Variable temperature stress in the nematode Caenorhabditis elegans (Maupas) and its implications for sensitivity to an additional chemical stressor

Nina Cedergreen; Nils Jakob Nørhave; Claus Svendsen; David J. Spurgeon

Variable temperature stress in the nematode Caenorhabditis elegans (Maupas) and its implications for sensitivity to an additional chemical stressor

Nina Cedergreen, Nils Jakob Nørhave, Claus Svendsen, David J. Spurgeon

Miljøkemi

14 Citationer (Scopus)

167 Downloads (Pure)

Abstract

A wealth of studies has investigated how chemical sensitivity is affected by temperature, however, almost always under different constant rather than more realistic fluctuating regimes. Here we compared how the nematode Caenorhabditis elegans responds to copper at constant temperatures (8â€"24Â°C) and under fluctuation conditions of low (Â±4Â°C) and high (Â±8Â°C) amplitude (averages of 12, 16, 20Â°C and 16Â°C respectively). The DEBkiss model was used to interpret effects on energy budgets. Increasing constant temperature from 12â€"24Â°C reduced time to first egg, life-span and population growth rates consistent with temperature driven metabolic rate change. Responses at 8Â°C did not, however, accord with this pattern (including a deviation from the Temperature Size Rule), identifying a cold stress effect. High amplitude variation and low amplitude variation around a mean temperature of 12Â°C impacted reproduction and body size compared to nematodes kept at the matching average constant temperatures. Copper exposure affected reproduction, body size and life-span and consequently population growth. Sensitivity to copper (EC50 values), was similar at intermediate temperatures (12, 16, 20Â°C) and higher at 24Â°C and especially the innately stressful 8Â°C condition. Temperature variation did not increase copper sensitivity. Indeed under variable conditions including time at the stressful 8Â°C condition, sensitivity was reduced. DEBkiss identified increased maintenance costs and increased assimilation as possible mechanisms for cold and higher copper concentration effects. Model analysis of combined variable temperature effects, however, demonstrated no additional joint stressor response. Hence, concerns that exposure to temperature fluctuations may sensitise species to co-stressor effects seem unfounded in this case.

Originalsprog	Engelsk
Artikelnummer	e0140277
Tidsskrift	P L o S One
Vol/bind	11
Udgave nummer	1
Antal sider	21
ISSN	1932-6203
Status	Udgivet - 1 jan. 2016

Adgang til dokumentet

Cedergreen et al, 2016_Variable tempForlagets udgivne version, 1,19 MB
Variable Temperature Stress in the Nematode Caenorhabditis elegans (Maupas) and Its Implications for Sensitivity to an Additional Chemical StressorForlagets udgivne version, 1,2 MB

Citationsformater

@article{ae81182bdfb047f3ad04ceb4c14a64ca,

title = "Variable temperature stress in the nematode Caenorhabditis elegans (Maupas) and its implications for sensitivity to an additional chemical stressor",

abstract = "A wealth of studies has investigated how chemical sensitivity is affected by temperature, however, almost always under different constant rather than more realistic fluctuating regimes. Here we compared how the nematode Caenorhabditis elegans responds to copper at constant temperatures (8{\^a}€{"}24{\^A}°C) and under fluctuation conditions of low ({\^A}±4{\^A}°C) and high ({\^A}±8{\^A}°C) amplitude (averages of 12, 16, 20{\^A}°C and 16{\^A}°C respectively). The DEBkiss model was used to interpret effects on energy budgets. Increasing constant temperature from 12{\^a}€{"}24{\^A}°C reduced time to first egg, life-span and population growth rates consistent with temperature driven metabolic rate change. Responses at 8{\^A}°C did not, however, accord with this pattern (including a deviation from the Temperature Size Rule), identifying a cold stress effect. High amplitude variation and low amplitude variation around a mean temperature of 12{\^A}°C impacted reproduction and body size compared to nematodes kept at the matching average constant temperatures. Copper exposure affected reproduction, body size and life-span and consequently population growth. Sensitivity to copper (EC50 values), was similar at intermediate temperatures (12, 16, 20{\^A}°C) and higher at 24{\^A}°C and especially the innately stressful 8{\^A}°C condition. Temperature variation did not increase copper sensitivity. Indeed under variable conditions including time at the stressful 8{\^A}°C condition, sensitivity was reduced. DEBkiss identified increased maintenance costs and increased assimilation as possible mechanisms for cold and higher copper concentration effects. Model analysis of combined variable temperature effects, however, demonstrated no additional joint stressor response. Hence, concerns that exposure to temperature fluctuations may sensitise species to co-stressor effects seem unfounded in this case.",

