OBJECTIVE: Tetranychus cinnabarinus (Boisduval) is an agricultural mite pest threatens crops throughout the world, causing serious economic loses. Exploring the effects of acaricides on predatory mites is crucial for the combination of biological and chemical control of T. cinnabarinus. Neoseiulus californicus (McGregor) is one of the principal natural enemies of T. cinnabarinus, which can be applied in protected agriculture. In this study, the effects of sublethal concentrations of a new acaricide, SYP-9625 on two mite species, and the effects of the application concentration on predatory mite, N. californicus were assessed. The aim of the present study was to evaluate the effect of SYP-9625 on life parameters and predation capacity of N. californicus based on the concentration-response bioassay of T. cinnabarinus to explor the application of the new acaricide with natural enemy N. californicus. METHOD: All of the experiments were conducted under laboratory conditions [25 ± 1°C, 16: 8 h (L: D) and 75 ± 5% RH]. The sublethal concentrations LC10 (0.375μg/mL) and the LC30 (0.841μg/mL) against T. cinnabarinus and the application concentration (100μg/mL) against N. californicus were used to evaluate the effects of SYP-9625 on population parameters of N. californicus based on an age-stage, two-sex life table and its predation capacity by functional response. RESULT: cinnabarinus females treated with LC30 exhibited significantly reduced net reproductive rates (R0 = 11.02) in their offspring compared with females treated with LC10 (R0 = 14.96) and untreated females (R0 = 32.74). However, the intrinsic rate of increase (rm) and the finite rate of increase (λ) of N. californicus indicated that the application concentration of SYP-9625 had no significant negative effect on N. californicus eggs (rm = 0.277, λ = 1.319) compared to the control (rm = 0.292, λ = 1.338). Additionally, most population parameters of N. californicus showed a dose-dependent manner with the increase of the concentration of SYP-9625 against T. cinnabarinus. SYP-9625 also stimulated the control efficiency of N. californicus against immobile stages including eggs and larvae. CONCLUSION: This study demonstrated that sublethal concentrations of SYP-9625 can inhibit the population growth of T. cinnabarinus. In addition, the sublethal concentrations and the application concentration showed no effect on the population growth of N. californicus. These two advantages described above showed great commercial potential of this new acaricide based on population parameters of the two mite species and predation capacity of the predatory mite under laboratory conditions.
OBJECTIVE:Tetranychus cinnabarinus (Boisduval) is an agricultural mite pest threatens crops throughout the world, causing serious economic loses. Exploring the effects of acaricides on predatory mites is crucial for the combination of biological and chemical control of T. cinnabarinus. Neoseiulus californicus (McGregor) is one of the principal natural enemies of T. cinnabarinus, which can be applied in protected agriculture. In this study, the effects of sublethal concentrations of a new acaricide, SYP-9625 on two mite species, and the effects of the application concentration on predatory mite, N. californicus were assessed. The aim of the present study was to evaluate the effect of SYP-9625 on life parameters and predation capacity of N. californicus based on the concentration-response bioassay of T. cinnabarinus to explor the application of the new acaricide with natural enemy N. californicus. METHOD: All of the experiments were conducted under laboratory conditions [25 ± 1°C, 16: 8 h (L: D) and 75 ± 5% RH]. The sublethal concentrations LC10 (0.375μg/mL) and the LC30 (0.841μg/mL) against T. cinnabarinus and the application concentration (100μg/mL) against N. californicus were used to evaluate the effects of SYP-9625 on population parameters of N. californicus based on an age-stage, two-sex life table and its predation capacity by functional response. RESULT: cinnabarinus females treated with LC30 exhibited significantly reduced net reproductive rates (R0 = 11.02) in their offspring compared with females treated with LC10 (R0 = 14.96) and untreated females (R0 = 32.74). However, the intrinsic rate of increase (rm) and the finite rate of increase (λ) of N. californicus indicated that the application concentration of SYP-9625 had no significant negative effect on N. californicus eggs (rm = 0.277, λ = 1.319) compared to the control (rm = 0.292, λ = 1.338). Additionally, most population parameters of N. californicus showed a dose-dependent manner with the increase of the concentration of SYP-9625 against T. cinnabarinus. SYP-9625 also stimulated the control efficiency of N. californicus against immobile stages including eggs and larvae. CONCLUSION: This study demonstrated that sublethal concentrations of SYP-9625 can inhibit the population growth of T. cinnabarinus. In addition, the sublethal concentrations and the application concentration showed no effect on the population growth of N. californicus. These two advantages described above showed great commercial potential of this new acaricide based on population parameters of the two mite species and predation capacity of the predatory mite under laboratory conditions.
