Reduction of pesticide use can increase earthworm populations in wheat crops in a European temperate region

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In: Agriculture, Ecosystems and Environment, 2013, 181, pp.223-230. Agricultural intensification has led to reduced soil biodiversity in arable lands. The potential benefits from organic farming and from low-input cropping systems have not yet been precisely assessed. Earthworm, having important agro-ecological functions, may be affected by pesticide applications, especially those species living mainly in the surface soil layer. We used a five-year experimental database including conventional and organic cropping systems to establish simple relationships between the Treatment Frequency Index - a phytosanitary indicator of pesticide pressure - and the abundance of three important earthworm species. We found that insecticides have more negative influence on earthworm species than herbicides and fungicides, and that species living in the soil's surface layer were the most affected by pesticides. Density of these earthworm species could be multiplied by a factor 1.5-4 if the Treatment Frequency Index was halved, as is currently required by some European regulations. Our results thus demonstrate that a reduction in pesticide application would increase earthworm population density in agricultural fields.
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Reduction of pesticide use can increase earthworm populations in wheat crops in a European
temperate region
a, a b c a d e C. Pelosi *, L. Toutous , F. Chiron , F. Dubs , M. Hedde , A. Muratet , J.-F. Ponge , S.
e f,g Salmon , D. Makowski
a INRA, UR251 PESSAC, F-78026 Versailles cedex, France
b Museum national d‟Histoire naturelle, UMR 7204 MNHN-CNRS-UPMC. 55 rue Buffon,
75005 Paris, France
c IRD, UMR BIOEMCO, Centre France Nord, 93143 Bondy Cedex, France
d ODBU, Observatoire départemental de la Biodiversité urbaine, Direction de la Nature, des
Paysages et de la Biodiversité, Conseil général de la
Département, F-93006 Bobigny Cedex, France
Seine-Saint-Denis, Hôtel du
e Muséum National d‟Histoire Naturelle, CNRS UMR 7179, 4 Avenue du Petit-Château,
91800 Brunoy, France
f INRA, UMR211 Agronomie, BP 01, F-78850 Thiverval-Grignon, France
g AgroParisTech, UMR211 Agronomie, BP 01, F-78850 Thiverval-Grignon, France
* Corresponding author: UR 251 PESSAC INRA, Bâtiment 6, RD 10, 78026 Versailles
cedex,
France.
Tel:
(+33)1.30.83.36.07;
celine.pelosi@versailles.inra.fr
Fax:
(+33)1.30.83.32.59.
E-mail
address:
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Abstract
Agricultural intensification has led to reduced soil biodiversity in arable lands. The potential
benefits from organic farming and from low-input cropping systems have not yet been
precisely assessed. Earthworm, having important agro-ecological functions, may be affected
by pesticide applications, especially those species living mainly in the surface soil layer. We
used a five-year experimental database including conventional and organic cropping systems
to establish simple relationships between the Treatment Frequency Index - a phytosanitary
indicator of pesticide pressure - and the abundance of three important earthworm species. We
found that insecticides were more harmful to earthworms than herbicides and fungicides, and
that speciesliving in the soil‟s surface layer were the most affected by pesticides.Lumbricus
castaneus density could be quadrupled if the Treatment Frequency Index was halved, as is
currently required by some European regulations. Our results thus demonstrate that a
reduction in pesticide application would strongly increase earthworm population density in
agricultural fields.
Keywords:Earthworm density; Treatment Frequency Index; Organic farming; Conventional
cropping system; Pesticides
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1. Introduction
Agricultural intensification has reduced soil biodiversity in cultivated fields (Bengtsson et
al., 2005; Doran and Zeiss, 2000; Hubbard et al., 1999). Organic and low-input cropping
systems have been proposed as alternatives to intensive agricultural practices to limit the
impact of chemicals on human health and on the environment (Bengtsson et al., 2005; Hole et
al., 2005). However, the effects of a reduction of pesticide applications on biodiversity and
particularly on soil organisms need further investigation (Hole et al., 2005).
