Global change ecotoxicology: Identification of early life history bottlenecks in marine invertebrates, variable species responses and variable experimental approaches

Climate change is a threat to marine biota because increased atmospheric CO2 is causing ocean warming, acidification, hypercapnia and decreased carbonate saturation. These stressors have toxic effects on invertebrate development. The persistence and success of populations requires all ontogenetic st...

Full description

Saved in:
Bibliographic Details
Published in:Marine environmental research 2012-05, Vol.76, p.3-15
Main Author: Byrne, M.
Format: Article
Language:English
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
Animals
Aquatic Organisms
Biological and medical sciences
Climate change
Climatology. Bioclimatology. Climate change
Earth, ocean, space
Ecotoxicology
Exact sciences and technology
External geophysics
Fundamental and applied biological sciences. Psychology
Global Warming
Invertebrate life histories
Invertebrates - physiology
Life Cycle Stages
Meteorology
Ocean acidification
Ocean warming
Oceans and Seas
Population Dynamics
Sea water ecosystems
Stress, Physiological
Synecology
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Climate change is a threat to marine biota because increased atmospheric CO2 is causing ocean warming, acidification, hypercapnia and decreased carbonate saturation. These stressors have toxic effects on invertebrate development. The persistence and success of populations requires all ontogenetic stages be completed successfully and, due to their sensitivity to environmental stressors, developmental stages may be a population bottleneck in a changing ocean. Global change ecotoxicology is being used to identify the marine invertebrate developmental stages vulnerable to climate change. This overview of research, and the methodologies used, shows that most studies focus on acidification, with few studies on ocean warming, despite a long history of research on developmental thermotolerance. The interactive effects of stressors are poorly studied. Experimental approaches differ among studies. Fertilization in many species exhibits a broad tolerance to warming and/or acidification, although different methodologies confound inter-study comparisons. Early development is susceptible to warming and most calcifying larvae are sensitive to acidification/increased pCO2. In multistressor studies moderate warming diminishes the negative impact of acidification on calcification in some species. Development of non-calcifying larvae appears resilient to near-future ocean change. Although differences in species sensitivities to ocean change stressors undoubtedly reflect different tolerance levels, inconsistent handling of gametes, embryos and larvae probably influences different research outcomes. Due to the integrative ‘developmental domino effect’, life history responses will be influenced by the ontogenetic stage at which experimental incubations are initiated. Exposure to climate change stressors from early development (fertilization where possible) in multistressor experiments is needed to identify ontogenetic sensitivities and this will be facilitated by more consistent methodologies. ► Climate change studies of marine invertebrates use variable methodologies. ► Fertilization in many marine invertebrates is robust to ocean change stressors. ► Early embryos appear most susceptible to warming. ► Calcifying larvae are susceptible to acidification. ► Variable species responses may be influenced by different methodologies.
ISSN:0141-1136
1879-0291
DOI:10.1016/j.marenvres.2011.10.004