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The ‘Goldilocks Grub’: reproductive responses to leafroller host development in Goniozus jacintae, a parasitoid of the light brown apple moth

Published online by Cambridge University Press:  12 September 2024

Emma Aspin
Affiliation:
School of Agriculture, Food & Wine, University of Adelaide, Waite Campus, Adelaide, Australia School of Biosciences, University of Nottingham, Sutton Bonington Campus, Loughborough, UK
Michael A. Keller
Affiliation:
School of Agriculture, Food & Wine, University of Adelaide, Waite Campus, Adelaide, Australia
Ian C. W. Hardy*
Affiliation:
School of Biosciences, University of Nottingham, Sutton Bonington Campus, Loughborough, UK Department of Agricultural Sciences, University of Helsinki, Helsinki, Finland
*
Corresponding author: Ian C. W. Hardy; Email: [email protected]
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Abstract

Many parasitoids alter their reproductive behaviour in response to the quality of encountered hosts. They make adaptive decisions concerning whether to parasitise a potential host, the number of eggs laid on an accepted host, and the allocation of sex to their offspring. Here we present evidence that Goniozus jacintae Farrugia (Hymenoptera: Bethylidae), a gregarious ectoparasitoid of larval tortricids, adjusts its reproductive response to the size and developmental stage of larvae of the light brown apple moth (LBAM), Epiphyas postvittana (Walker) (Lepidoptera: Tortricidae). Goniozus jacintae parasitises instars 3–6 of LBAM, but most readily parasitises the later, larger, instars. Brood sizes were bigger on larger hosts and brood sex ratios were female biased (proportion of males = 0.23) with extremely low variance (never >1 male in a brood at emergence), perhaps the most precise of all studied bethylids. Host size did not influence brood development time, which averaged 19.64 days, or the body size of male offspring. However, the size of females was positively correlated with host size and negatively correlated with brood size. The sizes of individual males and females were positively related to the average amount of host resource available to individuals within each brood, suggesting that adult body size is affected by scramble competition among feeding larvae. Average brood sizes were: 3rd instar host, 1.3 (SE ± 0.075); 4th instar, 2.8 (SE ± 0.18); 5th instar, 4.7 (SE ± 0.23); 6th instar, 5.4 (SE ± 0.28). The largest brood size observed was 8 individuals (7 females, 1 male) on the 6th instar of LBAM. These results suggest that later instars would give the highest yield to optimise mass-rearing of G. jacintae if used for augmentative biological pest control.

Type
Research Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press

Introduction

Upon finding a potential host, female hymenopteran parasitoids typically assess the quality of the host for offspring development (Rehman and Powell, Reference Rehman and Powell2010; Hajek and Eilenberg, Reference Hajek and Eilenberg2018) and make oviposition decisions in response to host condition (Visser et al., Reference Visser, van Alphen and Nell1990; Hardy et al., Reference Hardy, Griffiths and Godfray1992; Godfray, Reference Godfray1994; Bezemer and Mills, Reference Bezemer and Mills2003; Ayala et al., Reference Ayala, Pérez-Lachaud, Toledo, Liedo and Montoya2018; Li et al., Reference Li, Li and Meng2019). These oviposition decisions include the number of eggs laid (Godfray, Reference Godfray1987, Reference Godfray1994), and the allocation of sex to offspring (West, Reference West2009). Size-dependent selection of hosts is common in parasitoids, since the size of a host is often positively correlated with host quality via the quantity of resources available to offspring (Charnov and Skinner, Reference Charnov and Skinner1984; Godfray, Reference Godfray1994; Goubault et al., Reference Goubault, Fourrier, Krespi, Poinsot and Cortesero2004; Rehman and Powell, Reference Rehman and Powell2010), which influences how many progeny can be supported per host. In general, females are selected to lay a clutch size that maximises their gain in fitness across all hosts they expect to find during their lifetime (Godfray et al., Reference Godfray, Partridge and Harvey1991). In terms of sex allocation, mated haplo-diploid hymenopteran parasitoids are able to control whether their eggs remain unfertilised or become fertilised, developing into males or females, respectively (Godfray, Reference Godfray1994; Quicke, Reference Quicke1997). Understanding the reproductive strategies of parasitoids can be important for the successful implementation of biological pest control programmes, as these directly influence the number of female offspring recruited into each generation, and therefore, the degree to which target pest populations are likely to be suppressed (Hassell, Reference Hassell2000; Ode and Hardy, Reference Ode, Hardy, Wajnberg, Bernstein and van Alphen2008).

