Feeding Activity and Xenobiotics Modulate Oxidative Status in

Sep 23, 2014 - Daphnia magna: Implications for Ecotoxicological Testing ... xenobiotics on oxidative biomarkers in Daphnia magna. Antioxidant capacity...
1 downloads 0 Views 885KB Size
Subscriber access provided by University of Newcastle, Australia

Article

Feeding activity and xenobiotics modulate oxidative status in Daphnia magna: implications for ecotoxicological testing Sara Furuhagen, Birgitta Liewenborg, Magnus Breitholtz, and Elena Gorokhova Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/es5044722 • Publication Date (Web): 23 Sep 2014 Downloaded from http://pubs.acs.org on September 28, 2014

Just Accepted “Just Accepted” manuscripts have been peer-reviewed and accepted for publication. They are posted online prior to technical editing, formatting for publication and author proofing. The American Chemical Society provides “Just Accepted” as a free service to the research community to expedite the dissemination of scientific material as soon as possible after acceptance. “Just Accepted” manuscripts appear in full in PDF format accompanied by an HTML abstract. “Just Accepted” manuscripts have been fully peer reviewed, but should not be considered the official version of record. They are accessible to all readers and citable by the Digital Object Identifier (DOI®). “Just Accepted” is an optional service offered to authors. Therefore, the “Just Accepted” Web site may not include all articles that will be published in the journal. After a manuscript is technically edited and formatted, it will be removed from the “Just Accepted” Web site and published as an ASAP article. Note that technical editing may introduce minor changes to the manuscript text and/or graphics which could affect content, and all legal disclaimers and ethical guidelines that apply to the journal pertain. ACS cannot be held responsible for errors or consequences arising from the use of information contained in these “Just Accepted” manuscripts.

Environmental Science & Technology is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

Page 1 of 24

Environmental Science & Technology

1

Feeding activity and xenobiotics modulate oxidative status in

2

Daphnia magna: implications for ecotoxicological testing

3

Sara Furuhagen*, Birgitta Liewenborg, Magnus Breitholtz and Elena Gorokhova

4 5

Department of Applied Environmental Science, Stockholm University, Svante Arrhenius väg 8, 106 91 Stockholm, Sweden

6

*Corresponding author:

7

Sara Furuhagen

8 9

Department of Applied Environmental Science, Stockholm University, Svante Arrhenius väg 8, 106 91 Stockholm, Sweden

10

+46 8 674 72 79

11

[email protected]

12

13

14

15

16

17

18

19

20

21

22 1 ACS Paragon Plus Environment

Environmental Science & Technology

23

ABSTRACT

24

To apply biomarkers of oxidative stress in laboratory and field settings, an understanding of

25

their responses to changes in physiological rates is important. The evidence is accumulating

26

that caloric intake can increase production of reactive oxygen species and thus affect

27

background variability of oxidative stress biomarkers in ecotoxicological testing. This study

28

aimed to delineate effects of food intake and xenobiotics on oxidative biomarkers in Daphnia

29

magna. Antioxidant capacity measured as ORAC (oxygen radical absorbance capacity) and

30

lipid peroxidation assayed as TBARS (thiobarbituric acid reactive substances) were measured.

31

Food intake was manipulated by varying food densities or by exposing the animals to

32

chemicals inhibiting feeding rate (pharmaceutical haloperidol and pesticide lindane). Feeding

33

rate proved to affect both protein, ORAC and TBARS in unexposed daphnids. However, there

34

was no significant effect of feeding rate on the protein-specific ORAC values. Both

35

substances affected individual protein and ORAC levels and changed their relationship to

36

feeding rate. Our results show that inhibition of feeding rate influenced the interpretation of

37

biomarker response and further emphasize the importance of understanding (1) baseline

38

variability in potential biomarkers due to variations in metabolic state, and (2) the

39

contribution of feeding rate on toxic response of biomarkers.

40

41

42

43

44

45 2 ACS Paragon Plus Environment

Page 2 of 24

Page 3 of 24

Environmental Science & Technology

46

INTRODUCTION

47

To counteract pro-oxidative processes in aerobic organisms, homeostasis is maintained

48

between the cellular production of reactive oxygen species (ROS) and the endogenous

49

antioxidant defense. The balance between ROS production and the antioxidant defense can be

50

affected by physiological factors, such as age and disease1 as well as by environmental

51

factors, such as hypoxia2 and pollutants3. Caloric restriction (CR) has been identified as an

52

important factor affecting the cellular production of ROS as low-calorie diets hamper ROS

53

production4. Studies on isolated rat mitochondria showed that CR results in decreased

54

substrate oxidation activity, leading to lowered mitochondrial membrane potential and

55

increased proton leakage and thus a diminished generation of ROS5. This effect appears to be

56

a general mechanism as the effects of CR have been shown for a variety of species6. As an

57

excess of ROS can be harmful to DNA, lipids and proteins7, the levels of oxidative damages

58

on these biomolecules have been found to be lower in animals given a CR diet6.

59

Chemical substances can affect cellular ROS concentrations through different mechanisms.

