Apidologie

, Volume 48, Issue 5, pp 635–643 | Cite as

Toxicity of thiametoxam on in vitro reared honey bee brood

  • Giacomo Grillone
  • Daniela Laurino
  • Aulo Manino
  • Marco Porporato
Original article

Abstract

Pesticides are a possible cause of pollinator decline and honey bee colony losses experienced in several countries in recent years. In the past years, many north-west Italian beekeepers reported the presence of dead brood in field apiaries during neonicotinoid-coated maize sowing; therefore, a possible role of these insecticides was suspected. The objective of this study was to test this hypothesis. Laboratory repeated dose toxicity tests on in vitro reared larvae were carried out using thiamethoxam. The repeated treatment median lethal concentration (LC50) and the median lethal dose (LD50) 14 and 19 days after grafting were calculated and resulted of the same order of magnitude of realistic brood exposure under a worst-case scenario. Various sublethal effects, like brownish larvae, duplication of the pupal integument, delay in development, and deformed adults were also observed.

Keywords

Apis mellifera artificial rearing cumulative toxicity neonicotinoids sublethal doses thiametoxam 

1 Introduction

An extensive pollinator decline (Gallai et al., 2009; Potts et al., 2010; Nieto et al., 2014) and heavy honey bee colony losses (Janke and Rosenkranz, 2009; Neumann and Carreck, 2010) have been experienced in several countries lately. In the effort to bring light on the origin of these phenomena, several factors have so far been investigated. Furthermore, new features like the colony collapse disorder (CCD) syndrome have been described (vanEngelsdorp et al., 2009), nevertheless not a single cause was definitively identified (Maini et al., 2010; Ratnieks and Carreck, 2010; Williams et al., 2010). Therefore, it is most likely that some multifactorial effect is involved, and lately, the cumulative action of several stressors on the honey bee’s immune response has been proposed as a unifying model (Nazzi et al., 2012; Di Prisco et al., 2013).

Among the various factors suggested, pesticides are one of the most relevant and in-depth investigated causes of colony losses (Blacquière et al., 2012; Krupke et al., 2012; Lu et al., 2012; van der Sluijs et al., 2013; European Academies Science Advisory Council, 2015). In particular, neonicotinoid insecticides—especially when used in seed coating—were greatly debated since heavy honey bee mortalities were observed in Italy and other European countries during maize sowing (Greatti et al., 2003 and 2006; Forster, 2009; Pistorius et al., 2009; Chauzat et al., 2010; van der Geest, 2012). At last, these facts led in 2008 to the ban of the use of neonicotinoids and fipronil as coating active ingredients for maize and sunflower. As a result, a dramatic reduction in the poisoning incidents reported in Italy was observed (APENET, 2009). In the years before the ban, many north-west Italian beekeepers reported dead brood with symptoms reminding the European foul brood (EFB) in their hives during maize sowing, but an EFB diagnosis was not confirmed. After the neonicotinoid and fipronil use had been restricted, this syndrome nearly disappeared; therefore, a possible role of these insecticides in causing such symptoms was suspected, and the objective of this study is to test this hypothesis.

Pesticide risk assessment on honey bee brood is far more complex than on adult workers, especially when chronic or sublethal effects are involved, since the honey bee brood develops in the hives and carefully reared inside comb cells, and exposure to pesticides is mostly mediated by both forager and nurse adult workers. Due to such difficulties, several laboratory (Czoppelt 1991; Davis et al., 1988; Mussen et al., 2004; Aupinel et al., 2007a, b; Gregorc and Ellis, 2011; Hendriksma et al., 2011; Tavares et al., 2015), cage (Schur et al., 2003), and field procedures (Oomen et al., 1992; Everich et al., 2009) have been proposed for testing pesticide toxicity on honey bee brood and to assess experimental results. Presently, a universal consensus on a specific methodology for testing pesticides on honey bee brood has not yet been achieved (Aupinel et al., 2009; European Food Safety Authority, 2013a, b). Nonetheless, as a first step to detect any possible relationship between neonicotinoids and honey bee brood anomalies, we planned some laboratory toxicity tests on in vitro reared larvae hoping that the results could contribute to the debate. A repeated dose exposure test modified from Aupinel’s test (Aupinel et al., 2007a, b) was developed, and thiamethoxam was used as toxic agent, since it is extensively used on crops and its toxicity to honey bees is well known even though the few available data on larvae are controversial (European Food Safety Authority, 2013a).