Here we report on the responses of Goniozus jacintae Farrugia (Hymenoptera: Bethylidae) to the size and developmental stages of larvae of the light brown apple moth (LBAM), Epiphyas postvittana (Walker) (Lepidoptera: Tortricidae) (Danthanarayana, Reference Danthanarayana1980; Aspin et al., Reference Aspin, Keller, Yazdani and Hardy2021). This moth feeds on a wide range of crops and other plants (Suckling and Brockerhoff, Reference Suckling and Brockerhoff2010), and is the most damaging insect pest of grapevines in Australia (Scholefield and Morison, Reference Scholefield and Morison2010). Despite the common occurrence of G. jacintae (fig. 1a) as a beneficial insect, there is surprisingly little knowledge of its efficacy as a biological control agent for LBAM (Danthanarayana, Reference Danthanarayana1980; Paull and Austin, Reference Paull and Austin2006) and limited information on its reproductive biology (Danthanarayana, Reference Danthanarayana1980; Hopper and Mills, Reference Hopper and Mills2015). A recent study of G. jacintae foraging behaviour found that females have a stronger foraging response to larger hosts, which have a higher rate of feeding and produce more feeding damage (Aspin et al., Reference Aspin, Keller, Yazdani and Hardy2021). This is consistent with reports of other species of Goniozus, that have a greater reproductive success when attacking larger hosts (Hardy et al., Reference Hardy, Griffiths and Godfray1992; Luft, Reference Luft1993; Abdi et al., Reference Abdi, Lupi and Hardy2020).

Figure 1. Development of G. jacintae on light brown apple moth. Successive stages of development of a brood of G. jacintae on E. postvittana: (a) Host encounter: female G. jacintae on a paralysed 6th instar LBAM larva on a plantain leaf, (b) Day 1: eggs of G. jacintae laid on host's integument, (c) Day 6: larvae of G. jacintae, (d) Day 8: late instar larvae of G. jacintae and the head capsule of the consumed host, (e) Day 10: pupating larvae of G. jacintae inside their silken cocoons. Photo (A) has had the background changed to greyscale for clarity; the original leaf colour is green.

The Bethylidae is a cosmopolitan family of ectoparasitoid wasps, containing over 2000 described species within around 100 genera (Gordh and Móczár, Reference Gordh and Móczár1990). Their hosts are predominantly coleopteran or lepidopteran larvae that often live in cryptic locations, such as seed-borers and leafrollers (Evans, Reference Evans1978; Mayhew and Hardy, Reference Mayhew and Hardy1998). However, some bethylid species are reported to attack hosts in the pupal stage (Pérez-Lachaud et al., Reference Pérez-Lachaud, Batchelor and Hardy2004) and even hosts from other insect orders (Zhang et al., Reference Zhang, Song and Fan1984). Bethylid species have been used in research on the evolution of key life history traits, such as clutch size, sex allocation and sociality (Hardy et al., Reference Hardy, Griffiths and Godfray1992; Mayhew and Hardy, Reference Mayhew and Hardy1998; Goubault et al., Reference Goubault, Scott and Hardy2007; Khidr et al., Reference Khidr, Mayes and Hardy2013; Abdi et al., Reference Abdi, Lupi and Hardy2020; Guo et al., Reference Guo, Wang, Meng, Hardy and Li2022, Reference Guo, Zhou, Zhao, Meng, Hardy and Li2023; Malabusini et al., Reference Malabusini, Hardy, Jucker, Savoldelli and Lupi2022). Further, as many bethylid species utilise hosts that are pests of agriculturally important products, multiple species have been deployed, or considered as, biological control agents across a wide range of agro-ecosystems (Legner and Gordh, Reference Legner and Gordh1992; Batchelor et al., Reference Batchelor, Hardy and Barrera2006; Shameer et al., Reference Shameer, Nasser, Mohan and Hardy2018; Polaszek et al., Reference Polaszek, Almandhari, Fusu, Al-Khatri, Al Naabi, Al Shidi, Russell and Hardy2019).