Nowadays, agricultural spider mite pests are becoming one of the major threats to some important crops such as vegetables, fruits and ornamentals throughout the world. Most spider mite pests, such as Tetranychus cinnabarinus (Boisduval), have gained rapid resistance resulting from frequent applications of acaricides [1, 2]. Therefore, new acaricides with excellent insecticidal activity and low toxicity to natural enemies are becoming necessary [3].In integrated pest management (IPM) systems, natural enemies and compatible acaricides can be applied in a conjunct group, and a proportion of studies tend to paying more attention to the toxicity of acaricides on predatory mites [3-7]. Based on the inter-population differences in the sensitivities of these natural enemies, Lima evaluated different acaricide toxicities against Neoseiulus barkeri (Hughes) and suggested that fenpyroximate and chlorfenapyr can be used together with the predatory mite application [4, 8]. Recently, the sublethal effects of acaricides have been considered a more accurate approach to measure toxicity than direct contact toxicity [9]. Mollaloo investigated the effect of three lethal concentrations pyridaben on the developmental and reproductive parameters of Neoseiulus californicus (McGregor), which confirmed that the maneuverability about the combination of natural enemies such as phytoseiid predators with compatible acaricides is the key to decrease not only chemical applications but also the environmental hazards [10]. Furthermore, pest suppression by a predator species strongly depends on two major components of predator-prey interactions: the predators’ numerical and functional responses [11, 12]. Pesticide exposure can significantly influence the functional response of predators, so many studies have assessed the effects of pesticides on the functional response of predatory mite species [13]. For example, Poletti reported that although acetamiprid did not affect the functional responses of N. californicus, it weakened the predation capacity of Phytoseiulus macropilis (Banks) [4].The predatory mite N. californicus is one of the principal natural enemies of tetranychid mites in several countries andpromotes the efficient control of those mites in several crops [8]. Moreover, N. californicus exhibits broad environmental tolerance, and is used to manage pest mites in many countries, thus demonstrating the great biological control potential of N. californicus [14-17].SYP-9625 is a new acaricide which has been registered as the commercial formulation, TC 98% in China. It is one of a series of novel pyrazolyl acrylonitrile derivatives that has shown excellent acaricidal activity against T. cinnabarinus and very low toxicity to mammals [2]. Before promoting this new acaricide, it is important to evaluate its effects of applying on the pest mites as well as the natural enemy N. californicus under laboratory conditions to determine the reasonable concentration of SYP-9625 that has excellent insecticidal activity and low toxicity to N. californicus is also crucial. This study investigated the sublethal effects of the new acaricide SYP-9625 on two mite species and the effects of the application concentration on population parameters of N. californicus based on the two-sex age specific life tables. The functional response of N. californicus exposed to SYP-9625 was also assessed to evaluate its predation capacity.
Materials and methods
Insect cultures
The N. californicus colony was originally sampled in Sichuan Province, China in 2010 and was reared on detached kidney bean plants (Phaseolus coccineus L.) infested with T. cinnabarinus in the laboratory conditions. The T. cinnabarinus colony was collected from a farm located at Sichuan Agricultural University, China. Glass petri dishes (9 cm in diameter) were used to construct rearing arenas that were sealed using plastic wrap. A thin cotton layer was placed at the bottom of the Petri dish, and an upturned bean leaf was placed on the saturated cotton and surrounded with water to prevent the escape of the mites. The kidney bean leaves were replaced every week. All tests were conducted in the laboratory at a photoperiod of 16: 8 h (L: D), 25 ± 1°C and 75 ± 5% RH [3].
Chemical tested
SYP-9625 is a new acaricide that has been registered as the commercial formulation, TC 98% in China. It was synthesized by Yu et al., to target T. cinnabarinus and was obtained from Shenyang Sinochem Agrochemicals R & D Company, Ltd. SYP-9625 is one of a series of novel pyrazolyl acrylonitrile derivatives under an international patent that names a pyrazolyl acrylonitrile compounds and uses thereof [16]. The CAS number is 1253429-01-4 [18]. The application number is WO2010CN72224 20100427 and Priority number is CN2009183205 20090429. Yu investigated the syntheses and bioactivities of SYP-9625 and demonstrated its excellent acaricidal activity against T. cinnabarinus and its low acute toxicity to mammals.
Selection of sublethal concentrations of SYP-9625
A modified leaf-residue method was used to determine the response of T. cinnabarinus to numerous concentrations of SYP-9625 which were based on initial range-finding test. Bean leaf disks (2 cm in diameter) were immersed for 5 s in solutions of SYP-9625 or a control (0.05% Tween 80 aqueous solution) and allowed to air dry. After eclosion, healthy T. cinnabarinus females were transferred onto the bean leaf disks. After 24 h, mites were separated onto untreated leaf disks to mate with males from the stock colony. Every 12 h, the fecundity of females was recorded until the females died naturally [3]. There were 30 individuals per replicate and four replicates per concentration.A modified leaf dip method [19] was used to test the response of T. cinnabarinus eggs to the concentrations of SYP-9625 described above. 30 N. californicus female adults after coupled with males were placed on leaves for 12 h to allow oviposition and then were removed. Bean leaves with 50 eggs were then dipped for 5 s in solutions of SYP-9625 or a control (0.05% Tween 80 aqueous solution) and then placed upside down on a wet cotton pad soaked with distilled water. Eggs were checked daily and hatched in the laboratory. There were four replicates per concentration.These two methods were also used for assessing the response of N. californicus females and eggs to the application concentration of SYP-9625 (100 μg/mL) and ten times the application concentration (1000 μg/mL).