Earthworms represent a large proportion of soil biomass, i.e. up to 80% of fresh weight
(Yasmin andD‟Souza, 2010) and ensure important agro-ecological functions since they
influence organic matter dynamics and soil structure (Edwards and Bohlen, 1996; Sims and
Gerard, 1999). Earthworms are recognized as ecosystem engineers because they influence the
availability of resources to other species (Jones et al., 1994) and have positive effects on
organic matter dynamics and soil structure (Edwards and Bohlen, 1996). They are also
considered as bioindicators of soil biological functioning (Paoletti, 1999). Bouché (1972)
separated earthworms into three categories, basedon morphological
and behavioral
characteristics. Epigeic species, e.g.Lumbricus castaneus, are litter-dwellers living and
feeding on or near the soil surface. Anecic earthworms live in permanent vertical burrows
within the soil and may emerge to feed on surface litter, e.g.Lumbricus terrestris. Endogeic
species e.g.,Allolobophora chlorotica, live in temporary horizontal burrows and feed on the
soil. This species is geophagous since it gains its nutrients by eating the soil and the green
morph is characterized by Bouché (1972) as more epigeic.
Laboratory studies have shown that earthworms are exposed to pesticides through
ingestion or epidermal contact (Rodriguez-Castellanos and Sanchez-Hernandez, 2007;
Yasmin and D'Souza, 2010). Little is known about the effects of earthworm exposure to
pesticides in cultivated fields because most studies were conducted under laboratory
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conditions (Frampton et al., 2006; Yasmin and D'Souza, 2010) and cannot be easily
extrapolated to field conditions (Lowe and Butt, 2007; Svendsen and Weeks, 1997). Field
studies which compared earthworm communities in organic and conventional systems have
shown variable results (Hole et al., 2005; Nuutinen and Haukka, 1990), mainly due to
confounding factors such as variation in soil tillage, manure inputs or crop types (Hole et al.,
2005). We decided to study the effect of pesticide use in agricultural fields involving
conventional plowing and the same crop, i.e. winter wheat, on three earthworm species:L.
castaneus,L. terrestris and A. chlorotica which are widespread in Europe and variably in
contact with the soil surface and thus potentially exposed to pesticides (Römbke et al., 2004).
These species belong to the three ecological categories mentioned above and are involved in
the decomposition of surface and soil organic matter and in soil structure maintenance.
Pesticide risk assessment for human health and the environment has become a major
concern for scientists, politicians and civil society (Pingault et al., 2009; Sattler et al., 2007).
In Denmark the Treatment Frequency Index (TFI) was developed (Gravesen, 2003;
Jørgensen, 1999; Jørgensen and Kudsk, 2006) for the assessment of pesticide pressure at
different scales, from field to national level (Butault et al., 2011; Ferti Ouest 88, 2009). TFI is
defined as the mean number of treatments per hectare with commercial products, weighted by
the ratio of the dose used to the recommended dose (Pingault, 2007). TFI is easy to calculate
and operational at different levels, since it allows the aggregation of very different substances
to measure overall phytosanitary pressure (Butault et al., 2011). This indicator requires
investigations on pesticide use in agricultural fields.
This study aims at i) establishing statistical relationships between the pressure indicator
TFI and impact indicators for soil fauna, i.e. densities of three earthworm species variably in
contact with the soil surface, ii) using these relationships to estimate threshold values of TFI
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leading to an effect on earthworm densities, and iii) using these relationships to estimate the
effects of reduced pesticide use on earthworm densities.
2. Materials and methods
2.1. Sites and cropping systems
Field data were collected for 15 site-years with conventional cropping systems and 15
site-years with organic systems. A site-year is a unique combination of a site and a year.
Study sites were located in two agricultural areas of the Ile-de-France region and sampled
between 2005 and 2012 (Appendix A).
Eleven conventional and eleven organic sites were studied in 2012 in the department of
Seine-et-Marne, east of Paris, on clay loamy soils with 70% silt, 25% clay and 5% sand and a
neutral pH (Appendix A).