Goniozus jacintae readily parasitizes larval instars 3 to 6 of LBAM (Danthanarayana, Reference Danthanarayana1980; Aspin et al., Reference Aspin, Keller, Yazdani and Hardy2021). We thus investigated whether its reproductive behaviour varies according to host size and instar, first establishing whether host head capsule size or host weight better represents host size. Our ultimate aim was to provide a broader understanding of bethylid reproduction that could elucidate the potential of G. jacintae to control LBAM in the field. Information from this study will further contribute to the growing collection of other agro-ecosystems using species of Goniozus and other bethylids as agents of biological pest control (Legner and Gordh, Reference Legner and Gordh1992; Baker, Reference Baker1999; Batchelor et al., Reference Batchelor, Hardy and Barrera2006; Shameer et al., Reference Shameer, Nasser, Mohan and Hardy2018; Polaszek et al., Reference Polaszek, Almandhari, Fusu, Al-Khatri, Al Naabi, Al Shidi, Russell and Hardy2019) and assist the increase in efficacy of mass-rearing bethylid parasitoids in the laboratory.

Materials and methods

Host rearing

The culture of Epiphyas postvittana (LBAM) used in this experiment was established at the South Australian Research and Development Institute in 1994 and has since been maintained with annual additions of wild-caught moths. LBAM was reared on an artificial diet at 22 ± 2°C under 12L:12D photoperiod, following methods reported in Yazdani et al. (Reference Yazdani, Feng, Glatz and Keller2015).

Parasitoid rearing

A culture of G. jacintae was established from individuals reared from parasitized LBAM that were collected in vineyards at McLaren Vale, South Australia in 2017. The wasp culture was reared at 23 ± 2°C, 14L:10D in cages on larval LBAM that infested plantain, Plantago lanceolata L. (Lamiales: Plantaginaceae). Adult wasps were provided with water and honey ad libitum. Wasp cocoons were isolated in 50 mm × 18 mm diam. glass vials containing a drop of honey and fitted with caps that had screens for ventilation. Upon emergence, females were caged serially, 2–5 at a time, with 5 males to allow mating, and then re-isolated and held in vials for at least 1 h before being used in experiments.

Parasitoid reproduction

One hundred and sixty female G. jacintae were individually presented with one 4th instar LBAM larva feeding on a plantain leaf in a 50 mm × 18 mm diam. glass vial for 1 h so that they may have obtained oviposition experience prior to the experiment. The 4th instar was chosen as it represented the mean size of LBAM larvae, and according to Danthanarayana (Reference Danthanarayana1980), are the most predominantly parasitized instar by G. jacintae. Following this, each wasp was presented with a single host of known instar (3rd–6th), head capsule width and weight in a fresh glass vial. Once host attack was observed, the vial was left for 2 h to allow for oviposition behaviour to occur.

After oviposition, the female parasitoid was removed and the host and parasitoid clutch were maintained at at 22 ± 2°C under 12L:12D photoperiod until brood emergence. Upon emergence of the adult parasitoids, the following measurements were recorded: brood size ( = number of adult offspring), sex ratio ( = proportion of offspring that were males), time from oviposition to adult eclosion ( = developmental time) and length of thorax (an indicator of parasitoid body size).

Host size may be measured in several ways, including weight and head capsule width, and both may correlate with host instar. We took both measurements for LBAM larvae of each instar used in this experiment (3rd–6th), including the head capsule measures sizes for the 6th instar which have not been reported previously (Yazdani et al., Reference Yazdani, Glatz and Keller2014). Head capsule width was measured under a dissecting microscope at a magnification of 40 × with a calibrated ocular micrometre (precision ± 0.0125 mm). Host weight was measured using an A&D HR-250AZ analytical balance with a 0.1 mg resolution (A&D Company, Limited, Tokyo, Japan).

