows. This study will help fishery managers to make informed decisions for ecosystem-based fishery management of fish resources. [ABSTRACT FROM AUTHOR]

Published

2021

35. Trophic transfer efficiency in the Lake Superior food web: Assessing the impacts of non-native species.

Author

Matthias, B.G., Hrabik, T.R., Hoffman, J.C., Gorman, O.T., Seider, M.J., Sierszen, M.E., Vinson, M.R., Yule, D.L., and Yurista, P.M.

Abstract

Ecosystem-based management relies on understanding how perturbations influence ecosystem structure and function (e.g., invasive species, exploitation, abiotic changes). However, data on unimpacted systems are scarce; therefore, we often rely on impacted systems to make inferences about 'natural states.' Among the Laurentian Great Lakes, Lake Superior provides a unique case study to address non-native species impacts because the food web is dominated by native species. Additionally, Lake Superior is both vertically (benthic versus pelagic) and horizontally (nearshore versus offshore) structured by depth, providing an opportunity to compare the function of these sub-food webs. We developed an updated Lake Superior EcoPath model using data from the 2005/2006 lake-wide multi-agency surveys covering multiple trophic levels. We then compared trophic transfer efficiency (TTE) to previously published EcoPath models. Finally, we compared ecosystem function of the 2005/2006 ecosystem to that with non-native linkages removed and compared native versus non-native species-specific approximations of TTE and trophic flow. Lake Superior was relatively efficient (TTE = 0.14) compared to systems reported in a global review (average TTE = 0.09), and the microbial loop was highly efficient (TTE > 0.20). Non-native species represented a very small proportion (<0.01%) of total biomass and were generally more efficient and had higher trophic flow compared to native species. Our results provide valuable insight into the importance of the microbial loop and represent a baseline estimate of non-native species impacts on Lake Superior. Finally, this work is a starting point for further model development to predict future changes in the Lake Superior ecosystem. [ABSTRACT FROM AUTHOR]

Published

2021

36. Food web modeling indicates the potential impacts of increasing deforestation and fishing pressure in the Tapajós River, Brazilian Amazon.

Author

Capitani, Leonardo, Angelini, Ronaldo, Keppeler, Friedrich Wolfgang, Hallwass, Gustavo, and Silvano, Renato Azevedo Matias

Abstract

In the Tapajós River, Brazilian Amazon, fishing is an important activity, especially for low-income riverine populations. Unfortunately, the Tapajós River fish diversity and abundance are threatened by several anthropogenic drivers, including deforestation and overfishing. We modeled the lower Tapajós River's food web and simulated changes in biomass compartments as a response to increases in deforestation (loss of floodplain forest habitat) and on artisanal fishing pressure over 30 years. According to our simulations, the large-bodied species could be reduced drastically while small-bodied and fast-growing species could be favored by fishing effort increasing. The loss of floodplain forest is expected to cause a general decline (23%) of the total standing fish biomass. This reduction could reflect greater losses on species that are directly dependent on resources from the floodplain forests, such as fruits and seeds. These results indicated that the food web of the lower Tapajós River is structurally characterized by bottom-up control, through the use of basal resources, such as detritus (mostly from decomposing plants), fruits, seeds, terrestrial, and aquatic invertebrates. Furthermore, the simulations' results highlight that the protection of the floodplain forest through the existing protected areas will be of essential importance in the future to maintain fish biomass, sustainable artisanal fishing, and improve the food security of Amazonian riverine inhabitants. [ABSTRACT FROM AUTHOR]

Published

2021

37. A Trophic Model for a Periodically Closed Coastal Lagoon System in the Southern Mexican Pacific.

Author

López-Vila, Jesús M., Schmitter-Soto, Juan J., and Velázquez-Velázquez, Ernesto

Abstract

Carretas-Pereyra is an estuarine lagoon system located in the southern Mexican Pacific coast. Its connection to the sea is intermittent, because the mouth of the system closes seasonally under natural conditions, but it is often opened artificially for artisanal fishery purposes. In order to know the degree of development, structure, and functioning of this system, under intermittent communication with the sea, a trophic model was built using software Ecopath. The model was composed of 32 functional groups: one for birds, one for crocodylians, 18 for fishes, 9 invertebrates, 2 plankton, and detritus. The pedigree index of the model was 0.62, which mean it is an acceptable model. The results are consistent with findings for lagoon systems with permanent connection to the sea. Some of the ecosystemic mechanisms probably used to face the abrupt changes induced by the opening of a sea inlet are: system omnivory, elevated overhead, efficient metabolism in phytoplankton, species replacement, and species adaptability to dominant environmental conditions. These elements provide stability to the ecosystem and help in its recovery. Detritus, zooplankton, and phytoplankton were important components for the resiliency of the system. In spite of the biological and environmental changes induced by the intermittent opening of an inlet, Carretas-Pereyra has the necessary elements to absorb the impacts and function adequately. [ABSTRACT FROM AUTHOR]

