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Article

Research on the Reproduction of Trichogramma chilonis Based on Samia cynthia ricini Eggs: Temperature, Functional Response and Proportional Effect

by
Xi Yuan
,
Dunsong Li
* and
Weili Deng
Institute of Plant Protection, Guangdong Academy of Agricultural Sciences, Key Laboratory of Green Prevention and Control on Fruits and Vegetables in South China Ministry of Agriculture and Rural Affairs, Guangdong Provincial Key Laboratory of High Technology for Plant Protection, Guangzhou 510640, China
*
Author to whom correspondence should be addressed.
Insects 2024, 15(12), 963; https://doi.org/10.3390/insects15120963
Submission received: 3 November 2024 / Revised: 27 November 2024 / Accepted: 29 November 2024 / Published: 3 December 2024
(This article belongs to the Section Insect Physiology, Reproduction and Development)
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Simple Summary

Trichogramma chilonis is widely used for biological control, but there is a lack of efficient and available host eggs for the production of this parasitoid. Samia cynthia ricini, an economically valuable, non-mulberry silkworm, was previously reported to be used for the reproduction of Trichogramma spp. but subsequently received less attention, and more details about its use are unknown. Through laboratory experiments, we found that the suitable developmental temperature for adult S. c. ricini is 25–28 °C, and the adults must undergo at least 24 h of development time after emergence to lay more qualified eggs. T. chilonis has a type II functional response to S. c. ricini eggs. In brief, this means that as S. c. ricini egg density increases, the number of eggs parasitized by T. chilonis will gradually increase, but the growth rate will slow down and eventually reach a saturation state. Accordingly, by coordinating the ratio of parasitoid wasps to host eggs, we found that S. c. ricini eggs demonstrated excellent reproductive efficiency in terms of the reproduction of T. chilonis when the ratios were 1:2 and 1:3. We concluded that S. c. ricini eggs are potentially an excellent host egg for breeding T. chilonis and should be given more attention.

Abstract

T. chilonis is a commonly used biological agent, but its existing host eggs have shown some problems in the breeding of T. chilonis, and the search for more suitable host eggs is imminent. Here, we focused on S. c. ricini, an intermediate host that was used in the past for Trichogramma spp. but has since received less attention. We attempted to understand the effects of developmental temperature and duration on its longevity and egg production, evaluated the functional response of T. chilonis to S. c. ricini egg, and screened for a suitable wasp-to-egg ratio for the production of T. chilonis. Our results showed that the developmental temperature and duration after the emergence of T. chilonis significantly affected adult longevity and oviposition, that 25–28 °C is a suitable temperature range for the survival and e-g laying of S. c. ricini, and that a developmental duration of at least 24 h was required to obtain more qualified S. c. ricini eggs. T. chilonis demonstrated a type II functional response to S. c. ricini eggs; different wasp-to-egg ratios significantly affected the propagation efficiency of T. chilonis reproduction from S. c. ricini eggs, and the best reproduction efficiency was achieved with wasp-to-egg ratios of 1:2 and 1:3, Considering that there were no significant differences in most parameters between the two treatments, as well as cost concerns, we concluded that wasp-to-egg ratios of 1:2 are an important parameter that could be applied. Our results may provide some valuable insights into the mass rearing of T. chilonis.