Four conventional site-years and four organic site-years were studied in 2005, 2006, 2007
and 2011 from a trial located in Versailles, 15 km south-west of Paris, on silty clay soils with
58% of silt, 17% of clay and 25% of sand and a neutral pH (Appendix A).
No significant differences of texture, pH, organic matter and C/N ratio were found
(p>0.05) between organic and conventional systems (ANOVA, R version 2.15.3, 2013, data
from Appendix A).
The climate in both study areas is oceanic temperate with a mean annual precipitation of
640 mm and a mean annual temperature of 10.4 °C.
A conventional plowing at 25-30 cm depth was performed in all fields, at a frequency
ranging from every year to once every three years. The last plow was performed in 2010 or
2011, depending on the fields. All fields were cultivated with winter wheat at the time of
sampling. The levels of mineral fertilizers applied were quite similar across conventional
fields. No organic input was applied in organic and conventional fields in Versailles. In Seine-
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et-Marne, six organic fields and six conventional fields received organic inputs (poultry and
cattle manure, vegetable wastes or vinasse depending on the field). Some farms included both
fields under organic and conventional farming. This may explain why organic inputs were
similar. Moreover, the number of organic applications and the density of the three earthworm
species were not significantly correlated.
2.2. TFI calculation
Based on surveys conducted with field managers (farmers in Seine-et-Marne or the trial
manager in Versailles), the name of the pesticides used, including insecticide, herbicide and
fungicide treatments, the number of applications and the rate applied to the fields were used to
calculate the TFI. The index was calculated over one year before each sampling date because
mean Dissipation Time 50 (DT50) and mean DT90 in the field (i.e. time for respectively 50%
and 90% disappearance of the active ingredients applied at specific initial concentrations in
the field, in all our experimental fields), were respectively 2 and 8.5 months (PPDB, 2012)
(Appendix B).
TFI was calculated using the following formula: TFIfield= Σ(AD / HD),where AD is the
amount of pesticide applied in a field per hectare and HD is the recommended rate per hectare
(Ministère de l‟Agriculture et de la Pêche, 2008). Four types of TFI were calculated, namely
TFI Herbicide, TFI Insecticide, TFI Fungicide and TFI Total which is the sum of the three
TFIs (Appendix C). TFIs are equal to 0 in organic fields because no chemical pesticides were
applied.
2.3. Earthworm sampling method
Sampling was performed on each site on ten replicates in 2005, 2006, 2007 and 2011, and
on three replicates in 2012 (see Appendix A for sites concerned) using both chemical
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extraction and hand-sorting of earthworms (Pelosi et al., 2009). After removing the vegetation
on the ground surface, two applications of 3.2 l of a diluted expellant solution of allyl
isothiocyanate (AITC) was applied to the soil at 10-min intervals within a 40 x 40 cm metal
-1 frame. AITC was first diluted with isopropanol (propan-2-ol) to obtain a 5 g l solution
(Pelosi et al., 2009; Zaborski, 2003). This solution was then diluted with water to reach a
-1 concentration of 0.1 g l . After collecting emergent individuals during 20 minutes, a 40 cm x
40 cm x 20 cm-depth block of soil was excavated and remaining earthworms were hand-
sorted from the soil. Earthworms were preserved in 4% formalin solution. All individuals
(juveniles, sub-adults and adults) were counted. Sub-adults and adults were identified at
species level according to the identification key of Sims and Gerard (1999). Juveniles were
also identified at species level thanks to morphological characteristics of the species and to
the specific form they take in formalin in comparison with that of identified adults. We
focused on three earthworm species found in cultivated fields (Bouché, 1972).Lumbricus
castaneus, which may be also found occasionally within the soil profile, is an epigeic species
living mainly at the soil surface.Lumbricus terrestrisis an anecic species feeding on the soil
surface but living deeper in the soil. Sampled individuals ofthe third species, the endogeic
Allolobophora chloroticapresented a green coloration which is more epigeic than the albinic
form (Bouché, 1972). The green form ofA. chloroticais commonly found in the top 5 cm of
the soil.