Published

2021

38. How trophic impasses structure coastal food webs? Insights from ECOPATH modelling.

Author

Solsona, N., Sturbois, A., Desroy, N., Ponsero, A., Schaal, G., and Le Pape, O.

Subjects

*FOOD chains, *SHELLFISH, *GREEN algae, *TIDAL flats, *AGRICULTURE, *INTRODUCED species, *ANTHROPOGENIC effects on nature, *COASTAL ecosystem health

Abstract

Fluxes of organic matter are the foundation of the functioning of ecosystems and the understanding of their origin, production and their uses by biological and ecological processes is therefore essential. In anthropized systems, such as coastal ecosystems, disruptions caused by human activities at different scales can mobilize a significant part of the organic matter, which is no longer available locally for natural processes. As many coastal and marine ecosystems, the megatidal bay of Saint-Brieuc (BSB) faces cumulated impacts of strong anthropogenic pressures, mainly eutrophication-related proliferation of green algae, invasive species (slipper limpet) and shellfish farming. To assess these cumulative impacts, this study performs a quantitative assessment of the food web using the mass balanced Ecopath model, at two spatial scales: the whole Bay vs its intertidal fraction. Models outputs demonstrate the importance of the spatial scale considered on conclusions drawn. The global model showed that invasive species constitute a non-negligible trophic impasse. The intertidal submodel evidenced the effects of both green algae (trophic impasse) and farmed mussels (export), i.e. main producers and consumers, respectively, as additional bottlenecks limiting the trophic transfer. The BSB is thus characterized by tidal flats approaching their productive carrying capacity and low trophic transfer, hindered by three main trophic impasses. • Ecopath modelling is used to achieve a quantitative evaluation of the food web. • The bay of Saint-Brieuc ecosystem is characterized by three trophic impasses. • Green algae proliferations impact the productivity of phytoplankton. • Farmed mussels are important competitors and consume a high part of phytoplankton. • The slipper limpet is an important competitor but locally and patchily distributed. [ABSTRACT FROM AUTHOR]

Published

2024

39. Estimated flows and biomass in a no-take coral reef from the eastern tropical Pacific through network analysis

Author

L.E. Calderon-Aguilera, H. Reyes-Bonilla, M. Olán-González, F.R. Castañeda-Rivero, and J.C. Perusquía-Ardón

Subjects

Emergent properties, Macroscopic indexes, Trophic network, Ecosystem-based management, ECOPATH, Ecology, QH540-549.5

Abstract

In the southern Gulf of California, the Cabo Pulmo reef has been the focus of many studies because it is the northern-most coral reef in the eastern Pacific. It is a paragon of a well-managed marine protected area. Under the assumption that fishing mortality is negligible, we want to identify and quantify major energy flows in an ecosystem without human intervention and describe the ecosystem resources and their interactions among species, to provide a tool for ecosystem-based management. We built a trophodynamic model using Ecopath to perform network analysis. Based on fieldwork (October 2017 – May 2018) and literature review, we identified 57 functional groups comprising 51 consumers (including 15 top predators), five primary producers plus detritus, and cluster analysis of trait profiles. The connectance index (0.17) and the system omnivory index (0.22) are low, suggesting that consumers feed on a few discrete trophic levels. Biomass of primary producers (grazing food chain; 186.8 t km−2) provides 9,813 t km−2 y−1, whereas flow from detritus supply 344.9 t km−2 y−1. The transfer efficiency decreases as flows go up the food web, from 12% at TL II to 4% at TL X, and throughput cycled (including detritus) = 118.7 t km−2 y−1. In comparison with other coral reefs, we found that Cabo Pulmo complies with the attributes to resist disturbances, with an estimated total system throughput = 95,789 t km−2 y−1, a net system production = 38,535 t km−2 y−1, a large mean path length = 12.11, ascendency = 123,662 (52%) flowbits and overhead = 116,164 (48%) flowbits. The high quality of the ecosystem services provided by Cabo Pulmo and the scenic beauty appeals to developers. Although the system is resilient, unregulated human activities may impact the reef condition and decrease the residents' quality of life and that of all the people who make a living from the low impact activities currently in effect. The trophic web model presented here may help to improve the response capacity of the coalition of residents, authorities, diving companies, and NGO's to preserve the reef and be a key element to conserve the system by contributing to its best management.