1. Introduction

Biological control through the release of egg parasitoids is considered to be a safe and sustainable approach to achieve the effective management of agricultural pests [1]. Trichogramma species are the most widely exploited and used for pest management worldwide [2], and large-scale field releases for maize pest control have been carried out in China, with significant ecological and economic benefits [3]. Trichogramma chilonis (Ishii) is a Trichogramma spp. with high reproductive capacity [4], and has gained attention in recent years as a potential biological agent in the management of many important agricultural pests [5,6,7]. However, the achievement of the large-scale release of egg parasitoids is closely related to the cost of rearing [8], and exploring techniques and methods that can enable the mass rearing of T. chilonis is a critical step towards the use of them as a biological agent for successful biocontrol practices.
Trichogramma spp. spend all periods of their lives in host eggs except for their adult lives, so obtaining suitable intermediate host eggs is crucial for the mass production of T. chilonis [9]. Currently, the intermediate hosts used for the mass reproduction of Trichogramma spp. in China are the eggs of Corcyra cephalonica (Stainton) [10,11], Sitotroga cerealella (Olivier) [12,13], Samia cynthia ricini Boisduval [14] and Antheraea pernyi silk [11,15]. Among them, C. cephalonica and S. cerealella are widely used as intermediate hosts due to their ease of feeding, wide range of possible forage sources, and ability to reproduce indoors throughout the year and facilitate mass production [9,16,17]. However, the small egg sizes of C. cephalonica (0.5–0.9 mm) [18] and S. cerealella (0.5–0.6 mm) [17] resulted in inefficient wasp reproduction because only one Trichogramma individual can complete its development per insect egg. Moreover, the viability of Trichogramma spp. decreased after reproduction with S. cerealella eggs and parasitized eggs do not tolerate cold storage [19,20]; therefore, the use of small host eggs for the mass production of Trichogramma spp. is uneconomical [21]. In contrast, A. pernyi eggs are the most successful host eggs in the mass rearing of Trichogramma spp., with the advantages of a high reproduction rate, convenient transport and low cost [22]. Moreover, compared with the traditional reproduction using C. cephalonica eggs, the body size, longevity and lifetime fecundity of Trichogramma ostriniae Pang et Chen are superior when using A. pernyi eggs as a host, which make them a more effective natural enemy for biocontrol [23]. As early as 1962, Lin et al. [24] found that T. chilonis could be reproduced using A. pernyi eggs, carried out biological observations of T. chilonis parasitized in A. pernyi eggs and found that A. pernyi eggs had high efficiency in terms of T. chilonis reproduction. However, the production of A. pernyi is dependent on the use of Quercus palustris Münchh. in north-eastern China, and climatic and geographic differences have resulted in there being no cost advantage for the use of A. pernyi for the development of T. chilonis in southern China [22]. In addition, a recent study found that the parasitism and emergence rates of T. chilonis were significantly reduced when the eggs of A. pernyi were used as an alternative host, seriously affecting the propagation quality of T. chilonis and the field control effects [14]. Therefore, there is an urgent need to find a more cost-effective and high-efficiency intermediate host for the better reproduction of T. chilonis.
S. c. ricini (Lepidoptera: Saturniidae), is one of the most highly developed, domesticated and commercially available non-mulberry silkworms of economic importance [25]. This silkworm feeds on several host plants but mainly on Ricinus communis L. leaves [26,27] and can be raised indoors and reproduced for several generations per year [25]. In 1956, Pu et al. [19] used S. c. ricini eggs to breed T. chilonis, and found that each egg of S. c. ricini could breed about 28 T. chilonis offspring, the female ratio of the offspring was more than 80% and the propagation coefficient was 13.0 to 22.6 fold, which proved that the S. c. ricini eggs were an excellent host for T. chilonis. Since then, Liu et al. [28,29] have overcome the problem of raising S. c. ricini on artificial feed, and successfully achieved the annual breeding of S. c. ricini. T. chilonis reared from the eggs of S. c. ricini were then successfully released into the field [30,31]. However, in the early 1980s, due to the reform of China’s rural economic system and for other reasons, S. c. ricini was no longer reared at a large scale, and it ceased to be used in China as a host for the mass rearing of Trichogramma spp. [3]. In recent years, S. c. ricini has received renewed attention due to the continued high price of A. pernyi eggs [32] and the limited number of species of Trichogramma parasitoids that can be reproduced by A. pernyi eggs [33], making it necessary to improve our understanding of the usage of S. c. ricini eggs for the reproduction of T. chilonis. However, before we carry out the above-mentioned studies, we should focus on several key parameters of S. c. ricini rearing, such as temperature, light and the use of artificial feeds. Although previous studies have obtained important results regarding the effects of temperature on the development and reproduction of S. c. ricini [34] and the exploitation of artificial feeds [29], most of these studies concentrated on the pre-adult stage. In contrast, little research has dealt with the impact factors after the eclosion of insects, such as developmental temperature and duration, which significantly affect the quality of subsequent egg-laying [35]. Therefore, to better understand the factors affecting the reproduction of S. c. ricini, it is essential to expand our knowledge of the factors affecting the stage after eclosion, which will help to improve the efficiency of rearing and the quality of egg production for S. c. ricini.
The functional response refers to the correlation between the predation rate of a single predator and the different densities of its prey within a specific period [36,37], and is an important indicator when describing the dynamic relationship between the natural enemies of pests and the population quantity of pests and evaluating the parasitism or predation efficiency of natural enemies on pests [38,39]. Functional responses are typically distinguished into three response types, which are characterized by the number of prey consumed, which increases linearly (type I), hyperbolically (type II) or sigmoidally (type III) [36]. Understanding the functional responses of Trichogramma spp. can help to predict the pest control potential of Trichogramma spp. at different pest densities, which helps to formulate a more scientific and rational biological control strategy to determine the appropriate release number of Trichogramma spp. for optimal pest control and to improve the success and efficiency of biological control. For example, the handling time and attack rate of Trichogramma euproctidis (Girault) on Helicoverpa armigera (Hübner) eggs were 0.6898 h and 0.00823 h, respectively, and the maximum daily parasitism was 34.79 eggs per wasp [40], whereas the maximum number of parasitized eggs by each female of Trichogramma achaeae Nagaraja and Nagarkatti and T. chilonis on Tuta absoluta (Meyrick) was 16.23 and 11.05 eggs in 24 h, respectively [41]. Therefore, knowledge of the functional responses of Trichogramma spp. to different pests is of great practical importance for the development of control strategies and breeding strategies. However, to our knowledge, little of the literature has reported the functional responses of T. chilonis to the eggs of Spodoptera exigua Hübner and Plutella xylostella Linnaeus [41], C. cephalonica [7], T. absoluta [42], Galleria mellonella Linnaeus and Chilo sacchariphagus Bojer [43]. The potential of S. c. ricini as intermediate hosts for the mass production of T. chilonis and the functional response of T. chilonis to castor S. c. ricini eggs remains unclear. Based on this, this study intends to (1) explore the impacts of developmental temperature and duration on the oviposition of S. c. ricini; (2) reveal the functional response of T. chilonis to the eggs of S. c. ricini; (3) elucidate the effects of different ratios of T. chilonis to S. c. ricini eggs (wasp-to-egg ratios) on the reproduction of T. chilonis. This study conducts a preliminary exploration on the methods of reproduction of T. chilonis with S. c. ricini eggs, which may provide a reference for the industrialized production of T. chilonis in the future.

2. Materials and Methods

2.1. Insect Sources and Feeding

S. c. ricini eggs were provided by the Institute of Plant Protection, Guangxi Academy of Agricultural Sciences, and S. c. ricini were reared in an artificial climate chamber (RDZ-300D-4W, Ningbo Jiangnan Instrument Factory, Ningbo, China) with castor leaves for experimental use. The culture temperature was 25 ± 1 °C, relative humidity (RH) was 75 ± 10%, L:D = 14:10 (the following culture conditions are the same as this, unless otherwise stated), fresh castor leaves were added and food scraps were cleaned up daily.
Pupae of T. chilonis were collected from the natural egg masses of C. sacchariphagus and Chilo infuscatellus (Snellen) in the sugarcane field at Nanning City, Guangxi Zhuang, Autonomous Region. After identification and purification indoors, T. chilonis were bred in an artificial climate chamber. T. chilonis was used in the experiment after breeding for several generations with eggs of C. cephalonica and sufficient eggs were given at once to T. chilonis for parasitism during propagation.

2.2. Experimental Design

S. c. ricini that cocooned on the same day were selected and after 10 days of normal development at room temperature, the cocoon shells were carefully cut open with scissors and the pupae of S. c. ricini were cautiously taken out. After the sex identification of pupae under a dissecting microscope, female and male pupae were placed in separate containers to develop individually, to ensure that female moths that fledged were unmated prior to the experiment and that there was no food supplementation during the culture period.