Experimental set up
All bioassays were carried out on primary bean leaf discs positioned upon moistened cotton wads in Petri dishes or tissue culture plates with the surface upward. Mites fear water, especially the predator mites. Therefore, water and the cotton soaked by water were used to prevent mites escape from bean leaf discs. This traditional method has been used in many other studies, including Alinejad M 2014 et al. and Hamedi N 2011 et al. [3, 5, 20].To assess the effects of sublethal concentrations of SYP-9625 on bean leaf disks (2 cm in diameter) were immersed for 10 s in sublethal concentrations (LC10 and LC30) or a 0.05% Tween 80 aqueous solution (control) and allowed to air dry. The subsequent processes were the same as those used for the selection of sublethal concentrations. Approximately 100 to 120 eggs were retained and transferred onto untreated bean leaf disks. The population parameters were recorded every 12 h after the eclosion for both sexes. The female offspring were mated with males from the stock colony and all indices were recorded until the females died naturally [3, 21].To assess the effects of the application concentration on , a 3.5 cm diameter leaf disk with adequate quantities of T. cinnabarinus at each life stage as well as 30 N. californicus female adults after coupled with males were placed on leaves for 12 h to allow oviposition and then were removed. Bean leaves with 35 eggs were dipped in the solution with the application concentration (100 μg/mL) for 5 s and then placed upside down on a wet cotton pad soaked with distilled water. Eggs were checked daily and hatched in the laboratory. After hatching, the larvae were separated onto the untreated 2 cm diameter leaf disks using a 0.05% Tween -80 aqueous solution as a control. Population parameters were recorded every 12 h after eclosion for both sexes; all indices were recorded until all females died [22].The effects of the application concentration on The treatment method and setup were same as the experimental design for the determination of sublethal effects of SYP-9625 concentrations on T. cinnabarinus and its offspring from treated females.A modified method was conducted to assess the indirect effect on SYP-9625. We fed N. californicus on treated females of T. cinnabarinus and evaluated the population parameters of predatory mites. Sufficient quantities of eggs of N. californicus fed on untreated T. cinnabarinus were collected over 24 h. When N. californicus grew to the deutonymph life stage, enough T. cinnabarinus females were treated with sublethal concentrations (LC10 and LC30) or with a 0.05% Tween-80 aqueous solution (control) using the same method as described above. After 24 h, N. californicus were fed on treated T. cinnabarinus, and N. californicus females were mated with males from the stock colony. Population parameters were then recorded every 12 h for both sexes and all indices were recorded until the females died.There were 60 individuals of N. californicus per replicate and four replicates per concentration.To assess the effects of the application concentration on the functional response of , bean leaf disks (4 cm in diameter) were immersed in the application concentration (100 μg/mL) or a 0.05% Tween-80 aqueous solution (control) and allowed to dry. Healthy N. californicus females were transferred onto the treated and untreated bean leaf disks within 12 h of copulation. After 24 h, they were individually transferred onto untreated bean leaf disks (1 cm×0.5 cm) and fed with T. cinnabarinus at each life stage. Egg and nymphal densities were 10, 15, 20, 25, and 30 per leaf. Larval densities were 10, 20, 30, 40, and 50 per leaf. Adult densities were 10, 15, 20, 25, and 30 per leaf. All leaves were placed in centrifuge tubes (2 ml) that were specially constructed to prevent mites from escaping [23].To assess the functional response of healthy N. californicus females were individually introduced onto freshly cut leaf disks (2 mm×5 mm) that were placed in centrifuge tubes (0.5 ml) 12 h after copulation, starving for 24 h. T. cinnabarinus at all stages were treated for 24 h with sublethal concentrations (LC10 and LC30) of SYP-9625 or a 0.05% Tween -80 aqueous solution (control) using the same method described for determining the effect of sublethal concentrations on T. cinnabarinus and its offspring from treated females. T cinnabarinus were transferred onto leaf disks (1 cm×0.5 cm) with separately treated N. californicus using the same densities described above (see effects of the application concentration on the functional response of N. californicus).There were five replicates per concentration. The functional response of N. californicus was observed and recorded after 24 h.
Statistical analysis
The means and standard errors of the population parameters were estimated using a paired bootstrap test (TWOSEX-MS Chart) procedure [24] because it uses random resampling. The use of few replications can generate variable means and large standard errors (P < 0.05); thus, we used 10,000 replications.The functional response of N. californicus to the various prey stages and densities were expressed by fitting Holling’s equation to the data [25-27]:Where Na is the number of prey attacked, T is the experimental time (1h), N is the initial number of prey offered, a is the searching (attack) rate, and T is the handling time. Mean values of T were used to calculate the maximum attack rate defined as T/Th. The control efficiency of natural enemies can be represented by a/Th, as there is a positive correlation between a/Th and the control efficiency of natural enemies [28]. The searching rate, handling time and their asymptotic standard errors were estimated from nonlinear regressions of the disk equation. SAS statistical software was used to analyze the functional responses of N. californicus.
Age-stage, two-sex life table
The raw data of the life table parameters were assessed with an age-stage, two-sex life table [29-34] using the computer program TWOSEX-MS Chart [35]. The age-stage specific survival rate (s) (where x = age in days and j = stage), female age-specific fecundity (f), age-specific survival rate (l), age-specific fecundity (m), m for the total population, age-specific maternity (lm) and the population growth parameters [the intrinsic rate of increase (r), the finite rate of increase (λ), the net reproductive rate (R), the gross reproductive rate (GRR), the mean generation time (T) and the doubling time (DT)] were calculated accordingly [3, 36].
Results
Determination of sublethal concentrations
The sublethal concentrations of SYP-9625 were chosen from the 24 h acute concentration-response relationship generated for adult females of T. cinnabarinus (Table 1) [9]. The LC50 of SYP-9625 on adult females and eggs were 0.466 μg/mL and 1.472μg/mL, respectively. The sublethal concentrations, including the LC10 (0.375μg/mL) and the LC30 (0.841μg/mL) were determined using a probit procedure (SAS Institute 2002) for the subsequent experiments and are summarized in Table 1. The regression equation of concentration-mortality for females was Y = 1.447+4.365X, [Y = mortality (probit), X = the log10 of concentration] (Table 1). No mortalities were recorded in the controls.
Table 1
Bioassay on different stages of T. cinnabarinus treated with SYP-9625.
