Data from: Assessing bottom-trawling impacts based on the longevity of benthic invertebrates

Hiddink, Jan Geert, Bangor University

Jennings, Simon, University of East Anglia

Sciberras, Marija, Bangor University

Bolam, Stefan, Centre for EnvironmentFisheries and Aquaculture ScienceLowestoft Laboratory Suffolk UK

Cambie, Giulia, Wageningen Marine ResearchWageningen UR IJmuiden The Netherlands

McConnaughey, Robert, Alaska Fisheries Science Center

Mazor, Tessa, Commonwealth Scientific and Industrial Research Organisation

Hilborn, Ray, University of Washington

Collie, Jeremy, University of Rhode Island

Pitcher, C. Roland, Commonwealth Scientific and Industrial Research Organisation

Parma, Ana, National Scientific and Technical Research Council

Suuronen, Petri, Fisheries and Aquaculture DepartmentFood and Agriculture Organisation of the United Nations Rome Italy

Kaiser, Michel, Bangor University

Rijnsdorp, Adriaan, Wageningen Marine ResearchWageningen UR IJmuiden The Netherlands

Collie, Jeremy S., University of Rhode Island

Kaiser, Michel J., Bangor University

Rijnsdorp, Adriaan D., Wageningen University & Research

McConnaughey, Robert A., Alaska Fisheries Science Center

Published Oct 01, 2018 on Dryad. https://doi.org/10.5061/dryad.426658h

Cite this dataset

Hiddink, Jan Geert et al. (2018). Data from: Assessing bottom-trawling impacts based on the longevity of benthic invertebrates [Dataset]. Dryad. https://doi.org/10.5061/dryad.426658h

Abstract

1. Bottom trawling is the most widespread human activity directly affecting seabed habitats. Assessment and effective management of the effects of bottom trawling at the scale of fisheries requires an understanding of differences in sensitivity of biota to trawling. Responses to disturbance are expected to depend on the intrinsic rate of increase of populations (r), which is expected to be linearly related to the reciprocal of longevity. 2. We examine the relationship between the longevity of benthic invertebrates and their response to bottom trawling; both in terms of the immediate mortality following a trawl pass and their subsequent rates of recovery. We collate all available data from experimental and comparative trawling studies, and test how longevity influences these aspects of sensitivity. 3. The shortest-lived organisms (<1yr) increased in abundance shortly after experimental trawling, but showed no response to trawling in longer-term comparative studies. Conversely, the abundance of biota with a life-span >1yr decreased by ~9% immediately following a trawl pass. The effect of bottom trawling in comparative studies increased with longevity, with a 2-3× larger effect on biota living >10yr than on biota living 1-3yr. We attribute this difference to the slower recovery rates of the longer-lived biota. 4. The observed relationship between the intrinsic rate of population increase (r, our metric of recovery rate) and the reciprocal of longevity matches theoretical expectation and predicts that the sensitivity of habitats to bottom trawling is higher in habitats with higher proportions of long-lived organisms. 5. Synthesis and Applications. Where the longevity of a species or the longevity distribution of a community is known or can be inferred, our estimates of depletion and intrinsic rate of increase can be combined with high-resolution maps of trawling intensity to assess trawling impacts at the scale of the fishery or other defined unit of assessment. Our estimates of r may also be used to estimate recovery times following other forms of seabed disturbance.06-Sep-2018

Usage notes

Fuzzy-coded longevity

Fuzzy-coded longevity for all taxa in the database, in four longevity classes (<1, 1-3, 3-10, and >10 years).

Longevity.traits.csv

Comparative trawl studies data

Data extracted in a systematic review of comparative bottom trawl studies The readme file gives a more detailed description of the headers.

Comparative.data.csv