2.2.1. Developmental Temperature

Female pupae of S. c. ricini with a similar size and weight were selected and each pupa was individually packed in a cup and sealed with gauze mesh. After the pupae emerged, the unmated female moths that emerged on the same day were selected and packed into separate cups that were sealed with gauze mesh. Four treatments at different temperatures were set at 22, 25, 28 and 31 °C. The relative humidity was 75 ± 10% and the photoperiod was 14L:10D. Each treatment contained 30 female moths and was repeated three times.
During the adult stage, the number of eggs laid and the survival of each adult moth were observed daily. After the female moth died, the number of qualified eggs remaining in each moth was investigated via dissection, and the day-by-day average number of self-laying eggs, self-laying eggs per female, eggs remaining per female, the rate of eggs remaining per female and the total number of eggs per female were counted. The calculation of the relevant indicators is presented as follows:
DiAse = DiTse/DiTsf
Ase = Tse/Tf
Te = Tse + dTe
Are = Tre/Tf
Rre = Tre/Te × 100%
where DiAse indicates the average number of self-laying eggs on day i; DiTse is the total number of self-laying eggs on day i; DiTsf is the number of surviving female moths on day i; Ase indicates the average self-laying of eggs per female; Tse is the total number of self-laying eggs over the lifetime; Tf is the total number of female moths in the treatment; Te is the total number of S. c. ricini eggs; dTe represents the total number of eggs obtained by dissecting; Are indicates the average number of remaining eggs per female; Tre indicates the number of remaining eggs; Rre is the rate of remaining eggs.

2.2.2. Developmental Duration

We collected female S. c. ricini within 0.5 h of emergence and divided them into three equal parts. The female moths were cultured at 25 °C for 0 h, 5 h and 24 h and then dissected to retrieve the eggs, and there were no additional nutrients during the culture period. After the eggs were washed with detergent and dried, the number of immature eggs, empty eggshells and qualified eggs were counted immediately, and the total number of qualified eggs was calculated (Equation (6)). The eggs characterized by thin eggshells, the easy loss of moisture within the egg and a greenish color were defined as immature eggs. The identification of qualified and immature eggs was made in accordance with the local standard of Guangdong Province [44].
Tqe = Tse + dTqe
where Tqe indicates the total number of qualified eggs, Tse is the total number of self-laying eggs and dTqe represents the total number of qualified eggs obtained through dissection.

2.2.3. Functional Response

This experiment was carried out in an artificial climatic chamber with 25 °C, RH 70 ± 5%, L:D = 14:10 to explore the functional response of T. chilonis to the eggs of S. c. ricini. The host density was set to five treatments (13, 20, 40, 80, 120 eggs), with 10 replications for each treatment. At the beginning of the experiment, suitable egg masses were selected and cut, along with the spawning paper, to eventually form similar-sized egg cards. In a flat-bottomed glass tube (2 cm in diameter and 8 cm in length), an egg card with a single layer of 13, 20, 40, 80 and 120 freshly laid eggs of S. c. ricini was inserted. The test female wasp was T. chilonis within the parasitized eggs of C. cephalonica. Wasp cards were prepared before the test; each wasp card contained 100 eggs of a C. cephalonica that was parasitized by T. chilonis, and the parasitized eggs were due to emerge from the T. chilonis adults in 2 h. According to the local standard of Guangdong Province [44], each wasp card containing 100 eggs of C. cephalonica parasitized by T. chilonis will produce about 40 adult females of T. chilonis. After 24 h of parasitism, the parent wasps were removed, and the parasitized eggs of S. c. ricini were returned to the climatic chamber to continue cultivation. Breathable gauze was used to plug the mouth of the tube, and no food was provided to T. chilonis during the test period. The parasitism rate (PR) and emergence rate (ER) were calculated using the following equation:
PR (%) = Np/Nh × 100%
ER (%) = eNp/Np × 100%
where Np is the number of parasitized eggs and Nh is the total number of host eggs in a treatment, while eNp indicates the number of parasitized eggs that emerged.
The methodology used to establish the experimental population life table for T. chilonis parasitized by the eggs of S. c. ricini was referenced in previous research [45,46], and the calculation of the life table parameters, including net reproduction rate (R0), mean generation time (T), intrinsic natural growth rate (r) and finite growth rate (λ), can be found in the work of Xu et al. [47], as described in detail in our previous study [48].
The analysis of the experiment aiming to determine the functional response of T. chilonis to the eggs of S. c. ricini, was performed in two steps [49]. Firstly, a regression analysis of the number of parasitized hosts (Na) compared to the initial host density (N0) was performed to determine the type of functional response obtained using logistic regression. The polynomial function was fitted as follows:
N a N 0 = exp P 0 + P 1 N 0 + P 2 N 0 2 + P 3 N 0 3 1 + exp P 0 + P 1 N 0 + P 2 N 0 2 + P 3 N 0 3
where Na is the number of hosts parasitized, N0 is the initial host density, and P0, P1, P2 and P3 are the intercept, linear, quadratic and cubic coefficients, respectively. The maximum likelihood estimation was used for parameter estimation [50]. Secondly, the type of functional response was judged according to the positive and negative parameters: a type I functional response was considered when P1 = 0, type II functional response when P1 < 0 and a type III functional response when P1 > 0 and P2 < 0 [51]. After determining the type of functional response, the handling time and instantaneous attack rates for functional response type II were assessed using Rogers’ random parasitoid model [52]:
N a = N 0 ( 1 - exp ( α ( T h N a - T ) ) )
In which Na is the number of hosts parasitized, N0 is the initial host density, α is the instantaneous attack rate (h−1), Th is the handling time used by the parasitoid wasp to treat one host in hours and T is the total parasitic time (24 h).
The handling time and instantaneous attack rates for functional response type III were estimated using the following equations:
N a = a e b / N 0
Na is the number of hosts parasitized; a is the maximum number of parasitized; b is the optimal search density; N0 is the host density.