2.4. Statistical Analysis
The response variable was the density of earthworms per m². This variable was related to
TFI using two statistical methods. The first method was based on Poisson log-linear
regression. A Poisson model relating earthworm density to TFI was fitted for each species
using theglm function of R (Venables and Ripley, 2002). A separate regression model was
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fitted for each type of TFI (corresponding to herbicide, insecticide, fungicide separately, and
to all three pesticides together) leading to four different regression models per earthworm
species. Each model relates the expected earthworm density to TFI as follows:
TFI i i EYei
whereYiis the density of earthworms of speciesi, E(.) is the expected value,αiandβiare two
parameters corresponding to the log density for TFI=0 (i.e., maximum of the log density ifβi
<0) and to the TFI effect respectively. Estimated parameter values, their standard deviations,
and their associated p-values were used to analyze the effect of TFI on earthworm density and
its interaction with the species. In order to assess the robustness of the results to the dataset
characteristics, parameter estimation was repeated with a restricted dataset including the 22
sites located in Seine-et-Marne. The Akaïke Information Criterion (AIC) was computed for
model with and without TFI variables and models including TFI showed better (i.e., lower)
AIC values. The significance of the differences of the estimated TFI-effects across species
was tested by including a species-effect and a TFI-effect (main effect and interaction) in the
Poisson log-linear regression model, and by testing the significance of the interaction. The
fitted models were used in three different ways. First, the models were used to estimate
st rd earthworm densities for low and high TFI values (equal to the 1 and 3 quartiles of TFI data
of our dataset respectively). Second, the models were used to calculate the TFI values leading
to 50% and 75% of the earthworm densities obtained for TFI=0 (i.e, without pesticide
application). Third, the models were used to assess the consequences of a reduction of 50% of
the mean TFI values measured in France in 2006 according to Jacquet et al. (2006).
In the second method, a non-parametric technique was used to estimate the relationship
between earthworm density and TFI. A polynomial quadratic regression was fitted locally
using the loess function of R (Cleveland et al., 1992). With this approach, a quadratic function
is fitted locally at each TFI value x using data weighted by their distance to x. As the
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quadratic function is applied locally, the overall relationship between density and TFI can
take various shapes depending on the data distribution. Local regression was applied for each
type of TFI and each earthworm species separately. Like Poisson regression models, fitted
response curves were used to estimate earthworm densities for low and high TFI values and to
estimate TFI thresholds.
Contrary to Poisson regression, the non-parametric method does not rely on any
assumption about the probability distribution of the data. However, non-parametric methods
generally produce less accurate estimated values with small datasets. Results obtained with
the two methods were compared in order to assess the robustness of the conclusions to the
statistical technique used to analyze the data.
3. Results
A. chlorotica,L. castaneus, andL. terrestrisdensities ranged from 0 to 135, 105, and 44
-individuals m ², respectively, and the TFI Total in conventional sites ranged from 1.6 to 7.0
(mean = 4.1) (Fig. 1). When TFI Total was 0, mean values of earthworm densities were 25.0
-± 37.8, 7.5 ± 27.0, and 5.6 ± 12.4 individuals m ² forA. chlorotica,L. castaneus, andL.
terrestrisrespectively (Fig. 1).
Estimated values ofβii.e., TFI effect on earthworm density, are presented inTable 1. The
values of this parameter correspond to the effects of a one-unit increase of TFI on the log
earthworm density. TFI Total, TFI Herbicide, TFI Insecticide, and TFI Fungicide exerted
significant negative effects on earthworm densities for the three considered species (Table 1).
TFI effect differed significantly between the three species for all TFI categories (p<0.05), and
was invariably higher forL. castaneus for all the TFIs compared toL. terrestris andA.
chlorotica. TFI effects were always the lowest forA. chlorotica, effects onL. terrestrisbeing
intermediate (Table 1).