60

Pro-oxidative substances can increase generation of ROS and other radicals by entering redox

61

cycles8, but ROS production can be also induced by increasing metabolic rate as a response to

62

stress or through induction of enzymes involved in xenobiotic metabolism, such as CYP450

63

and NAD(P)H9. Moreover, the oxidative homeostasis can be disrupted by depletion of

64

antioxidative substances in xenobiotic metabolism7, 9. Consequently, biomarkers of oxidative

65

stress are widely used in ecotoxicology and ecology as indicators of stressful conditions10,

66

although specific causes of the observed biochemical alterations are not always identifiable

67

because of the plethora of factors that may affect the oxidative status of organisms. Therefore,

68

to facilitate biomarker application and interpretation of measured responses to stress factors,

69

we need to understand the magnitude and causes of background variability for the biomarker

70

of interest11. In particular, variability in feeding rate has a high potential to affect biomarkers 3 ACS Paragon Plus Environment

Environmental Science & Technology

71

of oxidative stress, because of the effect of caloric intake on the production of ROS. Feeding

72

rate is a sensitive and ecologically relevant end point in ecotoxicological assays as exposure

73

to a wide range of substances has been reported to cause feeding inhibition in various test

74

species12-13. In stress assessment, feeding inhibition assay proved to be about 50-fold more

75

sensitive than standardized acute ecotoxicological assays employing survival as an end

76

point14. Moreover, although effects of ad libitum feeding on many endpoints have been

77

identified as a serious methodological issue in tests with vertebrates15-17, no attempt has been

78

made so far to study the effects of feeding rate and xenobiotic exposure on oxidative

79

biomarkers in invertebrates. The objectives of this study were to (1) establish relationships

80

between feeding rate and oxidative biomarkers in Daphnia magna and (2) understand the

81

contribution of variation in feeding rate to toxic response.

82

Two model substances, haloperidol and lindane, were used to address these objectives.

83

Haloperidol is a dopamine receptor antagonist that has been found to cause feeding inhibition

84

in rats by blocking hunger perception18; and it has indeed been found to cause feeding

85

inhibition in D. magna (Furuhagen, unpubl. data). Lindane is a neurotoxic insecticide19 that

86

has been shown to inhibit feeding in daphnids by reducing the movement of filtering limbs12,

87

20-21

88

varying food levels in the absence of a toxic compound or to varying substance concentrations

89

at a constant food level. As proxies for antioxidant capacity and oxidative damage we assayed

90

oxygen radical absorbance capacity (ORAC) and lipid peroxidation levels measured as

91

thiobarbituric acid reactive substances (TBARS). Both biomarkers have been used before to

92

assess oxidative stress in microcrustaceans, including daphnids22-23. Two sets of hypotheses

93

were tested with regard to the effects of food intake and chemical exposure in this study. We

94

hypothesized that individual protein content will be positively related to feeding rate in the

95

unexposed daphnids (Hypothesis 1), due to increased protein synthetic activity at higher food

. In our study, we manipulated feeding activity in daphnids by exposing them to either

4 ACS Paragon Plus Environment

Page 4 of 24

Page 5 of 24

Environmental Science & Technology

96

intake. Moreover, the oxidative biomarkers will be positively related to the increase in protein

97

content of animals feeding at higher rates and thus having higher ROS production (Hypothesis

98

2). In addition to feeding inhibition and corresponding effects on the biomarker response, the

99

exposure to toxicants was hypothesized to have effects on the relationships between feeding

100

rate and protein allocation, and between protein content and oxidative biomarkers. In

101

particular, a negative effect on individual protein content was expected in the haloperidol-

102

exposed daphnids, whereas lindane was hypothesized to have a positive effect on the protein

103

content. The rationale for this expectation was based on the reported negative effect of

104

haloperidol on the expression of heat shock proteins (hsp)24 and the induction of hsp after

105

lindane exposure25 (Hypothesis 3). An increase in oxidative damage, independent of feeding

106

rates, was expected in exposed daphnids, whereas the antioxidant capacity could be both

107

positively and negatively affected by xenobiotics depending on the stress levels (Hypothesis

108

4).

109

110

METHODS

111

Test organism

112

The daphnids originated from a single clone (environmental pollution test strain Klon 5, the

113

State office for nature, environment, and customer protection North-Rhine Westfalia, Bonn,

114

Germany; originally from the Federal Environment Agency, Berlin, Germany). They were

115

cultured in 2 L M7 medium (OECD standard 202 and 211) at a stock density of ~20

116

individuals in each beaker and fed three times a week with a mixture of Pseudokirchneriella

117

subcapitata and Scenedesmus subspicatus.

118

5 ACS Paragon Plus Environment

Environmental Science & Technology

Page 6 of 24

119

Functional response experiments

120

Using varying densities of algal suspension we manipulated daphnid feeding rate. The

121

individuals feeding at varying rates were also used to measure individual protein content,

122

ORAC (Experiment I and II), and TBARS (Experiment II) (Table 1). The feeding rate of

123

juvenile daphnids (96 h old) as a function of food density was measured in M7 medium with 5

124

daphnids in each replicate. Fluorescence of the algae was measured using Turner designs 10-

125

AU Fluorometer at the start of the test and after 24 h to assess the feeding rate of the

126

daphnids. All experiments were conducted in darkness, at 20˚C to minimize algal growth

127

during the incubation. An additional replicate without daphnids served as a control to assess

128

algal growth. Incubation for ORAC and TBARS measurements (Experiment II) was done

129

using starved animals and those incubated at the intermediate food concentration (1.5 µg C

130

mL-1) and at the near-saturation concentration (7 µg C mL-1).

131

132

Feeding inhibition tests

133

Feeding inhibition tests (haloperidol: Experiment III and lindane: Experiment V; test

134

conditions as in Experiment I) were performed according to Barata, et al.

135

modifications. In these experiments, feeding rate was measured at a constant food

136

concentration (1.5 µg C mL-1) and the animals were used for measurements of individual

137

protein content and ORAC. Exposure for TBARS and ORAC (Experiments IV and VI for

138

haloperidol and lindane, respectively) were conducted at a food concentration of 1.5 µg C mL-

139

1

140

lindane were dissolved in dimethyl sulfoxide (DMSO) for use in the bioassays. Solvent

141

control with a DMSO concentration corresponding to a volume of 0.1‰ of the total

142

incubation volume was used in all exposure tests.