Stage
LC-P line (y = )
Correlation coefficient(r)
x2
LC50/95%CL(μg/mL)
LC30/95%CL(μg/mL)
LC10/95%CL(μg/mL)
Female
1.447+4.365x
0.9945
3.219
0.466(0.442~0.492)
0.353(0.332~0.374)
0.237(0.216~0.256)
Nymph
5.311+10.994x
0.9975
0.537
0.329(0.316~0.341)
0.295(0.279~0.307)
0.251(0.232~0.267)
Larva
2.003+4.746x
0.9930
2.372
0.378(0.357~0.404)
0.293(0.275~0.331)
0.203(0.182~0.221)
Egg
-0.362+2.157x
0.9950
1.244
1.472(1.272~1.694)
0.841(0.688~0.990)
0.375(0.269~0.480)
The toxicity and field control efficacy of SYP-9625 to T. urticae has been tested by Gong et al [37]. Based on that study, an application concentration of 100μg/mL SYP-9625 was used in our experiment. After 24, 48 and 72 h per treatment, N. californicus females and eggs were both insensitive to the application concentration of SYP-9625. Even at ten times the application concentration, the hatching rate was 99.33±0.67. As a consequence, 100μg/mL of SYP-9625 was used as the application concentration on N. californicus in this study (Table 2).
Table 2
Effect of SYP-9625 on the survival rate of eggs and adult females of N. californicus.
Acaricide
Dose μg/mL
Hatching rate (%)
Survival rate (%)
24 h
48 h
72 h
(SYP-9625)
100
100.00±0.00a
100.00±0.00a
100.00±0.00a
99.67±0.33a
1000
99.33±0.67a
100.00±0.00a
100.00±0.00a
99.00±0.58a
Control
/
99.67±0.33a
100.00±0.00a
100.00±0.00a
100.00±0.00a
Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.
Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.
Effects of sublethal concentrations of SYP-9625 on T. cinnabarinus females and their offspring
The Survival rate after 24 h treated by LC30 was 68%, which was significantly lower than the control (100%). The total spawning rate, female longevity and the fecundity of T. cinnabarinus females treated with sublethal concentrations (LC10, LC30) were significantly reduced, and the pre-oviposition periods were significantly extended compared with the controls (Table 3). The oviposition period of females in the LC30 treatment was significantly shorter than oviposition period of females in the control treatment. The total spawning rate, female longevity and fecundity of females in the LC30 treatment were lower than females exposed to the LC10 treatment. Moreover, the pre-oviposition periods in the LC30 treatment were longer than in the LC10 treatment.
Table 3
Effects of sublethal exposure to SYP-9625 on the fecundity and longevity of treated females of Tetranychus cinnabarinus.
Parameter
Control
SYP-9625
LC10
LC30
Survival rate after 24h (%)
100
92
68
Total spawning rate (%)
100.00±0.00a
72.13±7.48b
40.48±7.19cd
Preoviposition period (days±SE)
1.71±0.07d
2.75±0.07c
3.42±0.11a
Oviposition period (days±SE)
6.00±0.52a
4.85±0.61ab
4.10±0.65b
Fecundity per female (eggs±SE)
26.06±2.75a
12.53±2.29b
5.40±1.43cd
Female longevity (days±SE)
9.14±0.86a
6.89±0.70b
4.44±0.56cd
Note: The total spawning rate is the number of spawning individuals/ the total number of individuals that are effectively processed.
Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.
Note: The total spawning rate is the number of spawning individuals/ the total number of individuals that are effectively processed.Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.Fig 1 shows that the age-specific fecundity curves and the peak values of adult females T. cinnabarinus treated with sublethal concentrations (LC10, LC30) of SYP-9625 shifted. Moreover, a significant reduction in the age-specific survival rate was observed at both concentrations.
Fig 1
Female age-specific fecundity (fx5) and the age-specific survival rate (lx) of female adults T. cinnabarinus treated with sublethal concentrations of SYP-9625.
Moreover, the total survival rate was lowerin the LC30 treatment than in the LC10 treatment and the control. In Fig 2, the slope of l increased after 5 to 16 days as the sublethal concentration increased from LC10 to LC30, but they converged on the same value. The peak values of f and lm in individuals that survived the LC10 and LC30 treatments were distinctly lower than in the control, but less difference was observed between the LC10 and LC30 treatments. Consequently, sublethal concentrations of SYP-9625 weakened reproduction in the population, particularly the fecundity of female mites.
Fig 2
Age-specific survival rate (l), female age-specific fecundity (f), age-specific fecundity of the total population (m), and age-specific maternity (lm) of T. cinnabarinus eggs treated with sublethal concentrations of SYP-9625.
(A) Control, (B) LC10, (C) LC30.
Age-specific survival rate (l), female age-specific fecundity (f), age-specific fecundity of the total population (m), and age-specific maternity (lm) of T. cinnabarinus eggs treated with sublethal concentrations of SYP-9625.
(A) Control, (B) LC10, (C) LC30.As shown in Table 4, the r, λ and R of offspring from treated T. cinnabarinus females were significantly lower than the control. The increasing concentration produced a dramatic change. Additionally, the T in the LC30 treatment was significantly shorter than in the control.
Table 4
Population life table parameters for offspring from females of Tetranychus cinnabarinus treated with sublethal concentrations of SYP-9625.
Parameter
Control
SYP-9625
LC10
LC30
Intrinsic rate of increase rate, rm(d-1)
0.209±0.003a
0.166±0.005b
0.147±0.006c
Finite rate of increase, λ (d-1)
1.232±0.004a
1.180±0.006b
1.158±0.007c
Net reproductive rate, R0(offspring/individual)
32.74±2.03a
14.96±1.23b
11.02±1.17c
Mean generation time, T (d)
16.72±0.09a
16.33±0.11a
16.33±0.13a
Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.
Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.