author = "Nina Cedergreen and N{\o}rhave, {Nils Jakob} and Claus Svendsen and Spurgeon, {David J.}",

year = "2016",

month = jan,

day = "1",

language = "English",

volume = "11",

journal = "P L o S One",

issn = "1932-6203",

publisher = "Public Library of Science",

number = "1",

}

TY - JOUR

T1 - Variable temperature stress in the nematode Caenorhabditis elegans (Maupas) and its implications for sensitivity to an additional chemical stressor

AU - Cedergreen, Nina

AU - Nørhave, Nils Jakob

AU - Svendsen, Claus

AU - Spurgeon, David J.

PY - 2016/1/1

Y1 - 2016/1/1

N2 - A wealth of studies has investigated how chemical sensitivity is affected by temperature, however, almost always under different constant rather than more realistic fluctuating regimes. Here we compared how the nematode Caenorhabditis elegans responds to copper at constant temperatures (8â€"24Â°C) and under fluctuation conditions of low (Â±4Â°C) and high (Â±8Â°C) amplitude (averages of 12, 16, 20Â°C and 16Â°C respectively). The DEBkiss model was used to interpret effects on energy budgets. Increasing constant temperature from 12â€"24Â°C reduced time to first egg, life-span and population growth rates consistent with temperature driven metabolic rate change. Responses at 8Â°C did not, however, accord with this pattern (including a deviation from the Temperature Size Rule), identifying a cold stress effect. High amplitude variation and low amplitude variation around a mean temperature of 12Â°C impacted reproduction and body size compared to nematodes kept at the matching average constant temperatures. Copper exposure affected reproduction, body size and life-span and consequently population growth. Sensitivity to copper (EC50 values), was similar at intermediate temperatures (12, 16, 20Â°C) and higher at 24Â°C and especially the innately stressful 8Â°C condition. Temperature variation did not increase copper sensitivity. Indeed under variable conditions including time at the stressful 8Â°C condition, sensitivity was reduced. DEBkiss identified increased maintenance costs and increased assimilation as possible mechanisms for cold and higher copper concentration effects. Model analysis of combined variable temperature effects, however, demonstrated no additional joint stressor response. Hence, concerns that exposure to temperature fluctuations may sensitise species to co-stressor effects seem unfounded in this case.

AB - A wealth of studies has investigated how chemical sensitivity is affected by temperature, however, almost always under different constant rather than more realistic fluctuating regimes. Here we compared how the nematode Caenorhabditis elegans responds to copper at constant temperatures (8â€"24Â°C) and under fluctuation conditions of low (Â±4Â°C) and high (Â±8Â°C) amplitude (averages of 12, 16, 20Â°C and 16Â°C respectively). The DEBkiss model was used to interpret effects on energy budgets. Increasing constant temperature from 12â€"24Â°C reduced time to first egg, life-span and population growth rates consistent with temperature driven metabolic rate change. Responses at 8Â°C did not, however, accord with this pattern (including a deviation from the Temperature Size Rule), identifying a cold stress effect. High amplitude variation and low amplitude variation around a mean temperature of 12Â°C impacted reproduction and body size compared to nematodes kept at the matching average constant temperatures. Copper exposure affected reproduction, body size and life-span and consequently population growth. Sensitivity to copper (EC50 values), was similar at intermediate temperatures (12, 16, 20Â°C) and higher at 24Â°C and especially the innately stressful 8Â°C condition. Temperature variation did not increase copper sensitivity. Indeed under variable conditions including time at the stressful 8Â°C condition, sensitivity was reduced. DEBkiss identified increased maintenance costs and increased assimilation as possible mechanisms for cold and higher copper concentration effects. Model analysis of combined variable temperature effects, however, demonstrated no additional joint stressor response. Hence, concerns that exposure to temperature fluctuations may sensitise species to co-stressor effects seem unfounded in this case.

M3 - Journal article

SN - 1932-6203

VL - 11

JO - P L o S One

JF - P L o S One

IS - 1

M1 - e0140277

ER -

Variable temperature stress in the nematode Caenorhabditis elegans (Maupas) and its implications for sensitivity to an additional chemical stressor

Abstract

Adgang til dokumentet

Fingeraftryk

Citationsformater