26

with minor

and using the same test conditions as in Experiment II (Table 1). Both haloperidol and

6 ACS Paragon Plus Environment

Page 7 of 24

Environmental Science & Technology

143

144

Biochemical analyses

145

At the termination of each experiment, live daphnids were pooled within replicates, rinsed in

146

potassium phosphate buffer (PPB) and transferred to Eppendorf tubes. All samples were snap

147

frozen and stored at -80˚C until analysis.

148

149

Protein quantification

150

Samples for protein and ORAC measurements were homogenized in 150 µL PPB buffer (3.1

151

mM, pH 7.4). Protein content (µg ind-1) was determined by bicinchoninic acid method27 using

152

PierceTM BCA Protein Assay kit (Thermo Scientific) according to microplate procedure with

153

some modifications. Transparent microplate was used and total volume in the wells was 150

154

µL, with 10 µL homogenate, 10 µL PPB and 130 µL working solution. Absorbance was

155

measured at 540 nm using FluoStar Optima plate reader (BMG Lab Technologies, Germany).

156

157

Oxygen radical absorbance capacity (ORAC)

158

Total antioxidant capacity was assayed as ORAC according to Ou, et al.

159

modifications. Fluorescein was used as a fluorescent probe (106 nM) and 2,2- azobis(2-

160

amidinopropane) dihydrochloride (AAPH) (152.66 mM) as a source of peroxyl radicals.

161

Trolox (218 µM, Sigma-Aldrich) was used as standard. In each assay, 20 µL sample was

162

added to each well and mixed with 30 µL AAPH and 150 µL fluorescein. ORAC levels were

163

expressed as ORAC ind-1. Additionally, ORAC values were normalized to protein content

7 ACS Paragon Plus Environment

28

, with minor

Environmental Science & Technology

Page 8 of 24

164

(ORACp) before related to feeding rate because of the high contribution of proteins to ORAC

165

values29.

166

167

Lipid peroxidation

168

Two exposures were performed for unexposed and exposed daphnids for TBARS analysis

169

(Experiment II, IV, VI; Table 1) with high (A) and low (B) population density, respectively.

170

Daphnids were assayed for lipid peroxidation by a modified TBARS method for measuring

171

the aldehydic lipid peroxidation decomposition derivatives, which form fluorescent products

172

after reacting with thiobarbituric acid (TBA)30. Daphnids were homogenized in 200 µL PPB,

173

sonicated 3×10s and aliquoted. Subsamples of 125 µL tissue homogenate were treated with

174

125 µL 10% trichloroacetic acid. The sample was further mixed with 150 µL TBA (2 mM)

175

and incubated at 100˚C for 1 h. After cooling to room temperature, 220 µL of

176

butanol:pyridine (volume ratio 15:1) mixture were added, vortexed (2×10s) and centrifuged

177

for 5 minutes at 4000 g. The organic phase was used for fluorometric determination

178

(540nm/590nm) of malondialdehyde (MDA) concentration (µM MDA equivalents ind-1). The

179

MDA concentrations were expressed as TBARS ind-1. Following the common procedure for

180

biochemical end point, TBARS were normalized to protein content (TBARSp) before related

181

to feeding rate.

182

183

Data analysis and statistics

184

Feeding rate was calculated according to Båmstedt, et al.

185

unexposed daphnids was fitted to a sigmoid function32-33

186

 =  /1 +    

31

. The functional response of

(1) 8 ACS Paragon Plus Environment

Page 9 of 24

Environmental Science & Technology

187

where F is feeding rate (µg C h-1 ind-1), Fmax is the theoretical maximum feeding rate, e is

188

Euler´s number, k is a constant, C is food concentration (µg C mL-1) and Cm is the half-

189

saturation constant.

190

To test hypotheses 1 and 2, the relationships between feeding rate and biomarkers were

191

analyzed by linear regression analysis. The effect of chemical exposure on feeding rate was

192

evaluated using Hill equation

193

   =  +  −   ×   /  + 

194

where F is feeding rate (µg C h-1 ind-1), Fmin is the minimum feeding rate (µg C h-1 ind-1) and

195

Fmax the maximum feeding rate (µg C h-1 ind-1), C is the logarithm of the substance

196

concentration (mg L-1) +1 and n is the Hill constant34. The substance concentration

197

(logarithmic value) that causes 50% feeding inhibition is represented by EC50 (mg L-1).

198

Hypotheses 3 and 4 were addressed using general linear models to test the impact of

199

substance exposure on the relationships between feeding and protein allocation and between

200

protein content and oxidative biomarkers; experimental run (A and B) was used as a co-

201

variable to account for the differences in experimental design. All values were normalized to

202

the mean value of the control group for each treatment. To facilitate statistical comparisons

203

and interpretation, the independent variables were centered by their respective mean values

204

using response interval covering both exposed and unexposed daphnids. Centering input

205

variables removes the collinearity between the main effects and the interaction predictors,

206

therefore allowing the interpretation of main effects35. The interactions between explanatory

207

variables were removed from the model when non-significant. Assumptions of normality and

208

homoscedasticity were fulfilled for all data as confirmed by residual plot analysis. Significant

209

level was ˂0.05 for all tests and all analyses were carried out in R 2.13.2.

9 ACS Paragon Plus Environment

(2)

Environmental Science & Technology

210

Projection to latent structures by means of partial least squares (PLS) was applied to visualize

211

directions in a multivariate space for maximum separation of observations (biomarkers and

212

physiological variables across an individual) belonging to different groups (treatments). The

213

amount of variation attributed to each explanatory variable was determined by regressing each

214

explanatory variable against the response variable (Treatment as a categorical variable) in the

215

absence of the other explanatory variables36 as implemented in STATISTICA 8 (StatSoft, Inc.

216

2013).