Statistical Analysis

We used generalised linear modelling (GLM) and mixed modelling (GLMM) techniques (Dobson, Reference Dobson1983; McCullagh and Nelder, Reference McCullagh and Nelder1983; Aitkin et al., Reference Aitkin, Anderson, Francis and Hinde1989; Hardy and Smith, Reference Hardy, Smith, Hardy and Wajnberg2023) which allow for the analysis of data with non-normal error distributions, such as binomial or Poisson, without prior transformation. Log-linear analyses, utilising the log-link function, were used to determine the relationship between host weight and head capsule size as well as host weight and brood size. Parasitoid sex ratios were analysed using logistic regression and adopted a logit-link function. Broods consisting only of males on emergence were excluded from analyses (one brood of 4 individuals and one brood of 6 individuals) as they were most likely produced by virgin mothers (following Hardy and Cook, Reference Hardy and Cook1995). Variance in brood sex ratio was summarised using Heterogeneity Factors and the variance ratio, R, and departures from binomial distributions were assessed using the Meelis test (test statistic U) (Krackow et al., Reference Krackow, Meelis, Hardy and Hardy2002). Development time of parasitoid offspring was analysed using the Cox's proportional hazards model. A generalised linear model and a generalised linear mixed model analysis were conducted to determine the influence of host weight on the size of male and female parasitoids, respectively. When categorial variables (factors) with more than two levels were significant, model simplification was carried out via aggregation of factor levels (Hardy and Smith, Reference Hardy, Smith, Hardy and Wajnberg2023). GLM and GLMM analyses were conducted using the statistical software GenStat (version 20, VSN International, Hemel Hempstead, UK).

Results

Head capsule width, host weight and host instar

Larval instars are identified by head capsule width (Yazdani et al., Reference Yazdani, Glatz and Keller2014). Head capsule width was associated with host weight (log-linear ANCOVA: F (2,157) = 418.64, P < 0.001; fig. 2) in a curvilinear relationship (quadratic term: F (1,157) = 132.77, P < 0.001; fig. 2) that explained 84% of the variance in head capsule width. Head capsule width reached a maximum of approx. 1.4 mm. As larvae with head capsules of this width ranged widely in weight, between approximately 0.01 and 0.035 mg (fig. 2), host weight was used as the measure of host size in subsequent analyses (table 1).

Figure 2. The relationship between head capsule size and weight of E. postvittana.

Table 1. Head capsule widths (mm) of Epiphyas postvittana reared at 22°C.

Brood size and host weight/instar

Goniozus jacintae brood size increased with host weight (log-linear ANCOVA: F (5,154) = 73.18, P < 0.001; fig. 3) in a curvilinear relationship (quadratic term: F (1,154) = 28.07, P < 0.001; fig. 3). Broods laid on larger instars (5 and 6) did not differ significantly in size (aggregation of factor levels: F (4,155) = 0.02, P = 0.890). The average brood sizes developing from hosts of different instars were: 3rd instar, 1.3 (SE ± 0.075); 4th instar, 2.8 (SE ± 0.18); 5th instar, 4.7 (SE ± 0.23); 6th instar, 5.4 (SE ± 0.28).

Figure 3. The relationship between brood size and host weight, classified by host instar. Data points for each instar are shown as symbols and the log-linear models fitted for each instar are defined as the following: 3rd instar: long dash and dot line, 4th instar: round dotted line, 5th instar: solid black line, 6th instar: dashed line.

Sex ratio

Goniozus jacintae brood sex ratios were female biased: the mean proportion of offspring that were male was 0.23 (SE ± 0.01). The maximum number of males recorded in any brood was 1 and sex ratio variances were significantly under-dispersed (HF = 0.09; Meelis test: R = 0.022, U = −8.77, P < 0.001; table 2). When the brood size was one adult offspring, the offspring was always a female. There were no all-female broods when multiple offspring developed (brood sizes of 2 or more). Among instars 4, 5 and 6, sex ratios decreased significantly as brood size increased (F (3,156) = 162.06, P < 0.001; fig. 4) but did not differ between host instars 4, 5 and 6 (aggregation of factor levels: F (3,156) = 0.85, P = 0.495). Broods produced on 3rd instar hosts consisted of either one or two offspring and their sex ratios were either zero (a single female) or 0.5 (one male and one female), resulting in a positive relationship between sex ratio and brood size over this narrow brood size range (fig. 4). Sex ratios of broods produced on 3rd instar hosts were significantly different to broods produced on all other instars (F (1,156) = 142.24, P < 0.001).

