Variation of amphipod assemblage along the Sargassum stenophyllum (Phaeophyta, Fucales) thallus

Machado, Glauco; Neufeld, Aline Binato; Dena, Simone; Siqueira, Silvana Gomes Leite; Leite, Fosca Pedini Pereira

doi:10.1590/s0104-64972015002310

Cited by 12 publications

(7 citation statements)

References 29 publications

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“…Although different to previous feeding trials because of the incorporation of time-since-invasion, the present study also supports the ERH. These apparently contradictory conclusions may be the result of animals moving into S. muticum stands during the day for protection against visual predators, but then returning to native alga to feed during the night (Buschmann, 1990; Machado et al ., 2015). Alternatively, grazers on S. muticum could be feeding mainly on epiphytic material and detritus in the field (Viejo, 1999; Cacabelos et al ., 2010b), and may therefore avoid S. muticum under laboratory conditions due to experimental removal of epiphytes or the selection of individuals that are relatively epiphyte free.…”

Section: Discussionmentioning

confidence: 99%

Time-since-invasion increases native mesoherbivore feeding rates on the invasive alga, Sargassum muticum (Yendo) Fensholt

Kurr

Davies²

2017

J. Mar. Biol. Ass.

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Peer reviewed versionCyswllt i'r cyhoeddiad / Link to publication Dyfyniad o'r fersiwn a gyhoeddwyd / Citation for published version (APA): Kurr, M., & Davies, A. J. (2018). Time-since-invasion increases native mesoherbivore feeding rates on the invasive alga, Sargassum muticum (Yendo) Fensholt. Abstract 17 18Invasive algae can have substantial negative impacts in their invaded ranges. One widely-19 cited mechanism that attempts to explain how invasive plants and algae are often able to 20 spread quickly, and even become dominant in their invaded ranges, is the Enemy Release 21 Hypothesis. This study assessed the feeding behaviours of two species of gastropod herbivore 22 from populations exposed to the invasive alga Sargassum muticum for different lengths of 23 time. Feeding-trials, consisting of both choice and no-choice, showed that the herbivores 24 from older stands (35-40 years established) of S. muticum were more likely to feed upon it 25 than those taken from younger (10-19 years established) stands. These findings provide 26 evidence in support of the ERH, by showing that herbivores consumed less S. muticum if they 27 were not experienced with it. These findings are in accordance with the results of other 28 feeding-trials with S. muticum, but in contrast to research that utilises observations of 29 herbivore abundance and diversity to assess top-down pressure. The former tend to validate 30 the ERH, and the latter typically reject it. The potential causes of this disparity are discussed, 31 as are the importance of palatability, herbivore species, and time-since-invasion when 32 considering research into the ERH. This study takes an important, yet neglected, approach to 33 the study of invasive ecology. 34 35

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Section: Discussionmentioning

confidence: 99%

Time-since-invasion increases native mesoherbivore feeding rates on the invasive alga, Sargassum muticum (Yendo) Fensholt

Kurr

Davies²

2017

J. Mar. Biol. Ass.

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“…Boström & Mattila, 1999;Tait & Hovel, 2012) to avoid predators, such as Palaemon serratus which were abundant in most stands of S. muticum in this study. If many grazer species found on S. muticum are not feeding on it, but are instead using it for shelter (Machado et al, 2015) or feeding solely on its epiphytes (Viejo, 1999;Cacabelos et al, 2010b) this would explain why the 'sampling effect' applies in this instance. Due to their small size, the probability that the individuals of any one grazer species were feeding directly on S. muticum tissues is likely much lower than if these individuals were adults.…”

Section: Discussionmentioning

confidence: 99%

“…Likewise, many grazers could be feeding principally on the epiphytes of S. muticum (Viejo, 1999;Cacabelos et al, 2010b) or exploiting its fronds for shelter (e.g. Machado et al, 2015). Surprisingly few studies include diversity of local grazers when examining the impacts on invasive plants and algae (Kimbro et al, 2013), and little is known about how grazer diversity might impact a species such as S. muticum.…”

Section: Introductionmentioning

confidence: 99%

The chemical defences of the invasive alga Sargassum muticum (Yendo) Fensholt correlate to mesoherbivore diversity, but not to time-since-invasion

