Similar fish species composition despite larger environmental heterogeneity during severe hypoxia in a coastal ecosystem

Shinohara, Naoto; Hongo, Yuki; Ichinokawa, Momoko; Nishijima, Shota; Sawayama, Shuhei; Kurogi, Hiroaki; Uto, Yasuyuki; Mita, Hisanori; Ishii, Mitsuhiro; Kusano, Akane; Akimoto, Seiji

doi:10.1002/ece3.8884

Cited by 5 publications

(6 citation statements)

References 77 publications

(120 reference statements)

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“…Their finding was consistent with the expectation that abiotic filtering is stronger in harsh habitats (Chase, 2007; Guo et al, 2014). However, Shinohara et al (2022) found an opposite pattern in coastal fish communities in a Japanese bay. Compositional differences between bottom and surface water layers were less pronounced during the summer even though the environment is severer in comparison to other seasons (decreased DO).…”

Section: Temporal Dimensions Of Community Assemblymentioning

confidence: 97%

Spatiotemporal dimensions of community assembly

et al. 2022

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Ecological communities are assembled through a series of multiple processes, including dispersal, abiotic and biotic filtering, and ecological drift. Although these assembly processes act in concert to structure local communities, their relative importance is considerably variable among study systems. While such contingency of community assembly has been widely appreciated, the empirical and theoretical evidence is scattered around in the literature, and few efforts have been made to synthesize it. In this mini‐review, we summarize the accumulated evidence of the context‐dependency of community assembly rules, to reach a rough generalization of the contingency. Specifically, we argue that spatial and temporal dimensions can serve as general axes that regulate the relative importance of assembly processes. To this end, we synthesize the current understanding of how the relative importance of multiple assembly processes changes with spatial scales and complexity, and with time in the long and short terms. This review concludes that spatial and temporal dimensions can be common currencies of community assembly rules that are shared across various systems.

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Section: Temporal Dimensions Of Community Assemblymentioning

confidence: 97%

Spatiotemporal dimensions of community assembly

et al. 2022

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“…When we explore the global patterns of biodiversity, we need to consider spatiotemporal variation. Seasonal migratory fish appear in areas depending on the time of year and can alter biodiversity distribution patterns with the changing seasons [6][7][8] . In addition to migration, the incidence of vagrant fish that have migrated outside of their native range and are unlikely to persist and reproduce is thought to influence seasonal changes in biodiversity [9][10][11][12] .…”

Section: Introductionmentioning

confidence: 99%

“…However, a practical approach is the use of environmental DNA (eDNA), which refers to DNA shed into the environment by live, dead, or partially decomposed organisms containing DNA [14,15] . Recent developments in eDNA analysis have established the reliability of eDNA as a noninvasive, highly sensitive monitoring tool for diversity estimation and species composition, especially in aquatic ecosystems [8,[16][17][18] . A remarkable advantage of eDNA is the relatively low survey cost when compared with traditional capture-based survey methods for macro-organisms like fish, which enables us to collect more temporal and spatial frequencies in the field on larger scales [19] .…”

Section: Introductionmentioning

confidence: 99%

Large scale eDNA database reveals latitudinal diversity gradients with seasonal variations

Kasada

Shinohara

Fukasawa

et al. 2023

Preprint

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The spatial and temporal distribution patterns of marine organism diversity are crucial for the sustainable exploitation of fishery resources, management and preservation of marine ecosystems. We investigated the latitudinal diversity gradients of fish genera in Japanese waters using an environmental DNA (eDNA) survey. The environmental DNA data for 2111 surveys across Japan were obtained from the All Nippon eDNA Monitoring Network (ANEMONE) database. We observed a negative correlation between diversity and latitude in Japanese waters. The latitudinal gradient differed between seasons (correlation was especially negative in summer), suggesting that the seasonal change in the latitudinal gradient may be associated with the incidence of vagrant fish from tropical seas, and not the commonly observed pattern of seasonal migration (i.e., southwards in winter and northwards in summer). Furthermore, we found that global warming may lead to a temporary increase in biodiversity by increasing the incidence of vagrant fish from outside regions; however, this increase is not substantial. Although we did not find significant differences between years, further long-term and systematic monitoring may reveal temporal changes in marine biodiversity over longer time-periods, thus reflecting climate changes. Overall, the continued operation of ANEMONE will be the key to the future conservation of biodiversity in Japanese waters.

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“…Among other factors, species differences and spatial heterogeneity both have profound effects on beta-diversity. As well as spatial heterogeneity (Veech & Crist 2007; Báldi 2008; Jankowski et al 2009; Allouche et al 2012; Bar-Massada & Wood 2013; Heino et al 2013; Pomara et al 2013; Astorga et al 2014; Heino et al 2014; Bar-Massada 2015a,b; Royan et al 2015; Bar-Massada & Belmaker 2017; Zorzal-Almeida et al 2017; Ben-Hur & Kadmon 2020; Shinohara et al 2022), species differences can strongly influence beta-diversity. For example, dispersal mode (passive vs. active) and body size (small vs. large) are both strong determinants of beta-diversity patterns as revealed by meta-analyses (Soininen et al 2007; De Bie et al 2012).…”

Section: Introductionmentioning

confidence: 99%

“…2015; Bar-Massada & Belmaker 2017; Zorzal-Almeida et al . 2017; Ben-Hur & Kadmon 2020; Shinohara et al . 2022), species differences can strongly influence beta-diversity.…”

Section: Introductionmentioning

confidence: 99%

Jaccard dissimilarity in stochastic community models based on the species-independence assumption

Iritani

Ontiveros

Alonso

et al. 2022

Preprint

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Understanding how the spatial variation in species composition (beta-diversity) varies with biotic and abiotic conditions is one of the ultimate goals in biology. Theory predicts that beta-diversity is a consequence of two factors, species-level differences (defined as the variations among species in the probabilities that species are present in the landscape) and spatial heterogeneity (defined as the difference, between two sites, in the probabilities with which species are present). At present, however, the importance of each factor is unclear. Here, we take a probabilistic and combinatorial approach to examine the effects of species differences and spatial heterogeneity on the degree to which species assemblages in two spatial locations differ in species compositions. We first derived analytical and approximation formulae of the expectation and variance of the pairwise beta-diversity, based on the assumption that the presence probabilities of species are independent of each other. We found that, contrary to the intuitive claim that differences among species lead to greater beta-diversity, our method predicts that the reverse is also likely under some, though not all, circumstances. Strikingly, when space is homogeneous, beta-diversity decreases with species differences. This suggests that policy making for increasing species differences would, without the effort to maintaining environmental heterogeneity, induce biotic homogeneization. These findings suggest that maintaining beta-diversity as a conservation target may lead to undesired outcome unless species traits and environmental homogenization are monitored and adequately managed. Second, we illustrate our method using data from five woodpecker species in Switzerland, showing that the woodpecker species' joint distributions change considerably with time, and also that such changes are basically explained by the changes in the incidences of some of the species. The new framework can improve our understanding of how pairwise beta-diversity responds to species differences and spatial heterogeneity.

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Similar fish species composition despite larger environmental heterogeneity during severe hypoxia in a coastal ecosystem

Cited by 5 publications

References 77 publications

Spatiotemporal dimensions of community assembly

Spatiotemporal dimensions of community assembly

Large scale eDNA database reveals latitudinal diversity gradients with seasonal variations

Jaccard dissimilarity in stochastic community models based on the species-independence assumption

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