2.2.4. Wasp-to-Egg Ratios

We collected fresh parthenogenetic self-laying eggs of S. c. ricini laid within 24 h, which were washed with detergent and dried for the experiment. Five treatments were set up in this experiment, including T. chilonis-to-S. c. ricini egg ratios of 3:1, 2:1, 1:1, 1:2 and 1:3, with 10 replicates for each treatment. The corresponding treatments filled the tubes with 13, 20, 40, 80 and 120 S. c. ricini eggs (Table 1) in the form of loose eggs in the centrifuge tubes and the position of the eggs in the tubes was adjusted so that they were at the other end, away from the opening of the centrifuge tubes, and were in a single flat layer.
This experiment in this section was carried out using the above-mentioned wasp cards (2.2.3). The wasp card was inserted into the centrifuge tube and the opening of the tube was sealed with breathable paper and a rubber band. All the centrifuge tubes in the experiment were placed horizontally and flat in the light environment, making sure that the end with S. c. ricini eggs was towards the light and that all S. c. ricini eggs in the tubes were in the light. To avoid the reparasitization of S. c. ricini eggs by the emerged second-generation T. chilonis, on the 7th day of the experiment, the severely dried out S. c. ricini eggs that were not parasitized, the hatched S. c. ricini larvae that were removed from each centrifuge tube, the wasp cards and the parents of T. chilonis that had emerged were cleared; only the parasitized eggs of S. c. ricini that had turned black were retained and the mouths of the tubes were resealed with breathable paper and rubber bands. Then, the eggs were returned to the artificial climatic chamber for further development. After the offspring of T. chilonis had emerged and died, the number of females and males of T. chilonis offspring and the number of parasitized eggs that emerged from T. chilonis was recorded in each tube. The S. c. ricini eggs from which T. chilonis did not emerge were dissected one by one to check whether they were parasitized; then, the number of parasitized eggs from which T. chilonis did not emerge was recorded. The number of parasitized eggs, adult offspring and female offspring were counted, and the parasitism rate (Equation (7)), emergence rate (Equation (8)) and female sex ratio of offspring were calculated per tube as follows:
Np = eNp + neNp
fRo = NFo/NAo × 100%
where Np is the number of parasitized eggs; eNp indicates the number of parasitized eggs that emerged; neNp denotes the number of parasitized eggs that did not emerge; fRo is the female ratio of T. chilonis offspring; NFo represents the number of T. chilonis female offspring; NAo indicates the number of T. chilonis offspring adults.

2.3. Statistical Analysis

All data were statistically analyzed and processed using Excel 2010 (Microsoft Corporation, Redmond, WA, USA), statistical tests were performed on the computer using the software SAS V9.0 (SAS Institute Inc., Cary, NC, USA) and the NLIN program in SAS was used to estimate the parameters of attack rate (α) and handling time (Th). Significant differences among treatments were determined as one-way ANOVA and Duncan’s new complex polar difference method was used for multiple comparisons. S. c. ricini female survival rate was compared through a Kaplan–Meier survival analysis followed by a log rank test in GraphPad Prism 8 software (GraphPad Software Inc., San Diego, CA, USA). The graphs were drawn using Excel 2010 and GraphPad Prism 8 software.

3. Results

3.1. Effects of Developmental Temperature on the Longevity and Oviposition of S. c. ricini

There are some differences in the longevity and oviposition of female adults when using different developmental temperatures. The survival rate of female adults per day, at 25 °C, was higher than that of the other treatments, and the lowest was observed at 31 °C (Figure 1a); however, the difference in survival rate between these treatments was not significant (χ2 = 3.6, df = 3, p = 0.3). The longevity of female moths, at 25 °C, was significantly longer than the other treatments (Table 2), and the longevity at 28 °C and 31 °C was significantly shorter than that at 22 °C and 25 °C (F = 16.299, df = 3, p < 0.001). Females of S. c. ricini were observed to have an oviposition period of about 15 days and the average number of self-laying eggs per day showed an upward and then downward trend (Figure 1b), which reached a peak at 3–5 days and then declined each day. The peak period of oviposition was within 1 week after the emergence. The average number of self-laying eggs per day increased with temperature within 1–6 days after the emergence of female adults. At the 22 °C culture conditions, the total number of self-laying eggs of S. c. ricini was significantly lower than the other treatments (F = 9.559, df = 3, p < 0.001), whereas the average number of remaining eggs (F = 6.414, df = 3, p < 0.001) and the rate of remaining eggs (F = 6.418, df = 3, p < 0.001) were considerably higher than in the other treatments. The total number of eggs of S. c. ricini was significantly higher at 28 °C and 31 °C than at 22 °C (F = 3.195, df = 3, p < 0.001.025), whereas the differences in the total number of self-laying eggs and the average number of remaining eggs per female, the rate of remaining eggs and the total number of S. c. ricini eggs were not significant among the treatments of 25 °C, 28 °C and 31 °C.

3.2. Effects of Developmental Duration on the Quality of S. c. ricini Eggs

The female moths of S. c. ricini were collected just after emergence. Of the eggs obtained via immediate dissection, the rates of immature and qualified eggs were 32.48 ± 1.87% and 67.52 ± 1.87% (Figure 2), respectively. After the development of the female moths at 25 °C for 5 h, the rates of immature and qualified eggs received from dissections were 30.21 ± 5.20% and 69.79 ± 5.20%, respectively, and there was no significant increase in the rate of qualified eggs compared with the development of 0 h. Among the female moths that continued to develop until 24 h and then were dissected for eggs the rate of immature eggs (6.83 ± 1.52%) was significantly lower than that obtained using the other treatments (F = 18.407, df = 2, p < 0.001), whereas the rate of qualified eggs (93.17 ± 1.52%) was significantly higher than in the other treatments (F = 18.407, df = 2, p < 0.001). After 24 h of development, the eggs of S. c. ricini matured and were successively produced. To avoid the high rate of immature eggs obtained through dissection, it is necessary to give the female moth sufficient development time to obtain a higher rate of qualified eggs.