Published

2021

40. Trophic gauntlet effects on fisheries recovery: a case study in Sansha Bay, China

Author

Bin Xie, Cheng Huang, Ya Wang, Xijie Zhou, Guogan Peng, Yancheng Tao, Jiaju Huang, Xiaoqing Lin, and Lingfeng Huang

Subjects

high nutrient low chlorophyll, ecopath, stable isotope, mariculture, sansha bay, larimichthys crocea, Ecology, QH540-549.5

Abstract

Low biological productivity causes ecosystem energy deficiency. Sansha Bay is an important spawning and nursery ground for migratory fish in the East China Sea (ECS). There is significant mariculture in this area, but stock enhancement programs and seasonal fishery closures have failed to recover populations of the commercially important species, Larimichthys crocea. We want to figure out the potential reason of unsuccessful L. crocea resource in recent 30 years. In this study, the trophic status of L. crocea, the food source proportions of L. crocea and zooplankton, and the food web structure and functioning of Sansha Bay was analyzed. A high nutrient low chlorophyll phenomenon was observed: this prevented harmful algal blooms, and phytoplankton growth was restrained by intensive macroalgal culture, resulting in a low abundance of zooplankton in Sansha Bay. Phytoplankton was the most important food source of zooplankton, and zooplankton was the greatest food source of juvenile L. crocea. Analyzed L. crocea suffered from starvation. Crucially, most of the phytoplankton was not used efficiently in the Sansha Bay ecosystem. This study suggests that trophic bottleneck, caused by food limitation, is a potential reason for unsuccessful fishery recovery in enclosed bay with macroalgal culture.

Published

2021

41. Comparison of Marine Ecosystems of Haizhou Bay and Lvsi Fishing Ground in China Based on the Ecopath Model

Author

Shike Gao, Ze Chen, Yanan Lu, Zhen Li, Shuo Zhang, and Wenwen Yu

Subjects

Ecopath, food web, Haizhou Bay, Lvsi Fishing Ground, comparison, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

Recently, under the impacts of environmental shifts and human activities, marine ecosystem conservation and recovery have become increasingly important for the management and sustainable development of fishery resources. We construct two Ecopath models to describe and compare the similarities and differences in the structure and function of the ecosystems in Haizhou Bay (HZB) for 2020–2021 and Lvsi Fishing Ground (LSFG) for 2018–2019 in this study. Our results highlight the similarities of the two ecosystems in which plankton (e.g., zooplankton and phytoplankton) are important functional groups with bottom-up effect control and congers control the top-down effect. The differences between the two ecosystems indicate that the HZB ecosystem is relatively mature due to higher Finn’s cycling index (FCI), Finn’s mean path length (FMPL), Connectance Index (CI), System Omnivory Index (SOI), and Ascendency/capacity (A/C). However the food web structure in the LSFG is more diverse and stable with higher Overhead/capacity (O/C) and Overhead/capacity (H). The differences are possibly due to the low trophic level (TL) species composition in the two ecosystems. Therefore, we suggest that stock enhancement and release methods should be deployed to release high TL species into designated water areas to increase food web complexity and ecosystem maturity in HZB and LSFG. This study will help inform ecosystem and fishery regulations in different ways and facilitate discussion towards the establishment of strategic conservation planning and adaptive management.

Published

2022

42. A preliminary snapshot of the trophic model and ecosystem attributes of Kaptai reservoir ecosystem, Bangladesh.

Author

Khatun, Mst Halima, Barman, Partho Protim, Yi, Jundong, Lupa, Saymuna Tarin, Zahangir, Md Mahiuddin, and Liu, Qun