Table 2. Sexual composition of realised broods of Goniozus jacintae, and a test of sex ratio variance

Values lower than 1 for the variance ratio ‘R’ indicate sex ratio precision (less than binomial sex ratio variance). ‘U’ is the test statistic from the Meelis test.

Overall: R = 0.022, U = −8.77, P < 0.001.

Figure 4. The relationship between brood size and offspring sex ratio, classified by host instar. For instar 3 (dashed line), the fitted line is extrapolated to illustrate the bounded nature of the relationship: note that broods on 3rd instar hosts never exceeded 2 offspring. Sex ratios of broods developing on host instars 4, 5, and 6 did not differ significantly and were combined across instar classes (solid line). Lines were fitted by logistic ANCOVA. Data are shown as the mean values for each host instar group at each brood size ±1 standard error. Note that standard errors cannot be calculated for means of zero and also that they are asymmetrical around the non-zero means due to back-transformation from logit-scale estimates. Some estimates are slightly horizontally displaced to avoid visual overlap.

Developmental time of brood

There was no difference in parasitoid development time on different host instars (Cox PH model, χ2 = 2.78, d.f. = 3, P = 0.427). The mean development time from oviposition to adult eclosion was 19.64 days, SD = 0.88.

Size of emerging parasitoids

Female G. jacintae were larger than males; mean thorax lengths for male and female G. jacintae were (1.13, S.D. = 0.083) and (1.31, SD = 0.097), respectively. For adult males, there was no significant relationship between thorax length and host weight (F (4,71) = 0.33, P = 0.858; fig. 5a), nor was male size related to brood size (F (4,71) = 0.32, P = 0.865). Conversely, the body size of females was influenced by both host weight (F (1,88) = 4.44, P = 0.038, fig. 5b) and brood size (F (1,84) = 7.03, P = 0.01). There was also a significant interaction between these main effects (F (1,81) = 7.46, P = 0.008), with larger females developing from larger hosts, and smaller females developing from larger broods.

Figure 5. Parasitoid size and resource availability. Relationship between emerging parasitoid size and host weight, classified by host instar, for male (a) and female (b) offspring. Effect of increasing resource index on parasitoid size for male and female offspring (c).

The statistical interaction between host weight and brood size indicates that these are not separate influences on adult female size. We calculated a resource index (host weight/brood size) as a proxy for how much food resource, on average, was available to each individual in each brood. The effects of resource index, host larval instar and offspring sex on the size of each individual parasitoid were then explored using a generalised linear mixed model, with brood identity included as a random factor (Bolker et al., Reference Bolker, Brooks, Clark, Geange, Poulsen, Stevens and White2009). Thorax length was significantly influenced by both resource index (F (1,104) = 5.83, P = 0.017) and sex of the wasp (F (1,244) = 445.07, P < 0.001), such that the mean size of a parasitoid increased with increasing resource index, and males were smaller than females (fig. 5c), but thorax length was not influenced by host instar (F (3,84) = 1.20, P = 0.316).

Discussion

Goniozus jacintae females produce larger broods on larger hosts. This is consistent with prior reports on this species (Danthanarayana, Reference Danthanarayana1980; Hopper and Mills, Reference Hopper and Mills2015) and on other Goniozus species (Gordh et al., Reference Gordh, Woolley and Medved1983; Hardy et al., Reference Hardy, Griffiths and Godfray1992; Abdi et al., Reference Abdi, Lupi and Hardy2020) having greater reproductive success when attacking larger hosts. It is also consistent with the finding that G. jacintae have a stronger foraging response as hosts develop through instars 3 to 6, reflecting their growth in size (Aspin et al., Reference Aspin, Keller, Yazdani and Hardy2021).