217

218

RESULTS

219

Feeding and biomarker responses in unexposed animals

220

Feeding rate increased with increasing food concentration, reaching saturation at ~6.7 µg C

221

mL-1 (Figure 1). Moreover, individual protein content was significantly positively related to

222

feeding rate (Figure 3). Also, there was a significant positive relationship between individual

223

ORAC and protein values. However, no significant relationship between ORACp and feeding

224

rate was found. Finally, individual protein content and TBARS as well as TBARSp and

225

feeding rate were positively related to each other (Table 2; Figure 3).

226

227

Feeding and biomarker responses in exposed daphnids

228

Neither haloperidol nor lindane caused mortality within the tested concentration range.

229

However, both substances had inhibitory effect on feeding rate, following a sigmoid dose-

230

response and resulting in nearly complete feeding inhibition in the highest concentrations of

231

both substances. Haloperidol EC50 was 1.62 mg L-1 (95% confidence interval: 1.37 to 1.90 mg

10 ACS Paragon Plus Environment

Page 10 of 24

Page 11 of 24

Environmental Science & Technology

232

L-1) and lindane EC50 was 1.27 mg L-1 (95% confidence interval: 1.03 to 1.55 mg L-1) (Figure

233

2).

234

Similar to the unexposed daphnids, individual protein content was significantly positively

235

related to feeding rate in exposed daphnids. Moreover, haloperidol had a significant negative

236

effect on the baseline protein content and a positive effect on the slope on the relationship

237

between protein and feeding as indicated by the significant interaction term of feeding rate

238

and treatment. By contrast, lindane had no significant effect on the individual protein content

239

(Table 3A; Figure 3).

240

Again, similar to the unexposed daphnids, ORAC was positively related to protein content in

241

both haloperidol and lindane exposed daphnids. Moreover, haloperidol had a positive effect

242

on the ORAC – protein relationship, as indicated by the significant interaction between

243

treatment and protein content. Lindane significantly decreased the baseline ORAC values as

244

indicated by the significantly different intercept (Table 3B).

245

In contrast to the unexposed daphnids, a significant positive relationship between ORACp and

246

feeding rate was observed in the animals exposed to haloperidol or lindane. Moreover, both

247

substances had significant negative effects on the ORACp baseline as indicated by the

248

significant treatment effect (Table 3C).

249

Haloperidol had no significant effect on the relationship between TBARS and protein content.

250

However, the significant interaction for lindane and protein indicates a significantly negative

251

effect on the TBARS-protein relationship due to lindane exposure (Table 3D). Neither

252

haloperidol nor lindane had any significant effect on the relationship between TBARSp and

253

feeding rate (Table 3E).

254

The PLS analysis showed a clear pattern related to the differences between the lindane-

255

exposed and unexposed daphnids revealing relevant ORACp, feeding rate and TBARSp in 11 ACS Paragon Plus Environment

Environmental Science & Technology

256

this separation. The two PLS components accounted for 69% of the total variance. No clear

257

separation between the haloperidol-exposed and unexposed animals or animals exposed to

258

low lindane concentrations was observed, with variability in both haloperidol-exposed and

259

unexposed groups being largely affected by variations in feeding and individual protein

260

content (Figure 3).

261

262

DISCUSSION

263

In Daphnia magna, biomarkers of oxidative status changed in concert with feeding rate, that

264

thus was established as a confounding factor for oxidative biomarkers in this standard test

265

species. In addition to inducing feeding inhibition, exposure to our model substances,

266

haloperidol and lindane, altered the relationship between feeding rate, protein and oxidative

267

biomarkers, emphasizing the complexity of the biomarker responses.

268

Hypothesis 1, linking protein content to feeding rate, was confirmed by the significant

269

positive relationship between feeding rate and protein content, indicating that protein

270

synthesis increases as more resources become available for protein production37. Since protein

271

content is commonly used to normalize enzyme activities and other biochemical constituents

272

used as biomarkers in ecology and ecotoxicology, this response is important for biomarker

273

applications in general.

274

Hypothesis 2, linking oxidative biomarkers to individual protein content, was also supported.

275

In both exposed and unexposed daphnids, individual ORAC values were positively related to

276

protein content, most probably due to increased production and intake of low-molecular

277

compounds and proteins with antioxidative properties. The antioxidant defense consists of

278

enzymes as well as other proteins and low-molecular-mass agents, such as ascorbic acid,

279

reduced glutathione, methionine and uric acid7. The antioxidative activity of the water soluble 12 ACS Paragon Plus Environment

Page 12 of 24

Page 13 of 24

Environmental Science & Technology

280

fraction of these compounds is measured in the ORAC assay28. The lack of correlation

281

between ORACp and feeding rate in the unexposed daphnids suggests that the allocation of

282

proteins to the antioxidant defense did not increase in response to increased caloric intake,

283

which is in agreement with previous findings38. A baseline relationship between the feeding

284

rate and alterations in antioxidant defense has thus been established, which also facilitates

285

application of ORACp as a biomarker in ecological and ecotoxicological studies11.

286

Even though EC50 values for feeding inhibition were similar between haloperidol and lindane

287

as evidenced by the overlapping confidence intervals, their effects on protein and ORAC

288

differed, which may be related to differences in their mode of action18, 20. By including protein

289

and substance exposure in the statistical models we could confirm Hypothesis 3 and show that

290

haloperidol had a positive effect on the relationship between individual protein content and

291

feeding rate. This was likely due to decreased protein synthesis with increasing haloperidol

292

concentration39. By contrast to haloperidol, lindane did not have any effect on protein content.

293

Hence, any difference in protein content in response to increasing lindane concentration was

294

solely due to the decrease in filtering activity and thus feeding rate in the exposed animals.

295

Without including feeding rate as an explanatory variable to the model, this effect would have

296

been missed and observed alterations in protein content, and in the biomarker normalized to

297

protein content, may erroneously have been attributed direct toxic mechanisms on protein

298

metabolism.