Subjects

*RESERVOIRS, *PHYTOPLANKTON, *FRESHWATER ecology, *SUSTAINABILITY, *DETRITUS

Abstract

A mass-balanced Ecopath model presents a quantitative description of the trophic structure, flow of energy and trophic interaction among ecological groups of an ecosystem. The Ecopath with Ecosim (EwE) modeling program (Version 6.5) was used to develop a preliminary trophic model for a tropical freshwater reservoir. The total fish biomass was 6.245 t/km2 and the highest trophic level of the reservoir was 3.362 (for snakehead). The ecosystem is phytoplankton based because primary producers originated 68% and detritus originated 32% of the total flow from lower trophic level. The gross efficiency of the fishery was 0.004, suggesting the inefficiency of the system. The positive effect of phytoplankton and detritus on most of the other groups were evident from mixed trophic analysis while moderately higher ecotrophic efficiency (EE) of phytoplankton shows the ecosystem's potential bottom-up control. The competition for the same resources among different groups was also obvious. The ratio of primary production/respiration (1.969) suggests that the ecosystem is at the developing stage and utmost contemplation should be given to concerned human activities. The low value of relative ascendancy (30.13) and overhead (69.87) reveals the stability of the ecosystem and some degrees of maturity. It also predicts the presence of significant strength in reserve of the system to withstand or overcome any perturbation. However, ecologically sustainable resource management plans should be implemented to ensure the sustainability of this reservoir resources. [ABSTRACT FROM AUTHOR]

Published

2021

43. Modeling trophic interactions and impacts of introduced icefish (Neosalanx taihuensis Chen) in three large reservoirs in the Yangtze River basin, China.

Author

Huang, Geng, Wang, Qidong, Du, Xue, Feng, Kai, Ye, Shaowen, Yuan, Jing, Liu, Jiashou, Li, Zhongjie, and De Silva, Sena S.

Subjects

*WATERSHEDS, *RESERVOIRS, *ECOLOGICAL impact, *COMPETITION (Biology), *ENERGY transfer

Abstract

Non-native fish introductions may damage aquatic ecosystems. To assess the ecological impacts of the introduced icefish (Neosalanx taihuensis Chen), three reservoirs in a cascade, including the Shuibuya Reservoir (SBYR), which is devoid of icefish, and the Geheyan Reservoir (GHYR) and the Gaobazhou Reservoir (GBZR), which have large and small icefish populations, respectively, were selected for this study. Three mass-balance trophic models were established using the Ecopath approach. The results indicated that (1) the three ecosystems tended to depend more on the grazing food chain, possibly because the dominant fish species in three reservoirs were mainly filter feeders or planktivores; (2) the large icefish population in the GHYR decreased the overall energy transfer efficiency; (3) the ecosystem indices suggested that the GHYR ecosystem appeared to be a moderately mature system with a simple and vulnerable food web structure, and the lack of complexity was largely attributed to the large population of introduced icefish; and (4) the "mixed trophic impacts (MTI)" and niche overlap analysis indicated that the ecological impacts of icefish mainly came from predation and interspecific competition. This study demonstrates the consequence of icefish introduction to aquatic ecosystems and suggests that appropriate control of exotic fish is worth considering. [ABSTRACT FROM AUTHOR]

Published

2020

44. Combining scientific and fishers' knowledge to co-create indicators of food web structure and function.

Author

Bentley, Jacob W, Hines, David E, Borrett, Stuart R, Serpetti, Natalia, Hernandez-Milian, Gema, Fox, Clive, Heymans, Johanna J, and Reid, David G

Subjects

*PREDATION, *FISHERS, *INFORMATION modeling, *STRUCTURAL components, *PLAICE

Abstract

In this study, we describe the approach taken by the International Council for the Exploration of the Seas Irish Sea benchmark working group (WKIrish), to co-create diet information for six commercial species using fishers' and scientists knowledge and incorporate it into an existing Ecopath food web model of the Irish Sea. To understand how the co-created diet information changed the model we compared a suite of food web indicators before and after the addition of fishers' knowledge (FK). Of the 80 predator–prey interactions suggested by fishers during workshops, 50 were already included in the model. Although the small number of changes made to the model structure had an insignificant impact on the ecosystem-level indicators, indicators of species hierarchical importance and mixed trophic impacts were significantly changed, particularly for commercial species. FK heightened the importance of discards as a source of food for rays, plaice, and whiting and reduced the importance of cod, toothed whales, and plaice as structural components of the food web. FK therefore led to changes which will influence pairwise advice derived from the model. We conclude by providing lessons from WKIrish which we believe were key to the positive co-production experience and development of integrated management. [ABSTRACT FROM AUTHOR]