3.3. Functional Response of T. chilonis to S. c. ricini Eggs

3.3.1. Population Growth of T. chilonis

The egg density of S. c. ricini has a significant effect on the population growth of T. chilonis (Table 3). The average total number of T. chilonis (TW) and the average number of T. chilonis females (FW) produced by S. c. ricini eggs were significantly higher at egg densities of 80 and 120 than at densities of 13, 20 and 40, and at the egg density at 40, the results were also significantly higher than those obtained at a density of 13. With the increase in host density, the average number of T. chilonis females produced by a single S. c. ricini female (FWpf) also increased. At egg densities of 80 and 120, the net reproductive rate of T. chilonis was found to be significantly higher than that of other treatments (p < 0.05). Moreover, the intrinsic rate of increase and the finite rate of increase of T. chilonis exhibited a significant upward trend with the increase in egg density. Except for the treatment with an egg density of 13, the population multiplication time of T. chilonis was significantly shorter with increasing egg density. These results suggest that a host egg density of 120 was most favorable for population reproduction within the density range of this experiment.

3.3.2. Parasitic capacity of T. chilonis

A logistic regression analysis showed the linear coefficient of P1 < 0 for S. c. ricini eggs parasitized by T. chilonis, which indicates that the functional response was type II (Table 4). The Holling type II model was further fitted to obtain the functional response model for each temperature condition (Table 5). The instantaneous attack rate (α) of the T. chilonis parasitizing S. c. ricini eggs was 0.1840 and the handling time (Th) was 0.4628 d. The maximal parasitic was 2.16 eggs and the r of the functional equation was 0.9703, which provided a good fit to the equation. The parasitism of T. chilonis on the eggs of S. c. ricini increased with host density to a certain amount and then stopped, and the trend line equation showed a good match (Figure 3).

3.4. Effects of the Wasp–Egg Ratio on the Reproduction of T. chilonis Using S. c. ricini Eggs

The wasp-to-egg ratio had a significant effect on the parasitism efficacy of T. chilonis (Figure 4). The number of parasitized eggs increased and then decreased as the wasp-to-egg ratio grew smaller, and the treatment with a wasp-to-egg ratio of 1:2 led to the highest number of parasitized eggs (34.00 ± 1.79), with significantly more eggs than that of the other four treatments. However, the number of parasitized eggs obtained using wasp-to-egg ratios of 3:1 and 2:1 was significantly lower than that obtained with the other three treatments (F = 23.859, df = 4, p < 0.001) (Figure 4a). The parasitism rates varied significantly among treatments; the lower the number of S. c. ricini eggs, the higher the parasitism rate for the same number of T. chilonis (Figure 4b).
In addition, there was a significant effect of wasp-to-egg ratio on the survival and development of T. chilonis offspring (Table 6). After parasitizing the eggs of S. c. ricini, T. chilonis offspring develops and lives inside the eggs until it emerges, bites through the shell of the parasitized eggs and drills its way out. The treatments with wasp-to-egg ratios of 1:2 and 1:3 had significantly more parasitized eggs that emerged (eNp) than the other three treatments (F = 19.47, df = 4, p < 0.001). The emergence rate (ER) increased with the number of S. c. ricini eggs. The emergence rate of the treatment with a wasp-to-egg ratio of 3:1 was notably lower than that in the other treatments, whereas that in the treatment with a wasp-to-egg ratio of 1:3 was higher than that in the other four treatments (F = 13.816, df = 4, p < 0.001). Additionally, the number of T. chilonis in the parasitized eggs that did not emerge (neNw) in the treatments with wasp-to-egg ratios of 1:2 and 1:3 was significantly lower than in the treatments with ratios of 3:1 and 2:1 (F = 8.823, df = 4, p < 0.001). Moreover, the number of adults (NAo, F = 15.954, d = 4, p < 0.001) and female adults of T. chilonis offspring (fNAo, F = 16.127, d = 4, p < 0.001), and the propagation coefficient (PC, F = 16.127, df = 4, p < 0.001), in the treatments with wasp-to-egg ratios of 1:2 and 1:3 were considerably higher than in the other treatments; all five treatments showed a high female ratio of over 85% in the T. chilonis offspring. When S. c. ricini eggs are used at a wasp-to-egg of 1:2–1:3, the same number of T. chilonis female parents can breed a higher number of adult offspring and female offspring, which exhibit an increased reproductive efficiency.