2 Materials and methods

2.1 Brood rearing

First instar worker larvae were collected from three A. m. ligustica colonies. Computer-assisted wing venation morphometric analysis (Meixner et al., 2013) was used to assess the honey bee subspecies. The hives were periodically checked to exclude the presence of the most common honey bee diseases (Shimanuki and Knox, 2000).

The larvae were grafted from a single brood comb into the wells of a sterile 48-well tissue culture plate; different plates were used for each tested colony. After grafting, the brood was reared in a dark incubator at 34.5 (±0.5) °C for 21 days to allow adult emergence. Larvae were kept at 96% relative humidity in hermetic desiccators containing dishes filled with a K2SO4 saturated solution, and pupae were kept at 80% relative humidity in hermetic desiccators containing dishes filled with a NaCl saturated solution.

The Aupinel’s (Aupinel et al., 2005) semi-artificial diet was adopted. Larvae were fed daily for 6 days putting a food drop onto the well’s bottom; diet composition and amounts fed to larvae are shown in Table I. Fresh royal jelly produced in DISAFA’s apiary, yeast extract from Biokar diagnostics (Beauvais, France), and sugars from Serva Feinbiobiochemica (Heiderberg, Germany) were used.
Table I.

Daily food volumes provided to the larvae, composition of the diet according to their age, and doses of thiamethoxam fed to larvae for each tested concentration from day 1 to day 5 after grafting, day 0 being the grafting day.

Rearing day

Day 0

Day 1

Day 2

Day 3

Day 4

Day 5

Total

Larval food amount (μL)

10

10

20

30

40

50

160

diet composition

 Royal jelly (%)

50

50

50

50

50

50

 Yeast extract (%)

1

1

1.5

2

2

2

d-glucose (%)

6

6

7.5

9

9

9

d-fructose (%)

6

6

7.5

9

9

9

 Dry mattera (%)

29.55

29.55

33.05

36.55

36.55

36.55

Thiamethoxam dose (ng/larva)

 20 mg/L

200

400

600

800

1000

3000

 10 mg/L

100

200

300

400

500

1500

 5 mg/L

50

100

150

200

250

750

 2 mg/L

20

40

60

80

100

300

 1 mg/L

10

20

30

40

50

150

 0.5 mg/L

5

10

15

20

25

75

 0.2 mg/L

2

4

6

8

10

30

aCalculated from Crane (1990) for royal jelly and manufacturer’s specifications for the remaining ingredients

2.2 Toxicity tests

A thiamethoxam commercial formulation available in Italy (Actara® 25.0% pure thiamethoxam, hydro-dispersible granules) was used. It was mixed with the larval food so that known amounts of thiamethoxam were ingested by the larvae. Since the larvae were in contact with the artificial food, some contact action could not be completely excluded.

Preliminary tests were carried out to determine the concentration range between 100% mortality and a mortality level not significantly different from that of the untreated controls. On this basis, the following thiamethoxam concentrations were used to determine the LC50: 20, 10, 5, 2, 1, 0.5, and 0.2 mg/L. Three replications—one 48-well tissue plate per replicate—were done for each tested concentration and the untreated control, taking care that larvae from a different colony were used for each replicate.

From day 1 to day 5—day 0 being the day the larvae were grafted—1 μL of a thiamethoxam suspension in water was added to the food in each well with the treated larvae, and 1 μL of water was added in the wells with the untreated control larvae. The thiamethoxam suspension concentrations were such as to obtain the desired test concentration after dispersion of the given 1 μL drop in the larval food. Doses fed to larvae are shown in Table I.

Mortality and any morphological and/or developmental anomaly that could be considered as a sublethal effect were visually checked and recorded daily immediately before feeding. Larvae that died within 24 h after grafting were removed from the experiments and all computations in order to exclude grafting effects.

Two toxicity endpoints were evaluated: (i) cumulative mortality at day 14 after grafting as an assessment of living pupae (individual not molted from prepupa to pupa on day 14 after grafting were considered as dead in the pre-pupal phase); (ii) number of emerged adults (non-emerged individuals on day 21 after grafting were counted as dead during the pupal stage).

2.3 Statistical analysis

The larval survival was analyzed with the survival analysis module of the statistical package PAST 3.05 (Hammer et al., 2001). The Kaplan-Meier survival curves for the tested concentration and the untreated control were drawn, and each concentration curve was compared with that of the untreated control by means of the log-rank test. The Kaplan-Meier curves and the log-rank tests were computed according to Kleinbaum and Klein (2005). The obtained P values were corrected with the Holm-Bonferroni procedure (Holm, 1979) to provide a multicomparison correction.