Published

2019

45. Ecosystem modelling in the Northwestern Mediterranean Sea: Structure and functioning of a complex system

Author

Seyer, Thomas, Bănaru, Daniela, Vaz, Sandrine, Hattab, Tarek, Labrune, Céline, Booth, Shawn, Charmasson, Sabine, Seyer, Thomas, Bănaru, Daniela, Vaz, Sandrine, Hattab, Tarek, Labrune, Céline, Booth, Shawn, and Charmasson, Sabine

Abstract

Ecopath mass-balanced models are widely-used tools to address various challenges in the understanding and protection of ecosystems. To track the continuing improvements in data and the evolving environment (climate change, anthropic pressure), new models are regularly being developed. In this study, we built a Gulf of Lion Ecopath model, focused on the continental shelf, featuring enhanced representation of benthic invertebrates and a realistic assessment of catches, and which takes into account the significant changes observed after 2008–2009 in the trophic structure of this ecosystem as well as related changes in fisheries activities. The model is composed of 68 functional groups, including 6 primary producers, discards and detritus, 27 invertebrate groups, 31 fish groups, dolphins and seabirds. New datasets were taken into account for biomasses, as well as for diets. P/B and Q/B parameters were calculated to include the most recent and geographically closest data. Model results highlight a food web diagram, ranging over 5 trophic levels and placing Prionace glauca, Squalus acanthias and dolphins as top predators. The mixed trophic impact analysis showed that the groups with the highest accumulated negative impacts are, in decreasing order, benthic trawls, nets and carnivorous echinoderms. The groups with the highest accumulated positive impacts are, in decreasing order, detritus, microphytoplankton and nanoplankton. The flux analysis shows that a major part of the flows occurs at trophic level 2 with 35.1% of the model total throughput and 43.8% of the total biomass. The catches have a mean trophic level of 3.47, higher than in previous studies, reflecting the changes in the fisheries activities.

Published

2023

46. Long-term response of trophic structure and function to dam removal in a subtropical mountain stream.

Author

Lin, An-Cheng and Lin, Hsing-Juh

Subjects

*DAM retirement, *FRAGMENTED landscapes, *FOOD chains, *FIELD research, *ENERGY transfer, *ONCORHYNCHUS, *ECOSYSTEMS

Abstract

[Display omitted] Channel evolution before and after dam removal on 26 May 2011. • Long-term ecosystem effects after dam removal have rarely been discussed. • More energy was transferred further up in the food webs after short-term dam removal. • Both upstream and downstream resilience increased after long-term dam removal. • Effects of dam removal on downstream ecosystem were more evident. • Upstream and downstream ecosystems converged 8 years after dam removal. Although dam removal has been considered a viable strategy to mitigate habitat fragmentation within a stream, long-term ecosystem effects after dam removal have rarely been discussed. In an effort to enhance the resilience of the critically endangered Formosan salmon (Oncorhynchus masou formosanus) in response to climate change, a 15-m-high check dam in a subtropical high-mountain stream was half-removed. The aim of this study was to analyze the long-term response of trophic structure and function to dam removal by constructing Ecopath models upstream and downstream of the removed dam at different times. Field surveys for model parameters were conducted for a complete seasonal cycle 1 year before dam removal, 1 and 2 years (short-term) after dam removal and 7 and 8 years (long-term) after dam removal. Both upstream and downstream systems moved toward maturity after dam removal. In the short term after dam removal, more energy can be transferred further up in the food webs. The vitality and diversity of both systems also increased. In the long term after dam removal, although the transfer efficiencies of both systems generally showed a decreasing pattern, the resilience increased. Compared to the upstream system, the effects of dam removal on the downstream system were more evident. In the downstream system, dam removal enhanced the vitality of the Formosan salmon and thus the top-down control. The dominance of detritivory flow in the food web also shifted toward the dominance of herbivory flow. Consequently, the downstream system reached more maturity, and the food web was more closely linked. The ecosystem attributes of the upstream and downstream systems converged, suggesting that the decoupling between upstream and downstream systems resulting from damming disappeared 8 years after dam removal. [ABSTRACT FROM AUTHOR]

Published

2023

47. Highly Productive Tropical Seagrass Beds Support Diverse Consumers and a Large Organic Carbon Pool in the Sediments

Author

Chen-Lu Lee, Wei-Jen Lin, Pi-Jen Liu, Kwang-Tsao Shao, and Hsing-Juh Lin

Subjects

biodiversity, blue carbon, Ecopath, network analysis, seagrass beds, South China Sea, Biology (General), QH301-705.5