299

The Hypothesis 4 also found support as both haloperidol and lindane affected the relationship

300

between protein and ORAC. Exposure to haloperidol resulted in lower allocation of resources

301

to the antioxidant defense in relation to protein content, which is consistent with a general

302

response to starvation, whereas lindane caused a significant decrease in the baseline ORAC

303

values. Due to the effects of haloperidol and lindane on protein allocation and ORAC, there

304

were significant positive effects on the relationship between ORACp and feeding rate in the 13 ACS Paragon Plus Environment

Environmental Science & Technology

305

exposed daphnids. The altered ORAC-protein relationship and the positive relation between

306

ORACp and feeding rate indicate reduced resource allocation to antioxidant defense and/or a

307

depletion of antioxidative compounds due to the chemical exposure. One can speculate that

308

these effects may be related to detoxification as some agents contributing to the antioxidant

309

defense are also involved in xenobiotic metabolism. One of these, glutathione (GSH), is a co-

310

factor in the detoxification of ROS7 and depletion of GSH is used as a biomarker of oxidative

311

stress due its involvement in antioxidative reactions40. Both haloperidol and lindane have been

312

shown to cause GSH depletion due to its involvement in ROS detoxification and xenobiotic

313

metabolism41-43. Hence, depletion of GSH may partly explain the decrease in ORAC in

314

relation to protein content observed for exposed daphnids.

315

Contrary to Hypothesis 4, predicting that lipid peroxidation levels would increase in response

316

to xenobiotic exposure, haloperidol did not altered the relationship between protein content

317

and TBARS, thus indicating that lipid peroxidation levels were only affected by feeding rate

318

(Figure 3). These results contradict reported effects of this drug on lipid peroxidation in

319

humans that had been administrated haloperidol (10 mg day-1) for two weeks41. However, the

320

tested concentrations in our study may have been too low to induce oxidative damages during

321

the 24-h exposure and the antioxidant defense could successfully counteracted ROS effects

322

with non-detectable effects on lipid peroxidation levels. The high survival rate in this study

323

could be indicative of such responses, albeit high survivorship does not necessarily mean that

324

an oxidative stress response is absent23. Lindane significantly lowered the TBARS levels at

325

increasing protein content compared to the unexposed daphnids. Due to the positive effect of

326

lindane on hsp, and thus protein composition25, normalizing TBARS to the total protein

327

concentrations in the sample could introduce additional uncertainty and even be misleading

328

for understanding of chemical exposure effects. Assessment of normalization strategies for

14 ACS Paragon Plus Environment

Page 14 of 24

Page 15 of 24

Environmental Science & Technology

329

oxidative stress biomarkers is needed to facilitate interpretation of these responses in the field

330

and laboratory settings.

331

The observed effects of calorie intake on TBARS levels (Table 2, Figure 3) raise questions

332

about optimal testing design for studies employing oxidative stress biomarkers to evaluate

333

effects of various stressors. The ad libitum feeding regime used in many ecotoxicological tests

334

may lead to high lipid peroxidation levels in actively feeding non-stressed individuals and,

335

further, to erroneous interpretation of the results. Hence, bioassays with D. magna should be

336

performed at moderate food levels to avoid effects on biochemical markers that are solely a

337

consequence of ad libitum feeding. Moderate dietary restriction has also been shown to

338

increase the sensitivity and response to toxic substances in both rodents15 and rotifers44, and

339

our results indicate that this is also the case for oxidative biomarkers in D. magna.

340

In conclusion, our results indicate that alterations in oxidative biomarker response due to

341

xenobiotic exposure may not only be a consequence of direct interactions with oxidative

342

processes, but can also be a result of indirect response via feeding inhibition. Since protein

343

content, ORAC and TBARS were positively correlated with food intake, it is necessary to

344

account for inhibitory effects of xenobiotics on feeding rate when interpreting responses of

345

these biomarkers. Without considering confounding factors representing nutritional status and

346

metabolism when evaluating biomarker response to toxic exposure, there is a risk of making

347

erroneous conclusions about toxicity effects and mechanisms. To further increase the value of

348

biomarkers in general and oxidative biomarkers in particular, the importance of confounding

349

factors for interpretation of biomarker responses needs to be addressed routinely in biomarker

350

validation.

351

352

ACKNOWLEDGMENTS 15 ACS Paragon Plus Environment

Environmental Science & Technology

353

This study was supported by the Swedish Research Council for Environment, Agricultural

354

Science and Spatial Planning (FORMAS), Stockholm University’s strategic marine

355

environmental research program “Baltic Ecosystem Adaptive Management” and the Swedish

356

Foundation for Strategic Environmental Research (MISTRA; MistraPharma).

357

SUPPORTING INFORMATION

358

This information is available free of charge via the internet at http://pubs.acs.org.

359 360

REFERENCES

361 362 363 364 365 366 367 368 369 370 371 372 373 374 375 376 377 378 379 380 381 382 383 384 385 386 387 388 389 390