4. Discussion

Suitable intermediate host eggs are the key to breeding Trichogramma parasitoids, because the quality of the host eggs is related to the availability of nutrients for development, affecting the parasitism and emergence rates. The use of suitable host eggs also determines the propagation efficiency and cost of breeding Trichogramma parasitoids, while the knowledge of the intermediate host’s living characteristics and response to changes in the external environment provides the necessary basis to carry out the mass rearing of intermediate hosts and quality controls [9]. Insects are typical thermotropic animals, and temperature is an important environmental factor that affects their growth, development, reproduction and behavioral activities [53,54,55]. Previous studies have concluded that S. c. ricini is a non-stagnant insect; the appropriate temperature for indoor culture is 20–28 °C, and the longevity of adults is 10–12 d [34,56,57]. The results observed in this study are basically consistent with these findings. Our results suggest that post-feathered S. c. ricini have a higher survival rate and longer lifespan at 25 °C compared to that at lower (22 °C) and higher (28, 31 °C) temperatures, suggesting that the appropriate survival temperature for adults under laboratory conditions is 25 °C. Similarly, Wongsorn et al. [57] found that S. c. ricini survival rates and total egg production had maximum values of 25 °C compared to other temperature treatments. Generally, the developmental rate of insects starts at the critical thermal minimum and rises slowly with increases in temperature. The development rate rises almost linearly over a range of temperatures, continues to rise to the optimum level and finally falls rapidly following the critical maximum temperature [58]. Higher ambient temperatures can accelerate senescence by promoting insect development, shorten lifespan and worsen infection-based outcomes [59]. In addition, temperature significantly affected the oviposition of S. c. ricini. At lower temperatures (22 °C), S. c. ricini had fewer self-laying eggs and had a higher number of remaining eggs. Previous studies on several species of moths have indicated that egg production tended to increase and then decrease with temperature increases, i.e., egg production reached a maximum at a certain temperature, and excessively high or low temperatures lead to a decrease in egg production [60]. We found that the total number of S. c. ricini eggs increased with temperature in the range of 22 °C to 31 °C, whereas Wongsorn et al. [57] observed that in the temperature range of 25 °C to 48 °C, the total number of S. c. ricini eggs peaked at 36 °C (300.53 eggs/moth) and then declined. However, it is notable that we observed some abnormalities in the color of self-laying eggs at 31 °C during the experiment, and the appearance of the eggs (flattened and rounded) was not as good as that of the eggs formed under the treatments of 25 °C and 28 °C (Figure 5 presents the differences in the appearance of eggs; quantitative data of viable eggs were not counted in this study). Prior research has suggested that high temperatures (29 °C and 32 °C) may have an impact on egg quality by affecting ovarian development [61], but it has also been argued that high-temperature heatwaves (5–7 °C above optimal temperature) primarily influence male fecundity and sperm competitiveness, without impairing female reproduction [62]. In addition to the significant effect of temperature on the longevity and oviposition of S. c. ricini, the developmental duration after emergence also has a significant effect on oviposition. Normally, many insects require a period of time after emergence to achieve sexual maturity [63], and understanding the time it takes for insects to reach physiological maturity could help to deepen our knowledge. We found that more unqualified eggs were obtained at 0 h after emergence, whereas more qualified S. c. ricini eggs could be obtained 24 h after emergence. Harris and Rose [35] found that the development duration after emergence affected the time for Mayetiola destructor (Say) to reach sexual maturity, which in turn determined the onset of egg laying and affected the production of eggs and the distribution of egg laying time. For example, for females that mated 1, 2 and 3 h after emergence, the durations of the post-mating pre-ovipositional transition phase were 190, 160 and 120 min, respectively [35]. A sufficient developmental duration ensures the normal development and refinement of the insect’s reproductive organs so that the insect can lay eggs normally. If development is incomplete, there may be difficulty in laying eggs or a decrease in egg production. In summary, we concluded that 25–28 °C is the appropriate temperature range for the survival and egg-laying of S. c. ricini adults, and that adults need to experience at least 24 h of development after emergence to lay more qualified eggs.
Functional response analyses are often used to help predict the potential of parasitoids to regulate host populations [64,65]. Our results indicated that S. c. ricini exhibits a type II functional response to S. c. ricini eggs; the average number of hosts that parasitized eggs gradually increased with host density and attained the upper asymptote at an egg density of 80. Type II functional responses were common in Trichogramma spp.; more than 75% of relevant studies reported a type II functional response [42], and past studies have reported that T. chilonis showed type II functional responses to T. absoluta [42], C. cephalonica [7] and C. sacchariphagus [43]. The handling time of a Type II functional response involves subduing the host, accepting the host, spawning and then possibly cleaning and resting before moving on to find more hosts. Type II functional responses described an inverse density-dependent relationship between the proportion of parasitoids and the density of the hosts [36], i.e., biological agents are more effective at low pest densities. This provides an insight into the best means of field release for biological agents. Further references are provided for indoor T. chilonis reproduction, that is, low-density intermediate host eggs might be able to obtain a higher parasitism rate, which could lead to cost reductions and an increase in efficiency. For this reason, we carried out experiments on the reproduction of T. chilonis at different wasp–egg ratios, and our results showed that the parasitism rate decreased significantly with an increase in the number of S. c. ricini eggs when using the same number of T. chilonis. A similar phenomenon was observed by Li et al. [66] regarding the use of C. cephalonica eggs for T. chilonis reproduction. In addition, we found that the number of parasitized eggs that emerged, the emergence rate, the number of T. chilonis that emerged per S. c. ricini egg and the total number of T. chilonis gradually increased with the number of S. c. ricini eggs, which was consistent with the results observed by Lu et al. [67] when using A. pernyi eggs to breed T. chilonis. Compared to small eggs (C. cephalonica and S. cerealella), large eggs (A. pernyi and S. c. ricini) may contain more and richer nutrients, such as proteins and fats, providing more sufficient nutrients for the growth and development of T. chilonis larvae, which could lead to the production of more wasps. We observed the highest number of T. chilonis (186.80 ± 22.73) produced by a single S. c. ricini egg in the treatment with wasp–egg ratio of 1:3. However, not every parasitized egg successfully emerged, and previous studies have shown that some Trichogramma spp. can develop into adults in A. pernyi eggs but ultimately die in the egg because they are unable to bite through the egg shell [23,68]; this may be related to the lower emergence rates we observed. Furthermore, with an increase in proportion of the inoculation of parasitoids and host eggs, the frequency of superparasitism increased, and the body size, sex ratio of female offspring and number of emerged adults reduced [69]. This might explain the few emergences found in the wasp-to-egg treatments of 3:1 and 2:1 in our study. There was no significant difference in propagation performance between the treatments with wasp-to-egg ratios of 1:2 and 1:3, but there was a significant difference in emergence rate; therefore, based on the cost of S. c. ricini egg supply, a wasp-to-egg ratio of 1:2 may be suitable for T. chilonis propagation.
Although we explored the effects of developmental temperature and duration on the development and oviposition of S. c. ricini adults, other conditions, such as light, humidity and food sources, are also important influencing factors. In addition, egg management and quality control techniques, such as egg acquisition methods and egg storage, are important factors affecting the propagation efficacy of T. chilonis. Therefore, in the future, we should strengthen the knowledge of some important biotic and abiotic factors affecting the production of castor silkworms to provide a scientific basis for optimizing the breeding environment of S. c. ricini and improving the production of S. c. ricini, as well as to provide technological support for the establishment of a complete system of S. c. ricini egg production, storage and usage.