Abstract

Tropical seagrass beds are productive coastal ecosystems that are important blue carbon sinks and crucial habitats and feeding grounds for consumers at high trophic levels. To understand how energy sustains the ecosystem from seagrass production, we constructed an Ecopath trophic model to reveal the possible pathways of energy flow in the tropical seagrass beds around Dongsha Island, South China Sea. The model indicates that Dongsha seagrass beds were developing but well-structured ecosystems. The productive seagrasses were rarely directly consumed by herbivores and, ultimately, flowed into detrital pools. Detritus was the main food source used to support diverse consumers in the food web. Nevertheless, the low cycling rate (2.74%) suggests that most detritus was not reused or exported and was stored as a large organic carbon pool in the sediments. The detritus-feeding invertebrates are keystone groups in the Dongsha seagrass beds, as they recycle energy from detritus and transfer to top predators such as sharks. The predation of top predators affected the biomasses of other compartments, leading to strong top-down control via a trophic cascade effect.

Published

2021

48. DNA metabarcoding highlights cyanobacteria as the main source of primary production in a pelagic food web model

Author

Andreas Novotny, Baptiste Serandour, Susanne Kortsch, Benoit Gauzens, Kinlan M. G. Jan, Monika Winder, Department of Agricultural Sciences, Biological stations, and Plant Production Sciences

Subjects

11832 Microbiology and virology, Diversity, Multidisciplinary, Baltic sea, Nitrogen, Blooms, Climate, Communities, Deoxygenation, Terrestrial, Ecopath, Zooplankton, 4111 Agronomy, 1181 Ecology, evolutionary biology, 1172 Environmental sciences

Abstract

Models that estimate rates of energy flow in complex food webs often fail to account for species-specific prey selectivity of diverse consumer guilds. While DNA metabarcoding is increasingly used for dietary studies, methodological biases have limited its application for food web modeling. Here, we used data from dietary metabarcoding studies of zooplankton to calculate prey selectivity indices and assess energy fluxes in a pelagic resource-consumer network. We show that food web dynamics are influenced by prey selectivity and temporal match-mismatch in growth cycles and that cyanobacteria are the main source of primary production in the investigated coastal pelagic food web. The latter challenges the common assumption that cyanobacteria are not supporting food web productivity, a result that is increasingly relevant as global warming promotes cyanobacteria dominance. While this study provides a method for how DNA metabarcoding can be used to quantify energy fluxes in a marine food web, the approach presented here can easily be extended to other ecosystems.

Published

2023

49. A Comparative Analysis of Trophic Structure and Functioning in Large-Scale Mediterranean Marine Ecosystems

Author

Barausse, Alberto, Palmeri, Luca, Goffredo, Stefano, editor, and Dubinsky, Zvy, editor

Published

2014

50. Fishers' knowledge improves the accuracy of food web model predictions.

Author

Bentley, Jacob W, Serpetti, Natalia, Fox, Clive, Heymans, Johanna J, and Reid, David G

Subjects

*SCIENTIFIC knowledge, *SHELLFISH, *PREDICTION models, *CRABS, *HISTORICAL literacy, *INFORMATION resources, *COOKING

Abstract

Fisher's knowledge offers a valuable source of information to run parallel to observed data and fill gaps in our scientific knowledge. In this study we demonstrate how fishers' knowledge of historical fishing effort was incorporated into an Ecopath with Ecosim (EwE) model of the Irish Sea to fill the significant gap in scientific knowledge prior to 2003. The Irish Sea model was fitted and results compared using fishing effort time-series based on: (i) scientific knowledge, (ii) fishers' knowledge, (iii) adjusted fishers' knowledge, and (iv) a combination of (i) and (iii), termed "hybrid knowledge." The hybrid model produced the best overall statistical fit, capturing the biomass trends of commercially important stocks. Importantly, the hybrid model also replicated the increase in landings of groups such as "crabs & lobsters" and "epifauna" which were poorly simulated in scenario (i). Incorporating environmental drivers and adjusting vulnerabilities in the foraging arena further improved model fit, therefore the model shows that both fishing and the environment have historically influenced trends in finfish and shellfish stocks in the Irish Sea. The co-production of knowledge approach used here improved the accuracy of model simulations and may prove fundamental for developing ecosystem-based management advice in a global context. [ABSTRACT FROM AUTHOR]

Published

2019