1. Yu, B. P., Aging and oxidative stress: Modulation by dietary restriction. Free Radical Biology and Medicine 1996, 21 (5), 651-668. 2. Valko, M.; Leibfritz, D.; Moncol, J.; Cronin, M. T. D.; Mazur, M.; Telser, J., Free radicals and antioxidants in normal physiological functions and human disease. International Journal of Biochemistry & Cell Biology 2007, 39 (1), 44-84. 3. Mustafa, S. A.; Al-Subiai, S. N.; Davies, S. J.; Jha, A. N., Hypoxia-induced oxidative DNA damage links with higher level biological effects including specific growth rate in common carp, Cyprinus carpio L. Ecotoxicology 2011, 20 (6), 1455-1466. 4. Speakman, J. R.; Mitchell, S. E., Caloric restriction. Molecular aspects of medicine 2011, 32 (3), 159-221. 5. Lambert, A. J.; Merry, B. J., Effect of caloric restriction on mitochondrial reactive oxygen species production and bioenergetics: reversal by insulin. American journal of physiology. Regulatory, integrative and comparative physiology 2004, 286 (1), R71-9. 6. Sohal, R. S.; Weindruch, R., Oxidative stress, caloric restriction, and aging. Science 1996, 273 (5271), 59-63. 7. Halliwell, B.; Gutteridge, J. M. C., Free radicals in biology and medicine. 4 ed.; Oxford University press: United States, 2007. 8. Lushchak, V. I., Environmentally induced oxidative stress in aquatic animals. Aquatic Toxicology 2011, 101 (1), 13-30. 9. Livingstone, D. R., Contaminant-stimulated reactive oxygen species production and oxidative damage in aquatic organisms. Marine Pollution Bulletin 2001, 42 (8), 656-666. 10. Valavanidis, A.; Vlahogianni, T.; Dassenakis, M.; Scoullos, M., Molecular biomarkers of oxidative stress in aquatic organisms in relation to toxic environmental pollutants. Ecotoxicology and Environmental Safety 2006, 64 (2), 178-189. 11. van der Oost, R.; Beyer, J.; Vermeulen, N. P. E., Fish bioaccumulation and biomarkers in environmental risk assessment: a review. Environmental Toxicology and Pharmacology 2003, 13 (2), 57-149. 12. McWilliam, R. A.; Baird, D. J., Postexposure feeding depression: A new toxicity endpoint for use in laboratory studies with Daphnia magna. Environmental Toxicology and Chemistry 2002, 21 (6), 1198-1205.

16 ACS Paragon Plus Environment

Page 16 of 24

Page 17 of 24

391 392 393 394 395 396 397 398 399 400 401 402 403 404 405 406 407 408 409 410 411 412 413 414 415 416 417 418 419 420 421 422 423 424 425 426 427 428 429 430 431 432 433 434 435 436 437 438 439 440 441 442

Environmental Science & Technology

13. Domene, X.; Natal-da-Luz, T.; Alcaniz, J. M.; Andres, P.; Sousa, J. P., Feeding inhibition in the soil collembolan Folsomia candida as an endpoint for the estimation of organic waste ecotoxicity. Environmental Toxicology and Chemistry 2007, 26 (7), 1538-1544. 14. Barata, C.; Alanon, P.; Gutierrez-Alonso, S.; Riva, M. C.; Fernandez, C.; Tarazona, J. V., A Daphnia magna feeding bioassay as a cost effective and ecological relevant sublethal toxicity test for Environmental Risk Assessment of toxic effluents. Science of the Total Environment 2008, 405 (1-3), 78-86. 15. Hart, R. W.; Keenan, K.; Turturro, A.; Abdo, K. M.; Leakey, J.; Lyncook, B., Caloric restriction and toxicity. Fundamental and Applied Toxicology 1995, 25 (2), 184-195. 16. Keenan, K. P.; Ballam, G. C.; Soper, K. A.; Laroque, P.; Coleman, J. B.; Dixit, R., Diet, caloric restriction, and the rodent bioassay. Toxicological Sciences 1999, 52 (2), 24-34. 17. Pugh, T. D.; Klopp, R. G.; Weindruch, R., Controlling caloric consumption: protocols for rodents and rhesus monkeys. Neurobiology of Aging 1999, 20 (2), 157-165. 18. Ninan, I.; Kulkarni, S. K., Dopamine receptor sensitive effect of dizocilpine on feeding behaviour. Brain Research 1998, 812 (1-2), 157-163. 19. Videla, L. A.; Barros, S. B. M.; Junqueira, V. B. C., Lindane-induced liver oxidative stress. Free Radical Biology and Medicine 1990, 9 (2), 169-179. 20. Gliwicz, M. Z.; Sieniawska, A., Filtering activity of Daphnia in low concentrations of a pesticide. Limnology and Oceanography 1986, 31 (5), 1132-1138. 21. Hartgers, E. M.; Heugens, E. H. W.; Deneer, J. W., Effect of lindane on the clearance rate of Daphnia magna. Archives of Environmental Contamination and Toxicology 1999, 36 (4), 399404. 22. Vehmaa, A.; Hogfors, H.; Gorokhova, E.; Brutemark, A.; Holmborn, T.; Engstrom-Ost, J., Projected marine climate change: effects on copepod oxidative status and reproduction. Ecology and Evolution 2013, 3 (13), 4548-4557. 23. Barata, C.; Varo, I.; Navarro, J. C.; Arun, S.; Porte, C., Antioxidant enzyme activities and lipid peroxidation in the freshwater cladoceran Daphnia magna exposed to redox cycling compounds. Comparative Biochemistry and Physiology C-Toxicology & Pharmacology 2005, 140 (2), 175-186. 24. Nakki, R.; Nickolenko, J.; Chang, J. M.; Sagar, S. M.; Sharp, F. R., Haloperidol prevents ketamine- and phencyclidine-induced HSP70 protein expression but not microglial activation. Exp. Neurol. 1996, 137 (2), 234-241. 25. Saradha, B.; Vaithinathan, S.; Mathur, P. P., Lindane alters the levels of HSP70 and clusterin in adult rat testis. Toxicology 2008, 243 (1-2), 116-123. 26. Barata, C.; Baird, D. J.; Minarro, A.; Soares, A., Do genotype responses always converge from lethal to nonlethal toxicant exposure levels? Hypothesis tested using clones of Daphnia magna straus. Environmental Toxicology and Chemistry 2000, 19 (9), 2314-2322. 27. Smith, P. K.; Krohn, R. I.; Hermanson, G. T.; Mallia, A. K.; Gartner, F. H.; Provenzano, M. D.; Fujimoto, E. K.; Goeke, N. M.; Olson, B. J.; Klenk, D. C., Measurement of protein using bicinchonic acid. Anal. Biochem. 1985, 150 (1), 76-85. 28. Ou, B. X.; Hampsch-Woodill, M.; Prior, R. L., Development and validation of an improved oxygen radical absorbance capacity assay using fluorescein as the fluorescent probe. Journal of Agricultural and Food Chemistry 2001, 49 (10), 4619-4626. 29. Cao, G. H.; Prior, R. L., Comparison of different analytical methods for assessing total antioxidant capacity of human serum. Clinical Chemistry 1998, 44 (6), 1309-1315. 30. Hodges, D. M.; DeLong, J. M.; Forney, C. F.; Prange, R. K., Improving the thiobarbituric acid-reactive-substances assay for estimating lipid peroxidation in plant tissues containing anthocyanin and other interfering compounds. Planta 1999, 207 (4), 604-611. 31. Båmstedt, U.; Gifford, D. J.; Irigoien, X.; Atkinson, A.; Roman, M., 8 - Feeding. In ICES Zooplankton Methodology Manual, Huntley, R. H. W. L. R. S., Ed. Academic Press: London, 2000; pp 297-399. 32. Jeschke, J. M.; Kopp, M.; Tollrian, R., Consumer-food systems: why type I functional responses are exclusive to filter feeders. Biological Reviews 2004, 79 (2), 337-349. 17 ACS Paragon Plus Environment