5. Conclusions

Our results indicated that developmental temperature and duration after the emergence of S. c. ricini significantly affected the survival and oviposition of adults, that a suitable temperature range for the survival and egg-laying of adults after emergence is 25–28 °C, and that at least 24 h of development is required to obtain more qualified S. c. ricini eggs. T. chilonis exhibited a type II functional response to S. c. ricini eggs. The usage of S. c. ricini eggs for the reproduction of T. chilonis resulted in a high female ratio among offspring and S. c. ricini eggs showed an excellent reproductive performance. Different ratios of T. chilonis to S. c. ricini eggs significantly influenced the reproduction performance, with more T. chilonis offspring per S. c. ricini egg being obtained under the treatments with wasp-to-egg ratios of 1:2 and 1:3, showing a high propagation efficiency. However, given the cost of eggs, we concluded that a wasp-to-egg ratio of 1:2 is suitable for the reproduction of T. chilonis. There are still more aspects to be explored regarding the use of S. c. ricini for the reproduction of T. chilonis; however, our results may provide some valuable insights into the reproduction of T. chilonis.

Author Contributions

Conceptualization, X.Y.; methodology, X.Y. and W.D.; software, X.Y.; validation, W.D.; formal analysis, X.Y.; investigation, X.Y. and W.D.; resources, X.Y.; data curation, X.Y.; writing—original draft preparation, X.Y.; writing—review and editing, D.L.; visualization, X.Y.; supervision, X.Y.; project administration, X.Y. and D.L.; funding acquisition, X.Y. and D.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Science and Technology Plan Project of Maoming City (No. 2023S013075).

Data Availability Statement

The data presented in this study are available from the corresponding author upon request.

Acknowledgments

The present study was carried out in the laboratory of the Institute of Plant Protection, Guangdong Academy of Agricultural Sciences, and we are thankful for the support and assistance provided by our team; we would also like to thank the reviewers, who provided suggestions, insights and recommendations regarding the content and conclusions of this study, which greatly improved our manuscript.