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The effect of TFI Insecticide was the largest for all three species (Table 1). ForL.
castaneus, TFI Fungicide had a stronger effect than TFI Herbicide while the opposite result
was obtained forL. terrestrisandA. chlorotica(Table 1). In order to assess the robustness of
the results to the dataset characteristics, parameter estimation was repeated with a dataset
restricted to the 22 sites located in Seine-et-Marne. Results obtained with the full and the
restricted datasets are compared in Table 1. The results obtained forA. chlorotica andL.
terrestisshow that the TFI effect is still significant (p<0.05) even when the data obtained in
the trial are excluded from the analysis. The ranking of these species are similar with the full
and the restricted datasets for all type of TFI. In addition, results obtained with the restricted
dataset confirm that TFI Insecticide had a stronger effect on earthworm density than the other
types of TFI. It was not possible, to fit the model forL. castaneuswith the restricted dataset
because only one non-zero data was included in this dataset for this species.
With the Poisson regression model, densities ofL. castaneus reached values below 1
-individual m ² when TFI Total, TFI Herbicide, TFI Insecticide, and TFI Fungicide were 2.8,
1.7, 0.9, and 1.0 respectively. Estimated density for L. terrestris reached values below 1
-individual m ² when TFI Total, TFI Herbicide, and TFI Insecticide were 5.8, 2.9, and 1.9,
-respectively but did not reach values below 1 individual m ² for TFI Fungicide values
considered in our dataset (Fig. 2). Estimated densities ofA. chlorotica were always above 1
-individual m ² for the observed TFI values, but strongly decreased at high TFI.A. chlorotica
densities were 23.7%, 18.6%, 31.8% and 43.4% of the maximum estimated density values
when TFI Total, TFI Herbicide, TFI Insecticide, and TFI Fungicide reached the highest values
reported in the dataset (Fig. 2).
Results obtained with the two statistical methods were similar (Table 2). Earthworm
densities estimated for TFI = 0 using Poisson and non-parametric regressions were almost
identical. When TFI Total, TFI Herbicide, TFI Insecticide, and TFI Fungicide were 4.5, 2.4,
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1.0, and 1.0 respectively (i.e. the third quartiles of TFI in the dataset), Poisson and non-
parametric models again showed similar earthworm density values (Table 2). Differences
were greater for the density estimates obtained forA. chloroticaand for the third quartile of
TFI Herbicide and Fungicide. In this case, the Poisson models led to a lower estimate ofA.
chloroticadensity for the third quartile of TFI Herbicide and to higher estimated density for
the third quartile of TFI Fungicide (Table 2) compared to non-parametric estimated values.
Standard errors of non-parametric models were higher than those obtained with Poisson
models, due to the relatively small size of our dataset (Table 2).
Using both models, threshold values to maintain 50% and 75% of the maximum density
of the three species were calculated for the four TFI categories (Table 3). Each species
showed different threshold values for the four TFI categories,L. castaneus showing the
lowest thresholds (except in one case, for TFI Insecticide with the non-parametric model,
where thresholds for 50% of the maximum density forL. castaneusandL. terrestriswere 0.3
and 0.2 respectively) andA. chloroticausually the highest ones (except for TFI Total and TFI
Herbicide with the non-parametric model, for which thresholds forL. terrestriswere higher
than those ofA. chlorotica). Intermediate threshold values were obtained forL. terrestris. The
lowest threshold values were usually obtained for TFI Insecticide (except for 50% ofA.
chloroticadensity with the non-parametric model, where thresholds of TFI maximum
Insecticide and TFI Fungicide were 0.9 and 0.5 respectively).
According to Jacquet et al., (2011), mean TFI Total in 2006 in France was 3.8, which
-corresponds to an estimated density of 0.5 ± 0.2, 2.3 ± 0.4, and 11.4 ± 0.9 individuals m ² for
L. castaneus,L. terrestris, andA. chlorotica respectively, using Poisson models (Table 4).
According to the fitted models, 50% reduction of the TFI target (proposed by the French
government for 2018, Butault et al., 2011) would increaseL. castaneus,L. terrestris, andA.
chloroticadensities by a factor 3.8, 1.4, and 1.5 according to Poisson models and by a factor
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