Environmental Science & Technology

443 444 445 446 447 448 449 450 451 452 453 454 455 456 457 458 459 460 461 462 463 464 465 466 467 468 469 470 471 472 473 474 475 476 477 478 479 480

33. Sarnelle, O.; Wilson, A. E., Type III functional response in Daphnia. Ecology 2008, 89 (6), 1723-1732. 34. Barton, H. A.; Andersen, M. E.; Allen, B. C., Dose-response characteristics of uterine responses in rats exposed to estrogen agonists. Regulatory Toxicology and Pharmacology 1998, 28 (2), 133-149. 35. Schielzeth, H., Simple means to improve the interpretability of regression coefficients. Methods in Ecology and Evolution 2010, 1 (2), 103-113. 36. Wold, S.; Sjostrom, M.; Eriksson, L., PLS-regression: a basic tool of chemometrics. Chemometrics Intell. Lab. Syst. 2001, 58 (2), 109-130. 37. Hoppe, S.; Bierhoff, H.; Cado, I.; Weber, A.; Tiebe, M.; Grummt, I.; Voit, R., AMPactivated protein kinase adapts rRNA synthesis to cellular energy supply. Proceedings of the National Academy of Sciences of the United States of America 2009, 106 (42), 17781-17786. 38. Sohal, R. S.; Ku, H. H.; Agarwal, S.; Forster, M. J.; Lal, H., Oxidative damage, mitochondrial oxidant generation and antioxidant defense during aging and in response to food restriction in the mouse. Mechanisms of Ageing and Development 1994, 74 (1-2), 121-133. 39. Barrientos, A.; Marin, C.; Miro, O.; Casademont, J.; Gomez, M.; Nunes, V.; Tolosa, E.; Urbano-Marquez, A.; Cardellach, F., Biochemical and molecular effects of chronic haloperidol administration on brain and muscle mitochondria of rats. Journal of Neuroscience Research 1998, 53 (4), 475-481. 40. Doyotte, A.; Cossu, C.; Jacquin, M. C.; Babut, M.; Vasseur, P., Antioxidant enzymes, glutathione and lipid peroxidation as relevant biomarkers of experimental or field exposure in the gills and the digestive gland of the freshwater bivalve Unio tumidus. Aquatic Toxicology 1997, 39 (2), 93-110. 41. Pai, B. N.; Janakiramaiah, N.; Gangadhar, B. N.; Ravindranath, V., Depletion of glutathione and enhanced lipid-peroxidation in the CSF of acute psychotic following haloperidol administration. Biological Psychiatry 1994, 36 (7), 489-491. 42. Tanaka, K.; Kurihara, N.; Nakajima, M., Metabolism of lindane in house-flies metabolic desaturation, dehydrogenation and dehydrochlorination, and conjugation with glutathione. Pesticide Biochemistry and Physiology 1976, 6 (4), 392-399. 43. Anguiano, O. L.; de Castro, A. C.; de D'Angelo, A. M. P., The role of glutathion conjugation in the regulation of early toad embryos' tolerance to pesticides. Comparative Biochemistry and Physiology C-Toxicology & Pharmacology 2001, 128 (1), 35-43. 44. Kailasam, M.; Kaneko, G.; Oo, A. K. S.; Ozaki, Y.; Thirunavukkarasu, A. R.; Watabe, S., Effects of calorie restriction on the expression of manganese superoxide dismutase and catalase under oxidative stress conditions in the rotifer Brachionus plicatilis. Fisheries Science 2011, 77 (3), 403-409. 45. Rousseeuw, P. J.; Ruts, I.; Tukey, J. W., The bagplot: A bivariate boxplot. Am. Stat. 1999, 53 (4), 382-387.