Effects of the application concentration of SYP-9625 on N. californicus eggs
After a 5 s exposure to the application concentration (100μg/mL), preadult duration, longevity and the total life span of adults from the treated eggs of N. californicus were not significantly influenced, as shown in Table 5. Larval and protonymph durations in treatment groups were longer than the control. Beyond that, other indices including female proportion and the adult emergence rate showed less difference with the control. Table 6 presents the spawning rate, pre-oviposition and fecundity per female among the females grown from treated eggs. The total duration of pre-oviposition for females from eggs treated with SYP-962 was significantly longer than the control; in contrast, the duration of oviposition was shorter.
Table 5
Development time, longevity, and total life span of Neoseiulus californicus eggs treated with the application concentration of SYP-9625.
Parameter
Control
SYP-9625(100μg/mL)
Female proportion (%)
62.88±4.91a
60.99±4.87a
Adult emergence rate (%)
97.00±1.70ab
100.00±0.00a
Female
Egg duration (d)
1.83±0.07a
1.84±0.03a
Larva duration (d)
0.58±0.03b
0.73 ± 0.03a
Protonymph duration (d)
0.98± 0.01b
1.05 ±0.02a
Deutonymph duration (d)
1.22±0.06a
1.27±0.25a
Preadult duration (d)
4.61±0.04b
4.89± 0.04a
Longevity (d)
30.95±1.19a
26.30±1.37b
Total life span (d)
35.56±1.21a
31.18±1.38b
Male
Egg duration (d)
1.86± 0.04a
1.91± 0.03a
Larva duration (d)
0.58± 0.03a
0.59± 0.03a
Protonymph duration (d)
0.88±0.04b
0.91±0.03b
Deutonymph duration (d)
1.01±0.03a
1.08±0.03a
Preadult duration (d)
4.33±0.07b
4.49±0.07ab
Longevity (d)
33.04±2.22a
29.58±2.06a
Total life span (d)
37.38±2.25a
34.06±2.05a
Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.
Table 6
The reproduction and fecundity of Neoseiulus californicus eggs treated with the application concentration of SYP-9625.
Parameter
Control
SYP-9625(100μg/mL)
Spawning rate (%)
100.00±0.00a
100.00±0.00a
Pre-oviposition (d)
1.68±0.04a
1.72±0.05a
Total pre-oviposition (d)
6.29±0.07b
6.61±0.08a
Oviposition (d)
15.77±0.44a
13.30±0.45b
Fecundity per female (eggs)
46.72±1.35a
40.26±1.42ab
Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.
Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.The difference in l, f and m in the total population between treatments and control could barely been distinguish. The peak value of f for the control (2) occurred at 11 days, and the peak value of f 1.8 for the application concentration occurred at 10 days in Fig 3. The r, λ, GRR and T of treated N. californicus eggs were not significantly different from the control (Table 7). Hence, there was little effect on the population growth of N. californicus eggs exposed to the application concentration of SYP-9625.
Fig 3
Age-specific survival rate (l), female age-specific fecundity (f), age-specific fecundity of the total population (m), and age-specific maternity (lm) of N. californicus (McGregor) eggs treated with sublethal concentrations of SYP-9625.
(A) Control, (B) SYP-9625.
Table 7
Population life table parameters of Neoseiulus californicus eggs treated with the application concentration of SYP-9625.
Parameter
Control
SYP-9625(100μg/mL)
Intrinsic rate of increase rate, rm(d-1)
0.292±0.009a
0.277±0.009a
Finite rate of increase, λ (d-1)
1.338±0.012a
1.319±0.012a
Net reproductive rate, R0(offspring/individual)
28.50±2.41a
24.56±2.15ab
Mean generation time, T (d)
11.49±0.14a
11.55±0.16a
Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.
Age-specific survival rate (l), female age-specific fecundity (f), age-specific fecundity of the total population (m), and age-specific maternity (lm) of N. californicus (McGregor) eggs treated with sublethal concentrations of SYP-9625.
(A) Control, (B) SYP-9625.Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.
Effects of the application concentration of SYP-9625 on N. californicus females and their offspring
The application concentration reduced the survival rate of treated females (Fig 4). The peak value of female age-specific fecundity occurred earlier in the control than in the treatment. Additionally, the fluctuation in female age-specific fecundity was greater than in the control.
Fig 4
Age-specific survival rate (l) and female age-specific fecundity (f) of N. californicus (McGregor) adult females treated with sublethal concentrations of SYP-9625.
Initially, the age-specific survival rate at the application concentration declined slowly from 0 d to 30 d. Age-specific survival rate then decreased more rapidly from 30 d to 60 d. The acaricide treatment barely affected the age-specific survival rate of offspring from treated females of N. californicus, and the declining gradient of the earlier stage was higher than the control in Fig 5.
Fig 5
Age-specific survival rate (l), female age-specific fecundity (f), age-specific fecundity of the total population (m), and age-specific maternity (lm) of offspring from adult female N.californicus (McGregor) treated with sublethal concentrations of SYP-9625.
(A) Control, (B) SYP-9625.
Age-specific survival rate (l), female age-specific fecundity (f), age-specific fecundity of the total population (m), and age-specific maternity (lm) of offspring from adult female N.californicus (McGregor) treated with sublethal concentrations of SYP-9625.
(A) Control, (B) SYP-9625.Compared with the control, the R, rm and λ of offspring from individual N. californicus females treated with SYP-9625 were significantly lower (Table 8). However, there was no significant difference in the T between the treatment and control.
Table 8
Population life table parameters of offspring from Neoseiulus californicus females treated with the application concentration of SYP-9625.
Parameter
Control
SYP-9625(100μg/mL)
Intrinsic rate of increase rate, rm(d-1)
0.290±0.009a
0.233±0.012b
Finite rate of increase, λ (d-1)
1.336±0.012a
1.263±0.155b
Net reproductive rate, R0(offspring/individual)
27.37±2.43a
15.91±2.08b
Mean generation time, T (d)
11.42±0.14a
11.87±0.19a
Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.
Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.
Effects on N. californicus fed on T. cinnabarinus treated with sublethal levels of SYP-9625
As shown in Fig 6, l rapidly declined between 0 to 30 d with increased concentrations of SYP-9625; l declined more slowly from 30 to 48 d. After 48 d, all l values gradually decreased to 0% between 64.5 to 72.5 d. The fx5, mx and lxmx for the LC10 treatment were not significantly different from the control, but the fx5,
mx and lxmx for the LC30 treatment were all lower than the control. All of the population parameters for the LC30 treatment were lower than the control, with the exception of T (Table 9). After N. californicus were fed on treated T. cinnabarinus, the r of the subsequent generation was significantly reduced from 0.289 to 0.243. The intrinsic rate of increase rate (r) is an important parameter affecting variation in the population trend under specific environmental conditions and reflects the reproductive capacity of N. californicus. Additionally, λ was significantly reduced from 1.335 to 1.275, and R was significantly reduced from 28.71 to 18.13. However, the population parameters of the LC10 treatment were similar to those of the control.
Fig 6
Age-stage specific survival rate (s) of offspring from adult female N. californicus (McGregor) fed on T. cinnabarinus treated with sublethal concentrations of SYP-9625.
(A) Control, (B) LC10, (C) LC30.
Table 9
Population life table parameters of offspring from Neoseiulus californicus fed on Tetranychus cinnabarinus treated with sublethal levels of SYP-9625.
Parameter
Control
SYP-9625
LC10
LC30
Intrinsic rate of increase rate, rm(d-1)
0.289±0.009a
0.278±0.008a
0.243±0.009b
Finite rate of increase, λ (d-1)
1.335±0.012a
1.319±0.010a
1.275±0.012b
Net reproductive rate, R0(offspring/individual)
28.71±2.51a
28.02±2.37a
18.13±1.85b
Mean generation time, T (d)
11.61±0.15a
12.01±0.15a
11.91±0.16a
Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.
Age-stage specific survival rate (s) of offspring from adult female N. californicus (McGregor) fed on T. cinnabarinus treated with sublethal concentrations of SYP-9625.
(A) Control, (B) LC10, (C) LC30.Note: Data in the table are mean ± SE. Data in the same group followed by different letters indicate significant difference at the P<0.05 level using Duncan’s new multiple range test.
Effects of the application concentration on control efficiency of N. californicus
The control efficiency of N. californicus had an intrinsic acceleration owing to inverse density-dependent effects after adult female N. californicus were treated with 100 μg/mL of SYP-9625. There was no significant effect on the daily consumption of N. californicus against eggs and densities of 5, 10, or 15 adults of T. cinnabarinus per leaf. The daily consumption of nymphs significantly differed at densities of 10, 15, 20 and 30 nymphs per leaf. The daily consumption of larvae and adults declined significantly at densities of 30 and 50 per leaf and 20 and 25 per leaf, respectively (Table 10).
Table 10
Daily consumption by Neoseiulus californicus exposed to the application concentration of SYP-9625.
Stages of preys
Treatments
Density of Tetranychus cinnabarinus (number per leaf)
5
10
15
20
25
30
40
50
Egg
CK
—
7.60±0.68a
10.27±0.66b
12.00±0.63ab
15.00±0.63a
15.27±0.49a
—
—
SYP-9625
—
8.00±0.63a
13.50±0.22a
14.50±0.22a
14.50±0.50a
14.50±0.22ab
—
—
Larva
CK
—
10.00±0.00a
—
19.00±0.55a
—
28.60±0.75a
30.60±0.81ab
31.00±0.63b
SYP-9625
—
10.00±0.00a
—
19.00±0.32a
—
26.10±0.56b
29.00±0.32b
28.50±0.81c
Nymph
CK
—
10.00±0.00a
12.60±0.81b
19.20±0.20b
19.60±1.33a
20.00±0.32b
—
—
SYP-9625
—
9.50±0.22b
14.50±0.22a
20.00±0.00a
18.00±0.32a
24.50±1.75a
—
—
Adult
CK
3.40±0.24b
4.00±0.32b
5.20±0.37b
6.60±0.40a
8.40±0.24a
—
—
—
SYP-9625
3.50±0.22b
4.00±0.00b
4.00±0.32b
5.50±0.22b
7.50±0.22b
—
—
—
Note: Data in the table are means ± SE. Data in the same group (column and life stage) followed by different letters indicate a difference at the P < 0.05 level using by Duncan’s new multiple range test. “-” indicates that the treatments of corresponding densities were not processed.
Note: Data in the table are means ± SE. Data in the same group (column and life stage) followed by different letters indicate a difference at the P < 0.05 level using by Duncan’s new multiple range test. “-” indicates that the treatments of corresponding densities were not processed.The functional response of N. californicusfits reasonably well to a type II functional response of the Holling model (Table 11). The application concentration led to a reduction in handling time and attack rate against the different life stages, with the exception of nymphs. Compared with the control, the maximum attack rates (T/T) of N. californicus against nymphs was 128.2051, which was the highest value among the different stages. The control efficiency (a/T) of eggs and nymphs increased by 27.39% and 74.54%, respectively. a/T of larvae and adults decreased by 19.71% and 18.98%, respectively.
Table 11
Functional response models and parameters of Neoseiulus californicus exposed to the application concentration of SYP-9625.