Kurr

Davies

2019

Hydrobiologia

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Populations of the invasive alga Sargassum muticum were sampled along a time-sinceinvasion (TSI) gradient to test the hypothesis that chemical defences would increase with TSI, and diversity of native mesoherbivores. Algal chemical defences, phlorotannins, were quantified as a proxy for top-down-pressure, and these were compared with both native enemy diversity and time-since-invasion at each of seven sites along the west coast of the UK. The defences in the annual fronds showed a strong positive correlation with the biodiversity of native mesoherbivores. The defences in the perennial holdfasts, whilst generally higher than those in the fronds, showed no relationship. In contrast, defences in neither the fronds nor the holdfasts showed any relationship with TSI. The majority of mesoherbivores found in this survey were small and probably juvenile. Many of these individuals are known to occupy the fronds of S. muticum for shelter or to feed on its epiphytes, and are probably less likely to feed directly on its tissues than adults. The low probability that any one species of grazer was feeding on S. muticum tissues may explain why the alga contained a greater level of phlorotannin when the diversity of potential enemies was high. This study highlights the importance of enemy diversity in invasion ecology.

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“…Our assumption that zooplankton can graze on macroalgae is based on the notion that the marine biogeochemical component of "zooplankton" in UVic ESCM represents all higher trophic levels, including known macroalgae grazers such as amphipods (Jacobucci et al, 2008), gastropods (Chikaraishi et al, 2007;Krumhansl and Scheibling, 2011), sea urchins (e.g., Yatsuya et al, 2020) and fishes (e.g., Peteiro et al, 2014). Thus, we included this food web pathway to assess the sensitivity of macroalgae to potential grazers in the ocean, assuming that with large macroalgae farms the pelagic larvae of some grazing organisms like fish or urchins would settle within the farms.…”

Section: Interactions With Pelagic Microbial Ecosystemsmentioning

confidence: 99%

Carbon dioxide removal via macroalgae open-ocean mariculture and sinking: an Earth system modeling study

Keller

Oschlies

2023

Earth Syst. Dynam.

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Abstract. In this study, we investigate the maximum physical and biogeochemical potential of macroalgae open-ocean mariculture and sinking (MOS) as an ocean-based carbon dioxide removal (CDR) method. Embedding a macroalgae model into an Earth system model, we simulate macroalgae mariculture in the open-ocean surface layer followed by fast sinking of the carbon-rich macroalgal biomass to the deep seafloor (depth>3000 m), which assumes no remineralization of the harvested biomass during the quick sinking. We also test the combination of MOS with artificial upwelling (AU), which fertilizes the macroalgae by pumping nutrient-rich deeper water to the surface. The simulations are done under RCP 4.5, a moderate-emissions pathway. When deployed globally between years 2020 and 2100, the carbon captured and exported by MOS is 270 PgC, which is further boosted by AU of 447 PgC. Because of feedbacks in the Earth system, the oceanic carbon inventory only increases by 171.8 PgC (283.9 PgC with AU) in the idealized simulations. More than half of this carbon remains in the ocean after cessation at year 2100 until year 3000. The major side effect of MOS on pelagic ecosystems is the reduction of phytoplankton net primary production (PNPP) due to the competition for nutrients with macroalgae and due to canopy shading. MOS shrinks the mid-layer oxygen-minimum zones (OMZs) by reducing the organic matter export to, and remineralization in, subsurface and intermediate waters, while it creates new OMZs on the seafloor by oxygen consumption from remineralization of sunken biomass. MOS also impacts the global carbon cycle by reducing the atmospheric and terrestrial carbon reservoirs when enhancing the ocean carbon reservoir. MOS also enriches dissolved inorganic carbon in the deep ocean. Effects are mostly reversible after cessation of MOS, though recovery is not complete by year 3000. In a sensitivity experiment without remineralization of sunken MOS biomass, the whole of the MOS-captured carbon is permanently stored in the ocean, but the lack of remineralized nutrients causes a long-term nutrient decline in the surface layers and thus reduces PNPP. Our results suggest that MOS has, theoretically, considerable CDR potential as an ocean-based CDR method. However, our simulations also suggest that such large-scale deployment of MOS would have substantial side effects on marine ecosystems and biogeochemistry, up to a reorganization of food webs over large parts of the ocean.

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Variation of amphipod assemblage along the Sargassum stenophyllum (Phaeophyta, Fucales) thallus

Cited by 12 publications

References 29 publications

Time-since-invasion increases native mesoherbivore feeding rates on the invasive alga, Sargassum muticum (Yendo) Fensholt

Time-since-invasion increases native mesoherbivore feeding rates on the invasive alga, Sargassum muticum (Yendo) Fensholt

The chemical defences of the invasive alga Sargassum muticum (Yendo) Fensholt correlate to mesoherbivore diversity, but not to time-since-invasion

Carbon dioxide removal via macroalgae open-ocean mariculture and sinking: an Earth system modeling study

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