481 482 483

18 ACS Paragon Plus Environment

Page 18 of 24

Page 19 of 24

Environmental Science & Technology

484

485 486 487 488 489 490

Table 1. Summary of the experiments, specific conditions and measured biomarkers

Exp. I no test substance, varying food levels

Exp. II no test substance, varying food levels

Exp. III

Exp. IV

Exp. V

Exp. VI

Haloperidol

Haloperidol

Lindane

Lindane

Concentrations of the test substance (mg L-1)

0

0

0.2-3.1

0.2-3.1

0.2-1.6

0.2-1.6

Food concentration (µg C mL-1)

0-9.4

0-7

1.5

1.5

1.5

1.5

Feeding rate, Mortality

Mortality Feeding rate (B)

Feeding rate, Mortality

Mortality Feeding rate (B)

Feeding rate, Mortality

Mortality Feeding rate (B)

Protein, ORAC

Protein, ORAC, TBARS

Protein, ORAC

Protein, ORAC, TBARS

Protein, ORAC

Protein, ORAC, TBARS

Test volume (mL)

50

900 (A) 50 (B)

50

900 (A) 50 (B)

50

900 (A) 50 (B)

Individuals/replicate

5

33-35 (A) 5 (B)

5

33-35 (A) 5 (B)

5

33-35 (A) 5 (B)

5

3 (A) 18 pooled to 3 (B)

Exposure

Physiological end points Biomarkers measured

3 (A) 3 (A) 18 pooled to 5 18 pooled to 3 3 (B) (B) A – Exposure with high population density, B – Exposure with low population density Replicates/conc.

5

19 ACS Paragon Plus Environment

Environmental Science & Technology

491

492 493 494 495

Figure 1. Functional response of juvenile D. magna.fed P. subcapitata. The horizontal broken line represents the maximum feeding rate and the vertical line represents saturation level 6.7 µg C/ml, calculated using the lower 95% confidence interval for the theoretical Fmax.

496 497 498 499 500 501 502 503

20 ACS Paragon Plus Environment

Page 20 of 24

Page 21 of 24

Environmental Science & Technology

504 505 506

Figure 2. Feeding inhibition in Daphnia magna exposed to haloperidol (A) and lindane (B). The vertical lines represent EC50 values and the grey, broken lines represent upper and lower confidence interval (95%).

507 508 Table 2. Linear regression for unexposed daphnids.

Response variable

Explanatory variable

a

b

df

R2

p

Protein

FR

3.81

5.45

23

0.70

***

ORAC

Protein

0.10

0.059

23

0.71

***

ORACp

FR

-0.014

0.12

23

0.10

˃ 0.05

TBARS

Protein

1.15

-2.99

7

0.47

*

TBARSp

FR

0.47

0.51

7

0.54

*

Linear regressions (y = ax + b) for the relationships between feeding rate and biomarker responses and between biomarkers and individual protein content. Asterisks indicate level of significance for the slope (a): p ≤ 0.05 (*); p ≤ 0.01 (**); p ≤ 0.001 (***). FR – Feeding rate, ORAC – Oxygen radical absorbance capacity, ORACp - proteinspecific ORAC, TBARS – Thiobarbituric acid reactive substances, TBARSp - protein-specific TBARS

509 510 511 512 Table 3. General linear models testing effects of the xenobiotics and feeding rate on the individual protein content, ORAC,

21 ACS Paragon Plus Environment

Environmental Science & Technology

Page 22 of 24

ORACp, TBARS and TBARSp.

Haloperidol

Lindane

Estimate

SE

t

p value

Estimate

SE

t

p value

FR

0.54

0.11

4.77

***

0.15

0.017

8.77

***

Treatment

0.16

0.043

3.80

***

-0.06

0.042

-1.42

˃ 0.05

FR*Treatment

-0.27

0.13

-2.04

*

Protein

1.7

0.15

11.45

***

0.98

0.17

5.81

***

Treatment

0.023

0.043

0.54

˃ 0.05

0.27

0.056

4.89

***

Protein*Treatment

-0.60

0.22

-2.76

**

FR

0.93

0.12

7.67

***

0.38

0.15

2.55

*

Treatment

0.11

0.046

2.48

*

0.24

0.056

4.22

***

FR*Treatment

-0.98

0.14

-7.01

***

-0.44

0.17

-2.56

*

Protein

0.51

0.10

4.89

***

0.25

0.16

1.66

˃ 0.05

Treatment

0.022

0.044

0.49

˃ 0.05

0.025

0.042

0.58

˃ 0.05

0.39

0.19

2.07

*

A) Protein

B) ORAC

C) ORACp

D) TBARS

Protein*Treatment E) TBARSp FR

-0.20

0.12

-1.72

˃ 0.05

-0.20

0.12

-1.76

˃ 0.05

Treatment

-0.063

0.099

-0.64

˃ 0.05

-0.16

0.098

-1.61

˃ 0.05

Treatment group was set as a reference. Asterisks indicate level of significance: p ≤ 0.05 (*); p ≤ 0.01 (**); p ≤ 0.001 (***).FR – Feeding rate, ORAC – Oxygen radical absorbance capacity, ORACp – protein-specific ORAC, TBARS – Thiobarbituric acid reactive substances, TBARSp - protein-specific TBARS

513 514 515

22 ACS Paragon Plus Environment

Page 23 of 24

Environmental Science & Technology

516 517 518 519 520 521 522 523 524 525 526 527

Figure 3. Standardized biplot visualizing PLS model by scatter plots termed scores or loadings plots and showing how predictors form the space of the latent variables and how they are combined with the observations. Each point on the score plot represents an individual Daphnia sample projected in the bivariate space and loading scores provide the correlation between the original variables and the new component variables. The model is for Treatment as a response variable and feeding rate (FR), individual protein content (Protein), protein-specific ORAC and TBARS values (ORACp and TBARSp, respectively) as explanatory variables. The structure of the multivariate point cloud is represented by the shaded areas in the bagplot, analogous to a box-and-whiskers plot but also visualizing the spread, correlation, skewness, and tails of the data45. The small square colored according to the treatment represents the depth median (the deepest location), the dark area corresponds to 50% of the dataset, and the light area is a fence augmented by a default factor of 1.5. Sample points outside the shaded areas are outliers.

23 ACS Paragon Plus Environment

Environmental Science & Technology

145x131mm (96 x 96 DPI)

ACS Paragon Plus Environment

Page 24 of 24