The median lethal concentration (LC50) at day 14 and day 19 after grafting and the relative 95% confidence intervals were calculated by means of probit analysis; the procedure devised by Milani (1995) was adopted. Since in the tests each honey bee larva ingests a total of 150 μL of food from day 1 to day 5 (Table I), the repeated treatment cumulative median lethal dose (LD50) was obtained from the relative LC50. Moreover, the LC50 at day 14 and day 19 after grafting were calculated from mortality data relative to each tested colony; subsequently, the three pairwise LC50 ratios were calculated and their statistical significance determined, under the null hypothesis that they are identical, following the procedure given by Robertson and Preisler (1992) and the computational details adopted by Laurino et al. (2013).

The frequency of individuals showing sublethal effects below LC50 concentrations were compared with those observed in the untreated controls by means of Pearson’s χ 2 test of independence with d.f. = 1 and significance P values were calculated with a Monte Carlo permutation test with 9999 replicates. The statistical package PAST 3.05 (Hammer et al., 2001) was used for these computations.

3 Results

Larval mortality 24 h after grafting was always very low (0–3 dead larvae/plate; average survival ± standard deviation = 99.2 ± 1.64%). In the following days, mortality increased throughout the experiments, although feeding and, therefore, thiamethoxam administration had ceased 5 days after grafting to allow fully grown larvae to transform into prepupae.

Kaplan-Meier survival dynamic curves show a regular increase in mortality from the untreated controls to the highest tested thiamethoxam concentration (Figure 1). All tested concentrations resulted statistically highly different from those of the untreated controls (P < 0.01) except for the lowest one (0.2 mg/L) which was hardly significant (P < 0.05) as a consequence of the Holm-Bonferroni correction (Table II).
Figure 1.

Kaplan-Meier survival dynamic curves of honey bee worker brood treated with decreasing thiamethoxam concentrations and of the untreated controls.

Table II.

Survival dynamics of in vitro reared honey bee worker brood treated with decreasing thiamethoxam concentrations compared with those of the untreated controls.

Thiamethoxam concentration comparisons

Log-rank χ 2

Bonferroni-Holm corrected α

P (same) value

20 mg/L vs control

164.91

0.05

0.01

9.57 × 10−38**

10 mg/L vs control

79.45

0.025

0.005

4.96 × 10−19**

5 mg/L vs control

120.28

0.0166

0.00333

5.49 × 10−28**

2 mg/L vs control

64.45

0.0125

0.0025

9.92 × 10−16**

1 mg/L vs control

43.23

0.01

0.002

4.86 × 10−11**

0.5 mg/L vs control

11.60

0.0083

0.00166

0.00066**

0.2 mg/L vs control

8.35

0.0072

0.00142

0.0039*

Significant at *P = 0.05; highly significant at **P = 0.01

LC50 14 days after grafting, when pupation was achieved by all surviving individuals, resulted in 1.53 mg/L of larval food, nearly the double of the value of 0.79 mg/L of larval food reached 5 days later after adult emergence (Table III). Food intake was substantially completed by all larvae reaching the prepupal phase, and therefore, an individual intake of 150 μL of food was assumed to compute the LD50 values shown in Table III even if the larvae that died in the first days did not evidently ingest so much food. The three LD50 values calculated for each colony used in the tests were substantially similar, and no statistically significant difference emerged from the pairwise LC50 ratios.
Table III.

Thiametoxam repeated treatment median lethal concentration (LC50) and median lethal dose (LD50) for in vitro reared honey bee worker brood at day 14 and day 19 after grafting. In brackets LC50 and LD50 upper and lower limits at P = 0.95

 

Day 14

Day 19

LC50 (mg/L)

1.53 (0.33–3.26)

0.79 (0.25–1.39)

LD50 (ng/larva)

229 (50–489)

118 (37–209)

Various anomalies and sublethal effects were observed in the reared brood (Figure 2). In general, sublethal effects were most abundant at lower concentrations than at higher ones, as far as the number of dead larvae and pupae diminished. They were categorised as shown in Table IV. The number of brownish worker larvae treated with thiamethoxam concentrations below LC50 was significantly higher than that of untreated controls; pupation time was highly significantly delayed in treated brood, and significantly more deformed adults emerged from it in comparison with untreated controls. Moreover, three pupae still enclosed in the larval integument were also observed in the treated brood.
Figure 2.

Sublethal effects observed in honey bee brood rearing tests.

Table IV.