The host represents the sole nutritional resource for immature parasitoids. Larger hosts are preferential for the development of parasitoid larvae, since they contain more resources than their smaller counterparts (Godfray, Reference Godfray1994; Mackauer et al., Reference Mackauer, Sequeira, Otto, Dettner, Bauer and Völkl1997; Farahani et al., Reference Farahani, Ashouri, Zibaee, Abroon and Alford2016; Jervis et al., Reference Jervis, Copland, Shameer, Harvey, Hardy and Wajnberg2023). Smaller hosts may result in greater mortality and/or the production of smaller parasitoid offspring, with fitness measures such as fecundity and longevity also being lower among smaller adults (Godfray, Reference Godfray1994; Quicke, Reference Quicke1997; Mayhew, Reference Mayhew2016; Zhang et al., Reference Zhang, Yu, Wu, Dai, Yang, Zhang and Hu2022). Hence, identifying the most suitable host size for a potential biological control agent could enhance the success of mass-rearing parasitoids in the laboratory.

Host size influenced the size of emerging G. jacintae offspring, with larger females emerging from larger hosts. Fitness of female parasitoids is typically positively influenced by their body size (Hardy et al., Reference Hardy, Griffiths and Godfray1992; Kazmer and Luck, Reference Kazmer and Luck1995; Ellers et al., Reference Ellers, van Alphen and Sevenster1998; Sagarra et al., Reference Sagarra, Vincent and Stewart2001; Samková et al., Reference Samková, Hadrava, Skuhrovec and Janšta2019). Larger females exhibit higher fertility and longevity compared to smaller ones (Visser, Reference Visser1994; Harvey et al., Reference Harvey, Harvey and Thompson2001; Samková et al., Reference Samková, Hadrava, Skuhrovec and Janšta2019; Wang et al., Reference Wang, Hogg, Biondi and Daane2021), as well as greater foraging efficiency when searching for hosts or food resources (Visser, Reference Visser1994; Kazmer and Luck, Reference Kazmer and Luck1995; Sarfraz et al., Reference Sarfraz, Dosdall and Keddie2012). In addition, larger females have higher success in the outcome of conflicts for host resources against smaller, competing females (Petersen and Hardy, Reference Petersen and Hardy1996; Hardy et al., Reference Hardy, Goubault, Batchelor, Hardy and Briffa2013). Thus, it can be inferred that when a female G. jacintae is accepting a host for oviposition, host size will play a key role in determining not only the size of her brood but the size of the female offspring within that brood.

The size of female offspring was also significantly influenced by brood size; smaller females emerged from larger broods, a trend also reported in the congener Goniozus nephantidis (Muesebeck) when clutches were artificially created on hosts of a fixed size (Hardy et al., Reference Hardy, Griffiths and Godfray1992). However, the opposite pattern was seen in broods that were laid naturally (Hardy et al., Reference Hardy, Griffiths and Godfray1992). In contrast to solitary parasitoids, where only one offspring per host can survive and develop, gregarious offspring may share a host – the sole nutritional resource – with their siblings and even the offspring of conspecific females (Godfray, Reference Godfray1994). Parasitoid growth and development varies depending on both the quality and quantity of the host resource available (Mackauer et al., Reference Mackauer, Sequeira, Otto, Dettner, Bauer and Völkl1997; Cusumano et al., Reference Cusumano, Peri and Colazza2016; Pekas et al., Reference Pekas, Tena, Harvey, Garcia-Marí and Frago2016). Hence, scramble competition may arise between parasitoid larva on the same host, with potential impacts on offspring mortality (Salt, Reference Salt1961; Brodeur and Boivin, Reference Brodeur and Boivin2004; Fox and Messina, Reference Fox and Messina2018), fitness (Hardy et al., Reference Hardy, Griffiths and Godfray1992; Bernstein et al., Reference Bernstein, Heizmann and Desouhant2002; Pereira et al., Reference Pereira, Guedes, Serrão, Zanuncio and Guedes2017), and size (Visser, Reference Visser1996; Bezemer and Mills, Reference Bezemer and Mills2003; Malabusini et al., Reference Malabusini, Hardy, Jucker, Savoldelli and Lupi2022).