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. Daily changes in survival rate (a) and the number of self-laying eggs of S. c. ricini females (b) at different temperatures.
Figure 1. Daily changes in survival rate (a) and the number of self-laying eggs of S. c. ricini females (b) at different temperatures.
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Figure 2. Effects of developmental duration on the egg quality of S. c. ricini. (a) The rate of immature eggs (%); (b) the rate of qualified eggs (%). The columns in the figure represent the average value for that treatment, the error bars indicate the standard error and different lowercase letters in the figures indicate significant differences at the p < 0.05 level, as tested by Duncan’s new complex polarity test.
Figure 2. Effects of developmental duration on the egg quality of S. c. ricini. (a) The rate of immature eggs (%); (b) the rate of qualified eggs (%). The columns in the figure represent the average value for that treatment, the error bars indicate the standard error and different lowercase letters in the figures indicate significant differences at the p < 0.05 level, as tested by Duncan’s new complex polarity test.
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Figure 3. Functional response of T. chilonis to S. c. ricini eggs over 24 h period; the light orange sections represent 95% confidence intervals.
Figure 3. Functional response of T. chilonis to S. c. ricini eggs over 24 h period; the light orange sections represent 95% confidence intervals.
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Insects 15 00963 g004
Figure 4. Effects of the wasp–egg ratio on the parasitism efficacy of T. chilonis on S. c. ricini eggs. (a) The number of parasitizing eggs; (b) parasitism rate (%). The columns in the figure represent the average value for that treatment, the error bars indicate the standard error and different lowercase letters in the figures indicate significant differences at the p < 0.05 level, as tested by Duncan’s new complex polarity test.
Figure 4. Effects of the wasp–egg ratio on the parasitism efficacy of T. chilonis on S. c. ricini eggs. (a) The number of parasitizing eggs; (b) parasitism rate (%). The columns in the figure represent the average value for that treatment, the error bars indicate the standard error and different lowercase letters in the figures indicate significant differences at the p < 0.05 level, as tested by Duncan’s new complex polarity test.
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Insects 15 00963 g005
Figure 5. Morphology of eggs laid by S. c. ricini female adults incubated at 25 °C (A) and 31 °C (B), and developmental status of T. chilonis in S. c. ricini eggs (C). The red dots in the figure indicate immature eggs and the blue dots represent empty eggshells.
Figure 5. Morphology of eggs laid by S. c. ricini female adults incubated at 25 °C (A) and 31 °C (B), and developmental status of T. chilonis in S. c. ricini eggs (C). The red dots in the figure indicate immature eggs and the blue dots represent empty eggshells.
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Table 1. Number of T. chilonis and S. c. ricini eggs used in different treatments.
Table 1. Number of T. chilonis and S. c. ricini eggs used in different treatments.
Treatments (Wasp-to-Egg Ratio)3:12:11:11:21:3
Number of T. chilonis3940404040
Number of S. c. ricini eggs13204080120
Table 2. The average longevity and eggs number of S. c. ricini females under different temperatures.
Table 2. The average longevity and eggs number of S. c. ricini females under different temperatures.
Temperature (°C)Longevity (d)TseAreRre (%)Te
2210.50 ± 0.49 b144.4 ± 16.2 b95.2 ± 17.5 a35.81± 6.39 a239.6 ± 17.9 b
2512.13 ± 0.40 a251.4 ± 13.5 a27.2 ± 7.2 b11.89 ± 3.27 b273.3 ± 11.5 ab
289.28 ± 0.34 c239.6 ± 14.9 a42.3 ± 10.8 b15.08 ± 3.47 b281.9 ± 12.2 a
319.02 ± 0.26 c265.1 ± 17.5 a39.5 ± 9.2 b14.02 ± 3.24 b304.6 ± 14.9 a
Note: Tse is the total number of self-laying eggs over the lifetime; Are indicates the average number of remaining eggs per female; Rre is the rate of remaining eggs; Te is the total number of S. c. ricini eggs. Data in the table are the average ± standard errors, and different lowercase letters in the same column indicate significant differences at the p < 0.05 level, as tested by Duncan’s new complex polarity test.
Table 3. Effects of egg density of S. c. ricini on the life table parameters of the experimental population of T. chilonis.
Table 3. Effects of egg density of S. c. ricini on the life table parameters of the experimental population of T. chilonis.
Egg DensityR0rmλT (d)FWpfSex Ratio (%)FWTW
130.475 ± 0.028 c−0.073 ± 0.032 e0.930 ± 0.010 c−9.50 ± 0.17 d0.485 ± 0.271 e97.9 ± 2.74 a19.0 ± 6.88 c19.4 ± 7.07 c
201.088 ± 0.318 b0.008 ± 0.027 d1.008 ± 0.018 b83.51 ± 0.89 a1.238 ± 0.885 d87.8 ± 4.95 b43.4 ± 16.15 bc49.4 ± 18.11 bc
401.893 ± 0.265 b0.063 ± 0.006 c1.063 ± 0.027 b11.07 ± 0.37 b2.047 ± 0.713 c92.4 ± 2.02 ab75.7 ± 12.43 b81.9 ± 14.40 b
804.033 ± 1.893 a0.137 ± 0.012 b1.146 ± 0.008 b5.07 ± 0.62 c4.280 ± 0.830 b94.2 ± 2.79 ab161.3 ± 26.38 a171.2 ± 26.78 a
1204.670 ± 1.438 a0.151 ± 0.006 a1.163 ± 0.012 a4.59 ± 0.54 c5.160 ± 1.375 a90.5 ± 1.52 ab186.8 ± 22.73 a206.4 ± 26.54 a
Note: R0 is net reproductive rate; rm denotes intrinsic rate of increase; λ indicates finite rate of increase; T represents population multiplication time; FWpf refers to the average number of female wasps (T. chilonis) produced per female insect (S. c. ricini); FW is the average number of female wasps (T. chilonis); TW means the average total number of wasps (T. chilonis). Data in the table are the means average ± standard errors; different letter in the columns represented significant difference (p < 0.05, Tukey’s test).
Table 4. Statistical parameters of logistic regression analysis.
Table 4. Statistical parameters of logistic regression analysis.
ParametersEstimateStandard Errorχ2p-Value
P03.41960.475351.76<0.0001
P1−0.11260.026717.85<0.0001
P20.001250.0004159.050.0026
P3−0.0000005280.00000018967.740.0054
Table 5. Functional response parameters of T. chilonis.
Table 5. Functional response parameters of T. chilonis.
Functional Response TypeII-Type
Maximal parasitic (egg/d)2.16
A0.1840 ± 0.0711
Th (d)0.4628 ± 0.0502
Functional equationNa = 0.1840N/(1 + 0.4628N)
R20.9703
Note: Data in the table are the average ± standard errors. α, instantaneous attack rate; Th, handling time (d).
Table 6. Effects of different wasp-to-egg ratios on the development and survival of T. chilonis offspring and reproductive efficiency.
Table 6. Effects of different wasp-to-egg ratios on the development and survival of T. chilonis offspring and reproductive efficiency.
TreatmentDevelopment and Survival of T. chilonis OffspringReproductive Efficiency
eNpER (%)eNfwneNwNAofNAofRo (%)PC
3:11.20 ± 0.42 c9.39 ± 3.21 d19.00 ± 6.88 c30.24 ± 1.31 b19.40 ± 7.07 c19.00 ± 6.88 c98.41 ± 1.12 a0.4750 ± 0.1720 c
2:13.10 ± 0.90 bc20.60 ± 5.31 c43.40 ± 16.15 bc34.55 ± 1.30 a49.40 ± 18.11 bc43.40 ± 16.15 bc85.64 ± 4.95 c1.0850 ± 0.4038 bc
1:16.20 ± 1.04 b23.96 ± 3.96 c75.70 ± 12.43 b28.19 ± 1.19 bc81.90 ± 14.40 b75.70 ± 12.43 b94.33 ± 2.02 ab1.8925 ± 0.3107 b
1:212.10 ± 1.63 a35.28 ± 3.87 b161.30 ± 26.38 a24.92 ± 1.28 c171.20 ± 26.78 a161.30 ± 26.38 a92.79 ± 2.79 ab4.0325 ± 0.6595 a
1:312.60 ± 1.46 a46.87 ± 2.31 a186.80 ± 22.73 a28.87 ± 0.72 c206.40 ± 20.54 a186.80 ± 22.72 a91.83 ± 1.52 ab4.6700 ± 0.5682 a
Note: eNp, the number of parasitized eggs that emerged; ER, emergence rate; eNfw, the number of female waps (T. chilonis) that emerged per egg (S. c. ricini); neNw, the number of wasps that did not emerge per egg (S. c. ricini); NAo, the number of offspring adults; fNAo, the number of females in offspring adults; fRo, the female ratio of offspring adults; PC, propagation coefficient. Data in the table are the means average ± standard errors; different letters in the columns represent significant difference (p < 0.05, Tukey’s test).
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Yuan, X.; Li, D.; Deng, W. Research on the Reproduction of Trichogramma chilonis Based on Samia cynthia ricini Eggs: Temperature, Functional Response and Proportional Effect. Insects 2024, 15, 963. https://doi.org/10.3390/insects15120963

AMA Style

Yuan X, Li D, Deng W. Research on the Reproduction of Trichogramma chilonis Based on Samia cynthia ricini Eggs: Temperature, Functional Response and Proportional Effect. Insects. 2024; 15(12):963. https://doi.org/10.3390/insects15120963

Chicago/Turabian Style

Yuan, Xi, Dunsong Li, and Weili Deng. 2024. "Research on the Reproduction of Trichogramma chilonis Based on Samia cynthia ricini Eggs: Temperature, Functional Response and Proportional Effect" Insects 15, no. 12: 963. https://doi.org/10.3390/insects15120963

APA Style

Yuan, X., Li, D., & Deng, W. (2024). Research on the Reproduction of Trichogramma chilonis Based on Samia cynthia ricini Eggs: Temperature, Functional Response and Proportional Effect. Insects, 15(12), 963. https://doi.org/10.3390/insects15120963

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