Stage of prey
Treatment
Functional response equation
Correlation coefficient
Attack rate (a)
Handling time (Th)
T/Th
a/Th
Egg
CK
Na = 0.9746N/(1+0.0283N)
0.9801
0.9746
0.0290
34.4828
33.6069
SYP-9625
Na = 1.3959N/(1+0.0505N)
0.9207
1.3959
0.0326
30.6748
42.8190
Larva
CK
Na = 1.1614N/(1+0.0127N)
0.9257
1.1614
0.0109
91.7431
106.5505
SYP-9625
Na = 1.2190N/(1+0.0174N)
0.9170
1.2190
0.0143
69.9301
85.2448
Nymph
CK
Na = 1.1272N/(1+0.0168N)
0.9148
1.1272
0.0149
67.1141
75.6510
SYP-9625
Na = 1.0299N/(1+0.0081N)
0.9353
1.0299
0.0078
128.2051
132.0385
Adult
CK
Na = 0.7020N/(1+0.0514N)
0.9904
0.7020
0.0732
13.6612
9.5902
SYP-9625
Na = 0.6791N/(1+0.0594N)
0.9184
0.6791
0.0874
11.4416
7.7700
Control efficiency of N. californicus fed on T. cinnabarinus treated with sublethal acaricide
The functional response model parameters for N. californicus fed on T. cinnabarinus treated with sublethal acaricide were altered for various life stages (Table 12). There was a significant increase in the daily consumption of N. californicus against eggs at densities of 10, 15 and 20 T. cinnabarinus eggs per leaf with an increased concentration of SYP-9625. There was no significant difference in the control efficiency against nymphs among all treatments and the control at densities of 10, 15, or 20 nymphs per leaf. When the nymphal density increased to 25 and 30 per leaf, the daily consumption was higher in the treatments than in the control. There was little difference in control efficiency among all treatments and the control at densities of 5, 10 and 15 adults per leaf. When the adult density increased to 20 and 25 per leaf, the daily consumptions were significantly lower than the control.
Table 12
Daily consumption of Neoseiulus californicus fed on Tetranychus cinnabarinus treated with sublethal acaricide.
Stage of prey
Treatment
Density of Tetranychus cinnabarinus (number per leaf)
5
10
15
20
25
30
40
50
Egg
CK
—
7.60±0.68b
10.27±0.66b
12.00±0.63b
15.00±0.63a
15.27±0.48a
—
—
LC10
—
9.40±0.24a
12.40±0.24a
14.20±0.20a
14.50±0.22a
15.00±0.00a
—
—
LC30
—
8.00±0.63ab
12.00±0.32a
15.50±0.50a
15.50±0.22a
15.60±0.24a
—
—
Larva
CK
—
10.00±0.00a
—
19.00±0.55a
—
28.60±0.75a
30.60±0.81a
31.00±0.63a
LC10
—
10.00±0.00a
—
20.00±0.00a
—
29.33±0.18a
28.33±0.66b
32.67±0.80a
LC30
—
10.00±0.00a
—
19.33±0.37a
—
29.33±0.18a
29.67±0.48ab
31.00±0.84a
Nymph
CK
—
10.00±0.00a
12.60±0.81a
19.20±0.20a
19.60±1.33b
20.00±0.32b
—
—
LC10
—
10.00±0.00a
13.60±0.40a
18.40±0.40a
21.60±0.24ab
22.00±0.55a
—
—
LC30
—
10.00±0.00a
12.67±0.18a
18.33±0.18a
22.27±0.19a
22.67±0.18a
—
—
Adult
CK
3.40±0.24a
4.00±0.32a
5.20±0.37a
6.60±0.40a
8.40±0.24a
—
—
—
LC10
4.00±0.32a
4.400±0.24a
4.60±0.24a
5.00±0.32b
5.00±0.32b
—
—
—
LC30
4.00±0.00a
4.33±0.18a
4.33±0.37a
5.00±0.55b
5.33±0.18b
—
—
—
Note: Data in the table are means ± SE. Data in the same group (column and life stage) followed by different letters indicate a difference at the P < 0.05 level using by Duncan’s new multiple range test. “-” indicates that the treatments of corresponding densities were not processed.
Note: Data in the table are means ± SE. Data in the same group (column and life stage) followed by different letters indicate a difference at the P < 0.05 level using by Duncan’s new multiple range test. “-” indicates that the treatments of corresponding densities were not processed.The functional response model fits reasonably well to a type II functional response of the Holling model based on the parameters in Table 13. The sublethal concentrations led to an increase in the attack rate against all life stages compared with the control. The attack rates against adults in the LC10 and LC30 treatments increased by 344.64% and 176.71%, respectively. The handling time of the different life stages did not differ at any concentration, except that the handling time of adults was longer than the control. The highest value of T/T was 107.5269 against nymphs in the LC30 treatment, which was the maximum attack rate documented in this experiment. The maximum a/T (112.9677) was also observed for nymphs in the LC30 treatment. However, the a/T against adults had a maximum value at LC10. When the concentration of SYP-9625 reached the LC30, the value of a/T was still higher than the control, but a decrease was observed.
Table 13
Functional response model and parameters of Neoseiulus californicus fed on Tetranychus cinnabarinus treated with sublethal acaricide.