Conversely, the size of male G. jacintae offspring was not related to either host size or brood size when these were treated as separate explanatory variables. However, it was influenced by these properties when combined into an index of per capita resource availability, as was female size. This suggests that, as above, there may be scramble competition between offspring within a brood for food as a resource, with direct consequences on offspring size. This competition may influence male offspring size to a lesser extent than females, since males require fewer resources than females due to their smaller size. As is common in bethylids, adult G. jacintae males emerge from their cocoons before females in preparation for mating (Hardy et al., Reference Hardy, Stokkebo, Bønløkke-Pedersen and Sejr2000; Amante et al., Reference Amante, Schöller, Suma and Russo2017; E. Aspin, pers. obs.). There may be little advantage for males in acquiring more resources to become larger, as development to a larger size may extend development time and result in the male missing the opportunity to emerge before females and secure mating opportunities (reviewed in Boulton et al., Reference Boulton, Collins and Shuker2015; Wang et al., Reference Wang, Xiang, Hou, Yang, Dai, Li and Zang2019; Teder et al., Reference Teder, Kaasik, Taits and Tammaru2021). Furthermore, as there is typically no more than 1 male in a G. jacintae brood, larger body size will not normally enhance competitive ability with male siblings.

The sex ratio of G. jacintae is female biased (mean proportion of males = 0.23), similar to that of most bethylids, most likely due to high levels of sibling mating and the resulting selection from local mate competition (Green et al., Reference Green, Gordh and Hawkins1982; Mayhew and Hardy, Reference Mayhew and Hardy1998; Tang et al., Reference Tang, Meng, Kapranas, Xu, Hardy and Li2014; Abdi et al., Reference Abdi, Lupi and Hardy2020). In addition, the sex ratio of G. jacintae has extremely low variance (significantly less than binomial); all broods with a size greater than one contained only one male. Notably, the variance ratio for G. jacintae (R = 0.022) is lower than estimates obtained for several congeners: G. nephantidis, R = 0.743 (Hardy and Cook, Reference Hardy and Cook1995); G. legneri, R = 0.572, (Khidr et al., Reference Khidr, Mayes and Hardy2013); G. nigrifemur, R = 0.37; G. emigratus, R = 0.42 (Hardy et al., Reference Hardy, Dijkstra, Gillis and Luft1998).

Sex allocation is a behaviour of interest for the application of biological control and the mass rearing of bethylids, as the number of female offspring recruited into each generation positively influences the degree to which target pest populations are likely to be suppressed (Ode and Hardy, Reference Ode, Hardy, Wajnberg, Bernstein and van Alphen2008). It is well known that parasitoids make adaptive decisions about sex allocation (reviewed in Charnov, Reference Charnov1982; Waage, Reference Waage, Waage and Greathead1986; West, Reference West2009; Whitehorn et al., Reference Whitehorn, Cook, Blackburn, Gill, Green and Shuker2015; Fellowes et al., Reference Fellowes, van Alphen, Shameer, Hardy, Wajnberg, Jervis, Hardy and Wajnberg2023), and that selection favours mothers that are able to produce precise sex ratios, as this does not produce any superfluous males and instead promotes the number of dispersing females (Green et al., Reference Green, Gordh and Hawkins1982; Hardy, Reference Hardy1992; West and Herre, Reference West and Herre1998; Khidr et al., Reference Khidr, Mayes and Hardy2013). However, there are multiple factors that influence selection for, and the attainment of, precise sex ratios, such as the order in which sexes are produced when clutches are laid and developmental mortality (Green et al., Reference Green, Gordh and Hawkins1982; Nagelkerke and Hardy, Reference Nagelkerke and Hardy1994; Kapranas et al., Reference Kapranas, Hardy, Morse and Luck2011). Mortality of parasitoid larva during the developmental stage increases the variance of observed sex ratios at eclosion, introducing the risk that no males survive to maturity, resulting in a brood of virgin females with very limited fitness under single foundress local mate competition (reviewed in Nagelkerke and Hardy, Reference Nagelkerke and Hardy1994; Hardy et al., Reference Hardy, Dijkstra, Gillis and Luft1998; see also Kapranas et al., Reference Kapranas, Hardy, Morse and Luck2011). The advantage of precise sex ratios can vary considerably depending on the different distributions of mortality within a brood (Nagelkerke and Hardy, Reference Nagelkerke and Hardy1994). Although this study did not provide a direct assessment of G. jacintae mean mortality or its distribution across broods and sexes, the extremely low brood sex ratio variance we recorded (see above) suggests that very few offspring die between oviposition and maturity and further that laying just one male per clutch will represent optimal sex allocation. In addition, parasitoids exhibit different sequence patterns when laying a clutch; some species lay female eggs first whereas others lay male egg(s) first (reviewed in Hardy, Reference Hardy1992). In the current study, all single egg broods produced females, and all 2-egg broods produced one male and one female, suggesting that this bethylid may fit in the group of parasitoids that lay male eggs last, although empirical assessment will be required to confirm this. Therefore, in order to obtain a fuller understanding of how the observed G. jacintae brood sex ratios arise, the sequence of sex allocation during the oviposition of a clutch and, especially, developmental mortality, should be assessed.

