Locomotory activity and feeding strategy of the hadal munnopsid isopod <i>Rectisura</i> cf. <i>herculea</i> (Crustacea: Asellota) in the Japan Trench

Jamieson, Alan J.; Fujii, Toyonobu; Priede, Imants George

doi:10.1242/jeb.067025

Cited by 11 publications

(14 citation statements)

References 39 publications

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“…Jamieson et al . () also reported a single individual R. herculea with a high size‐specific speed of 0.33 cms −1 BL −1 relative to the mean 0.19 cms −1 BL −1 . This particular specimen accelerated to 1.2 cms −1 as an aversion response in the presence of a fish, as shown in Figure (Jamieson et al .…”

Section: Resultsmentioning

confidence: 89%

“…5 min; or an anaerobic threshold speed, sustainable for between 20 and 60 min (see foregoing discussion on the ‘power profile’) for R. herculea (but not a maximum explosive speed, for which Jamieson et al . () reported considerably higher backward jump escape speeds). From this aversion response speed, we approximated a scaled corresponding maximal sustainable aerobic power, or anaerobic threshold, speed for T. chopini .…”

Section: Resultsmentioning

confidence: 95%

“…This particular specimen accelerated to 1.2 cms −1 as an aversion response in the presence of a fish, as shown in Figure (Jamieson et al . ). We consider this aversion response to be within mid‐range sustainable capacities described as a maximal sustainable aerobic speed, sustainable for c .…”

Section: Resultsmentioning

confidence: 97%

“…We used data from Jamieson et al . (), illustrated in Figure , for R . herculea , a living crustacean with a body length between 2.5 and 5 times that of T. chopini , to derive an approximate range of speeds for T. chopini for a range of body lengths (BL).…”

Section: Resultsmentioning

confidence: 99%

“… Estimated maximal sustainable walking speed trilobites of varying body length, scaled according to aversion response size‐specific speed of 0.33 cms −1 BL −1 from Jamieson et al . () for the extant crustacean, R. herculea . …”

Section: Resultsmentioning

confidence: 99%

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Trilobite ‘pelotons’: possible hydrodynamic drag effects between leading and following trilobites in trilobite queues

2017

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Energy saving mechanisms in nature allow following organisms to expend less energy than leaders. Queues, or ordered rows of individuals, may form when organisms exploit the available energy saving mechanism while travelling at near-maximal sustainable metabolic capacities; compact clusters form when group members travel well below maximal sustainable metabolic capacities. The group size range, given here as the ratio of the difference between the size of the largest and smallest group members, and the size of the largest member (as a per cent), has been hypothesized to correspond proportionately to the energy saving quantity because weaker, smaller, individuals sustain speeds of stronger, larger, individuals by exploiting the energy saving mechanism (as a per cent). During migration, small individuals outside this range may perish, or form sub-groups, or simply not participate in migratory behavior. We approximate drag forces for leading and following individuals in queues of the late Devonian (~370 Ma) trilobite Trimerocephalus chopini. Applying data from literature of R. herculea, a living crustacean, we approximate the hypothetical walking speed and maximal speeds for T. chopini. Findings reasonably support the hypothesis: among the population of fossilized queues of T. chopini reported by Kin & Błażejowski (2013), trilobite size range was 75% while the size range within queues, was 63%; this corresponds reasonably with drag reductions in following positions that permit ~61.5% energy saving for trilobites following others in optimal low-drag positions. We model collective trilobite behavior associated with hydrodynamic drafting.

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Section: Resultsmentioning

confidence: 89%

Section: Resultsmentioning

confidence: 95%

Section: Resultsmentioning

confidence: 97%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Trilobite ‘pelotons’: possible hydrodynamic drag effects between leading and following trilobites in trilobite queues

2017

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Scientific and technological progress in the microbial exploration of the hadal zone

Fan

Wang

Ding

et al. 2021

Mar Life Sci Technol

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The hadal zone is the deepest point in the ocean with a depth that exceeds 6000 m. Exploration of the biological communities in hadal zone began in the 1950s (the first wave of hadal exploration) and substantial advances have been made since the turn of the twenty-first century (the second wave of hadal exploration), resulting in a focus on the hadal sphere as a research hotspot because of its unique physical and chemical conditions. A variety of prokaryotes are found in the hadal zone. The mechanisms used by these prokaryotes to manage the high hydrostatic pressures and acquire energy from the environment are of substantial interest. Moreover, the symbioses between microbes and hadal animals have barely been studied. In addition, equipment has been developed that can now mimic hadal environments in the laboratory and allow cultivation of microbes under simulated in situ pressure. This review provides a brief summary of recent progress in the mechanisms by which microbes adapt to high hydrostatic pressures, manage limited energy resources and coexist with animals in the hadal zone, as well as technical developments in the exploration of hadal microbial life.

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Abyssal Scavenging Communities attracted to Sargassum and fish in the Sargasso Sea

Fleury

Drazen

2013

Deep Sea Research Part I: Oceanographic Research Papers

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Locomotory activity and feeding strategy of the hadal munnopsid isopod Rectisura cf. herculea (Crustacea: Asellota) in the Japan Trench

Cited by 11 publications

References 39 publications

Trilobite ‘pelotons’: possible hydrodynamic drag effects between leading and following trilobites in trilobite queues

Trilobite ‘pelotons’: possible hydrodynamic drag effects between leading and following trilobites in trilobite queues

Scientific and technological progress in the microbial exploration of the hadal zone

Abyssal Scavenging Communities attracted to Sargassum and fish in the Sargasso Sea

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