Incorporating thermal niche to benefit understanding climate‐induced biological variability in small pelagic fishes in the Kuroshio ecosystem

Ma, Shouxiang; Tian, Yongjun; Li, Jianchao; Ju, Peilong; Sun, Peng; Ye, Zhenjiang; Liu, Yang; Watanabe, Yoshirô

doi:10.1111/fog.12570

Cited by 7 publications

(3 citation statements)

References 93 publications

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“…The distribution of Eugymnanthea is influenced by the Kuroshio current providing warm waters and nutrients in the North Pacific 31,34 ; moreover, a widening in the distribution range of this genus in Japan is likely due to building of new infrastructures for aquaculture and the spreading of the introduced bivalve M. galloprovincialis .…”

Section: Resultsmentioning

confidence: 99%

“…Most occurrence records are from Japan, the Caribbean, and the Mediterranean seas (Figure 5b-d Sea and in the Northern region of Hokkaido, where cold waters likely limited the establishment of bivalve-inhabiting eirenids. 26 The distribution of Eugymnanthea is influenced by the Kuroshio current providing warm waters and nutrients in the North Pacific 31,34 ; moreover, a widening in the distribution range of this genus in Japan is likely due to building of new infrastructures for aquaculture and the spreading of the introduced bivalve M. galloprovincialis.…”

Section: Geographical and Bathymetric Distribution Of Hydroidsmentioning

confidence: 99%

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Guests or pests? Eirenid hydroids living on the soft tissue of bivalves

Camillo

Roveta

Mantas

et al. 2023

Reviews in Aquaculture

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Both wild and reared bivalves can host hydroids from the Eirenidae family which settle on the soft body parts of their host. Thousands of hydroids have been observed on a single bivalve, and often have severe detrimental effects on the host. However, this relationship has received little attention in aquaculture research, which is probably due to a lack of baseline data. An extensive review was conducted (i) to show the current level of knowledge on the association between eirenids and bivalves, providing a benchmark for future research; (ii) to detect a critical combination of biotic/abiotic factors that could switch the relationship from commensalism to infestation and (iii) to identify research priorities for future studies. Seventy scientific papers were screened to provide ecological information useful in understanding the hydroid‐host‐environment interactions and to show the global spatial and bathymetric distribution of the relationship. Although the main parameters influencing the hydroid abundance were identified, it was challenging to collate information from such heterogeneous data sources. A standardized method for data collection is proposed to obtain more robust and comparable data on the association. The most relevant and unstudied issue is the potential physiological and qualitative changes that could occur in infested bivalves. Monitoring the association could provide data needed to prevent or to control hyper‐proliferation of the symbionts and to detect eventual synergistic effects with climate change. This could be fundamental for species living in areas particularly prone to climate regime shifts, such as semi‐enclosed basins and estuarine habitats.

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Section: Resultsmentioning

confidence: 99%

Section: Geographical and Bathymetric Distribution Of Hydroidsmentioning

confidence: 99%

Guests or pests? Eirenid hydroids living on the soft tissue of bivalves

Camillo

Roveta

Mantas

et al. 2023

Reviews in Aquaculture

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“…Sea surface temperature and depth were important predictors for nearly the entire forage fish community but had a weaker influence than the submesoscale eddies and front persistence. SST is well established as a regulating factor in the distribution of pelagic fishes via physiological thermal niche constraints (Ma et al, 2022 ), and top predator distributions are known to be associated with SST patterns, as they track prey distributions (Hazen et al, 2013 ). SST and depth were also consistently predictive of forage fish distributions in single‐species modeling frameworks (Friedland et al, 2020 ; Holland et al, 2021 ; Suca, Deroba, et al, 2021 ).…”

Section: Discussionmentioning

confidence: 99%

Surface and subsurface oceanographic features drive forage fish distributions and aggregations: Implications for prey availability to top predators in the US Northeast Shelf ecosystem

Goetsch

Gulka

Friedland

et al. 2023

Ecology and Evolution

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Forage fishes are a critical food web link in marine ecosystems, aggregating in a hierarchical patch structure over multiple spatial and temporal scales. Surface-level forage fish aggregations (FFAs) represent a concentrated source of prey available to surface-and shallow-foraging marine predators. Existing survey and analysis methods are often imperfect for studying forage fishes at scales appropriate to foraging predators, making it difficult to quantify predator-prey interactions. In many cases, general distributions of forage fish species are known; however, these may not represent surface-level prey availability to predators. Likewise, we lack an understanding of the oceanographic drivers of spatial patterns of prey aggregation and availability or forage fish community patterns. Specifically, we applied Bayesian joint species distribution models to bottom trawl survey data to assess species-and community-level forage fish distribution patterns across the US Northeast Continental Shelf (NES) ecosystem.Aerial digital surveys gathered data on surface FFAs at two project sites within the NES, which we used in a spatially explicit hierarchical Bayesian model to estimate the abundance and size of surface FFAs. We used these models to examine the oceanographic drivers of forage fish distributions and aggregations. Our results suggest that, in the NES, regions of high community species richness are spatially consistent with regions of high surface FFA abundance. Bathymetric depth drove both patterns, while subsurface features, such as mixed layer depth, primarily influenced aggregation behavior and surface features, such as sea surface temperature, sub-mesoscale eddies, and fronts influenced forage fish diversity. In combination, these models help quantify the availability of forage fishes to marine predators and represent a novel application of spatial models to aerial digital survey data.

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