Stage of prey
Treatment
Functional response equation
Correlation coefficient
Attack rate (a)
Handling time (Th)
T/Th
a/Th
Egg
CK
Na = 0.9746N/(1+0.0283N)
0.9801
0.9746
0.0290
34.4828
33.6069
LC10
Na = 1.7287N/(1+0.0776N)
0.9262
1.7287
0.0449
22.2717
38.5011
LC30
Na = 1.0281N/(1+0.0241N)
0.9024
1.0281
0.0234
42.7350
43.9359
Larva
CK
Na = 1.1614N/(1+0.0127N)
0.9257
1.1614
0.0109
91.7431
106.5505
LC10
Na = 1.1805N/(1+0.0130N)
0.9282
1.1805
0.0110
90.9091
107.3182
LC30
Na = 1.1660N/(1+0.0128N)
0.9148
1.1660
0.0110
90.9091
106.0000
Nymph
CK
Na = 1.1272N/(1+0.0168N)
0.9148
1.1272
0.0149
67.1141
75.6510
LC10
Na = 1.1529N/(1+0.0156N)
0.9711
1.1529
0.0135
74.0741
85.4000
LC30
Na = 1.0506N/(1+0.0098N)
0.9711
1.0506
0.0093
107.5269
112.9677
Adult
CK
Na = 0.7020N/(1+0.05136N)
0.9904
0.7020
0.0732
13.6612
9.5902
LC10
Na = 3.1214N/(1+0.1926N)
0.9707
3.1214
0.1926
5.1921
16.2066
LC30
Na = 1.9923N/(1+0.3468N)
0.9623
1.9923
0.1741
5.7438
11.4434
Discussion
In previous studies, many species of natural enemies and pesticides have been tested so far to corroborate the combination of chemical and biological control agents under laboratory conditions [38-42]. Moreover, numerous studies have focused on the importance of sublethal effects of pesticides on predatory mites [3, 9, 33]. On one hand, this is the first report on both pest mites and the predatory mites of the new pesticide SYP-9625. On the other hand, N. californicus provides good efficacy against pest mites as showed by most studies [15, 43]. Therefore, this study was designed to examine the appropriate concentration of SYP-9625 that can be used to control the increasing population of T. cinnabarinus effectively and simultaneously protect N. californicus.
Sublethal effects of SYP-9625 on T. cinnabarinus
Our results showed that the sublethal concentration of SYP-9625 can effectively inhibit the increasing population of The overall impact on T. cinnabarinus offspring is greater for females than for males, which was approximately similar to the results obtained by Asma et al. for T. urticae treated with a series of biopesticide concentrations (0.31-10ml/l) [20]. The population parameters (r, λ and R) of offspring treated with sublethal concentrations decreased significantly as the concentration increased, which is consistent with the findings of Asma et al. and Dejan [20, 44].
Effects of SYP-9625 on N. californicus
Our results revealed that the application concentration negatively affected the survivorship of N. californicus adulthood and its subsequent generation, which is consistent with the findings of Maryam et al for N. californicus treated with LC15 sublethal concentration of spiromesifen [45]. In addition, the r, λ and R of offspring from N. californicus females fed on T. cinnabarinus treated with an LC30 of SYP-9625 were significantly reduced, which is partly consistent with the previous findings [4]. Many indices of N. californicus eggs exposed to the application concentration (100μg/mL) preadult duration, longevity, total life span, female proportion and adult emergence rate showed less difference when compared with the control. All the results showed that the application concentration of SYP-9625 had little influence on the development and fecundity of N. californicus eggs. This demonstrates that N. californicus eggs were able to tolerate the application concentration of SYP-9625 (100 mg/L).
Effects of SYP-9625 on the functional response of N. californicus
N. californicus exhibited a Holling type-II type functional response when fed on T. cinnabarinus exposed to sublethal concentrations of SYP-9625, and no changes in the functional response model were observed. Similarly, Li et al. showed that a Holling type—II functional response was exhibited by predatory thrips Scolothrips. takahashii fed on Tetranychus viennensis except for female [46]. The attack rate of N. californicus expoed to the application concentration of SYP-9625 increased compared with the control, except for the attack rate on nymphs treatment. The attack rate against treated T. cinnabarinus increased as well, particularly for adults. In contrast, Angeliki et al. reported that sublethal concentrations of thiacloprid led to a significant reduction of the attack rate of Macrolophus pygmaeus [28]. In general, most of the handling time (T) of N. californicus against treated T. cinnabarinus and the handling time of N. californicus exposed to the application concentration was longer than the control, which is consistent with the study on M. pygmaeus exposed to thiacloprid and chlorantraniliprole [28]. The control efficiency a/T against treated adult T. cinnabarinus reached a maximum value in the LC10 treatment. Furthermore, the a/Th against the larval and nymphal stages were significantly higher than other stages. Consequently, the predation ability of N. californicus against sublethal treated T. cinnabarinus and the predation ability of N. californicus exposed to the application concentration were both significantly positively affected, particularly at the lower sublethal concentration of SYP-9625 (LC10). This result differed from other studies such as Rashidi et al. which found that sublethal doses of four pesticides negatively affected the control efficiency of Habrobracon. Hebetor [47]. It might due to the weak toxicity of SYP-9625 against N. californicus, and a hormesis effect at lower concentrations (LC10) stimulates the trophic behavior of N. californicus. It is reported that the hormesis effect occurs at a low doses in a number of ecological populations such as the control efficiency of Pardosa agrestis treated with eight herbicides and Supputius cincticeps treated with sublethal concentrations of permethrin [48, 49].We maintain that a lower concentration (LC10 = 0.375 μg/mL) of SYP-9625 is beneficial for N. californicus. SYP-9625 at the LC10 can stimulate the predation capability against T. cinnabarinus and is also safe for N. californicus eggs.
Conclusions
The sublethal effects of SYP-9625 on T. cinnabarinus, the effects of application concentration of SYP-9625 on the predatory mite N. californicus and the functional response of N. californicus were successfully assessed. This study concludes that SYP-9625, particularly at a lower concentration (LC10 = 0.375 μg/mL) can effectively control the increasing population of T. cinnabarinus and stimulate the predation capability of N. californicus. We confirmed that the new acaricide SYP-9625 can be used in concert with the release of the predator N. californicus in IPM.
Fig 1
Fig 2
Fig 3
Fig 4
Fig 5
Fig 6