Number of sublethal effects showed by in vitro reared honey bee worker brood treated below LC50 thiamethoxam concentrations (0.5 and 0.2 mg/L) and in the untreated controls. A number of normal individuals are reported for comparison purposes

Sublethal effect

Larvae

χ 2

Monte Carlo P

Treated

Control

  

Color of larvae

 Brownish

141

114

4.98

0.0281*

 Pearly-white

146

172

Pupation time

 Delayed

40

27

10.11

0.0017**

 Normal

26

52

Pupal integument

 Double

3

0

3.42

0.1091 n.s.***

 Normal

66

77

Adult workers

 Deformed

36

62

8.18

0.0073**

 Normal

21

11

*Significant (P < 0.01); **highly significant (P < 0.01); ***n.s. not significant at p = 0.05

4 Discussion

The very low larval mortality observed 24 h after grafting indicates that grafting effects were negligible throughout the experiment; thanks to the implementation of sound beekeeping practices in the management of the colonies the larvae were taken from and the correct grafting technique.

Feeding the larvae for 5 days with a constant thiamethoxam concentration instead of feeding them with a single dose in an early development stage, as suggested in most recently proposed protocols for testing pesticides on brood (Aupinel et al., 2007a, b; Hendriksma et al., 2011), seems a more realistic simulation of what may happen in a honey bee colony growing in an intensive farming area. The adopted repeated dose approach could anyhow be considered more as a chronic toxicity test than as an acute toxicity test; therefore, the use of Kaplan-Meier survival dynamic curves to depict the mortality increase, and of log-rank tests to compare them, appear fully justified. Since the untreated control mortality was higher than the optimal levels suggested in the literature (Aupinel et al., 2005 and 2009), the more restrictive value of α = 0.01 was preferred to the usual α = 0.05 to evidence statistical significance. Under such conditions, the lowest tested concentration could be regarded as the NOAEC for thiamethoxam on brood in the adopted experimental conditions.

LC50 figures obtained by us are of an order of magnitude lower than those reported by Tavares et al. (2015) for Africanized honey bees. Different responses to toxic compounds have been evidenced between honey bee strains (Ladas, 1972; Mansour and Al-Jalil, 1985; Suchail et al., 2000 Laurino et al., 2013), but in this case, the adopted experimental designs—single dose vs repeated doses—should account for the difference.

The use of LC50—and/or the derived LD50—values to express the results of a repeated dose toxicity test could be somehow questionable, since they are more often derived from acute toxicity tests. In any case, they prove to be rather useful when comparing laboratory results with a realistic landscape-level exposure to pesticides. Honey bee larvae are exposed to pesticides chiefly through the food nurse bees give them since the amounts of pollen and honey given to them is very low. Nurse bees may eat contaminated pollen and nectar and thus produce larval food containing pesticides (Rortais et al., 2005). Therefore, effective exposure levels are difficult to determine. To overcome these difficulties, the EFSA guidance document on the risk assessment of plant protection products on bees (European Food Safety Authority, 2013b) proposes various shortcut values (SV) to be used for the estimation of oral exposure via nectar and pollen consumption under different scenarios. Since the reported EFB-like symptoms had been observed in field apiaries during maize sowing, the SVs proposed by EFSA for the adjacent crop (4.4 μg/larva) and/or field margin (2.2 μg/larva) scenarios can be considered as the most appropriate and should be chosen among the various SVs relative to honey bee larvae. These SVs refer to an a.i. application rate of 100 mg/m2, while the maximum application rate allowed for maize seed dressing in Italy was 6.3 mg/m2 only (European Food Safety Authority, 2013a); therefore, the SVs should be reduced to 272 and 136 ng/larva respectively. In any case, it should be noted that such SVs are to be considered as a worst-case scenario. Since the LD50 values obtained in the present study are lower than the suggested SVs, it is likely that a widespread use of dressed seeds could expose honey bee larvae to dangerous thiamethoxam concentrations. Therefore, extensive brood mortality and colony weakening would likely occur.

Various sublethal effects of pesticides on honey bee brood have been reported in the literature (Desneux et al., 2007; Wu et al., 2011; Blacquière et al., 2012; Simon-Delso et al., 2014), and some of them, like the delay in pupation and in adult emergence, were observed also during this research. On the contrary, developmental troubles leading to the emergence of deformed adults and the extremely rare—and therefore not statistically significant—appearance of pupae that are still enclosed in the larval integument were not commonly observed and seem to be rather unlikely for neurotoxic insecticides like thiamethoxam.

Notes

Acknowledgements

The authors wish to thank Dr. Noa Simon-Delso for her helpful criticism on the earlier draft of the manuscript.

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Copyright information

© INRA, DIB and Springer-Verlag France 2017

Authors and Affiliations

  1. 1.Dipartimento di Scienze Agrarie, Forestali e AlimentariUniversità di TorinoTurinItaly

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