Your search keyword '"benthic organisms"' showing total 4 results

1. Active buoyancy adjustment increases dispersal potential in benthic marine animals.

Author

Hamel, Jean‐François, Sun, Jiamin, Gianasi, Bruno L., Montgomery, Emaline M., Kenchington, Ellen L., Burel, Benoit, Rowe, Sherrylynn, Winger, Paul D., Mercier, Annie, and Webb, Tom

Subjects

*BENTHIC animals, *BUOYANCY, *SEA cucumbers, *MICROCYSTIS, *MARINE animals, *ECHINODERMATA, *MAGNITUDE (Mathematics)

Abstract

While the study of dispersal and connectivity in the ocean typically centres on pelagic species and planktonic larval stages of benthic species, the present work explores an overlooked locomotor means in post‐settlement benthic stages that redefines their dispersal potential.Members of the echinoderm class Holothuroidea colonize a diversity of marine environments world‐wide, where they play key ecological and economical roles, making their conservation a priority. Holothuroids are commonly called sea cucumbers or sea slugs to reflect their slow movements and are assumed to disperse chiefly through pelagic larvae.The present study documents and explores their unexpected ability to actively modify their buoyancy, leading them to tumble or float at speeds orders of magnitudes faster than through benthic crawling. Two focal species representing different taxonomic orders, geographic distributions and reproductive strategies were studied over several years.Active buoyancy adjustment (ABA) was achieved through a rapid increase in water‐to‐flesh ratio by up to 740%, leading to bloating, and simultaneously detachment from the substrate. It occurred as early as 6 months post settlement in juveniles and was recorded in wild adult populations. In experimental trials, ABA was triggered by high conspecific density, decreasing salinity and increasing water turbidity. Based on field video footage, ABA‐assisted movements generated speeds of up to 90 km/day.These findings imply that displacement during planktonic larval stages may not supersede the locomotor capacity of benthic stages, challenging the notion of sedentarity. Combining the present results and anecdotal reports, ABA emerges as a generalized means of dispersal among benthic animals, with critical implications for world‐wide management and conservation of commercially and ecologically significant species. [ABSTRACT FROM AUTHOR]

Published

2019

2. Active buoyancy adjustment increases dispersal potential in benthic marine animals

Author

Bruno L. Gianasi, Ellen Kenchington, Benoit Burel, Paul D. Winger, Jean-François Hamel, Jiamin Sun, Sherrylynn Rowe, E. M. Montgomery, and Annie Mercier

Subjects

0106 biological sciences, Biology, 010603 evolutionary biology, 01 natural sciences, Sea cucumber, Animals, 14. Life underwater, dispersal, Ecology, Evolution, Behavior and Systematics, Behavioural Ecology, locomotor behaviour, marine organisms, Ecology, 010604 marine biology & hydrobiology, fungi, Pelagic zone, benthic organisms, Plankton, biology.organism_classification, Substrate (marine biology), Salinity, echinoderm, Echinoderm, Benthic zone, Larva, movement ecology, Biological dispersal, Animal Science and Zoology, sea cucumber, Research Article

Abstract

While the study of dispersal and connectivity in the ocean typically centres on pelagic species and planktonic larval stages of benthic species, the present work explores an overlooked locomotor means in post‐settlement benthic stages that redefines their dispersal potential.Members of the echinoderm class Holothuroidea colonize a diversity of marine environments world‐wide, where they play key ecological and economical roles, making their conservation a priority. Holothuroids are commonly called sea cucumbers or sea slugs to reflect their slow movements and are assumed to disperse chiefly through pelagic larvae.The present study documents and explores their unexpected ability to actively modify their buoyancy, leading them to tumble or float at speeds orders of magnitudes faster than through benthic crawling. Two focal species representing different taxonomic orders, geographic distributions and reproductive strategies were studied over several years.Active buoyancy adjustment (ABA) was achieved through a rapid increase in water‐to‐flesh ratio by up to 740%, leading to bloating, and simultaneously detachment from the substrate. It occurred as early as 6 months post settlement in juveniles and was recorded in wild adult populations. In experimental trials, ABA was triggered by high conspecific density, decreasing salinity and increasing water turbidity. Based on field video footage, ABA‐assisted movements generated speeds of up to 90 km/day.These findings imply that displacement during planktonic larval stages may not supersede the locomotor capacity of benthic stages, challenging the notion of sedentarity. Combining the present results and anecdotal reports, ABA emerges as a generalized means of dispersal among benthic animals, with critical implications for world‐wide management and conservation of commercially and ecologically significant species., This study documents the unexpected ability of so‐called sessile or sedentary benthic marine animals (e.g. sea cucumbers) to actively modify their buoyancy to tumble or float at speeds orders of magnitudes faster than anticipated. These findings redefine the locomotor capacity of benthic animals, challenging the notion of sedentarity, with critical implications for worldwide management and conservation of commercially and ecologically significant species.

Published

2019

3. A quantitative analysis of fishing impacts on shelf-sea benthos.

Author

Collie JS, Hall SJ, Kaiser MJ, and Poiner IR

Abstract

1. The effects of towed bottom-fishing gear on benthic communities is the subject of heated debate, but the generality of trawl effects with respect to gear and habitat types is poorly understood. To address this deficiency we undertook a meta-analysis of 39 published fishing impact studies. 2. Our analysis shows that inter-tidal dredging and scallop dredging have the greatest initial effects on benthic biota, while trawling has less effect. Fauna in stable gravel, mud and biogenic habitats are more adversely affected than those in less consolidated coarse sediments. 3. Recovery rate appears most rapid in these less physically stable habitats, which are generally inhabited by more opportunistic species. However, defined areas that are fished in excess of three times per year (as occurs in parts of the North Sea and Georges Bank) are likely to be maintained in a permanently altered state. 4. We conclude that intuition about how fishing ought to affect benthic communities is generally supported, but that there are substantial gaps in the available data, which urgently need to be filled. In particular, data on impacts and recovery of epifaunal structure-forming benthic communities are badly needed.

Published

2000

4. The Distribution of Benthic Invertebrates on Substrata in Fast-Flowing Streams

Author

Egglishaw, Henry J.

Published

1969