This study provides new information on the reproductive behaviour of a relatively unstudied potential biocontrol agent as well as complementing findings from existing work on bethylids (Griffiths and Godfray, Reference Griffiths and Godfray1988; Hardy et al., Reference Hardy, Griffiths and Godfray1992, Reference Hardy, Stokkebo, Bønløkke-Pedersen and Sejr2000; Luft, Reference Luft1993; Hardy and Mayhew, Reference Hardy and Mayhew1998; Polaszek et al., Reference Polaszek, Almandhari, Fusu, Al-Khatri, Al Naabi, Al Shidi, Russell and Hardy2019). Although some aspects require further investigation, we have demonstrated that (1) like other bethylids, G. jacintae has greater reproductive success on larger hosts and exhibits female biased sex ratios (2) these sex ratios have extremely low variance, seemingly lower than all previously studied bethylids, and finally, (3) female parasitoid offspring size is influenced by brood size and host weight whilst male size is not, but the body size of both sexes is positively determined by the per capita availability of resources during development. Such information is key for designing and implementing effective biological control programmes for LBAM, for instance, when considering which larval instar would produce the most (large and mated female) parasitoid offspring per host during mass-rearing procedures.

Acknowledgements

We thank Dr Hieu Trung Bui for assistance with insect culture maintenance, Georgia Black for the editing of fig. 1 and Dr Maryam Yazdani and Dr Jerome Buhl for co-supervision of E.A. The culture of LBAM was obtained from the South Australian Research and Development Institute (SARDI). We thank anonymous referees for their constructive comments. E.A. was funded by the University of Nottingham – University of Adelaide joint PhD programme.

Competing interests

None.

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Figure 0

Figure 1. Development of G. jacintae on light brown apple moth. Successive stages of development of a brood of G. jacintae on E. postvittana: (a) Host encounter: female G. jacintae on a paralysed 6th instar LBAM larva on a plantain leaf, (b) Day 1: eggs of G. jacintae laid on host's integument, (c) Day 6: larvae of G. jacintae, (d) Day 8: late instar larvae of G. jacintae and the head capsule of the consumed host, (e) Day 10: pupating larvae of G. jacintae inside their silken cocoons. Photo (A) has had the background changed to greyscale for clarity; the original leaf colour is green.

Figure 1

Figure 2. The relationship between head capsule size and weight of E. postvittana.

Figure 2

Table 1. Head capsule widths (mm) of Epiphyas postvittana reared at 22°C.

Figure 3

Figure 3. The relationship between brood size and host weight, classified by host instar. Data points for each instar are shown as symbols and the log-linear models fitted for each instar are defined as the following: 3rd instar: long dash and dot line, 4th instar: round dotted line, 5th instar: solid black line, 6th instar: dashed line.

Figure 4

Table 2. Sexual composition of realised broods of Goniozus jacintae, and a test of sex ratio variance

Figure 5

Figure 4. The relationship between brood size and offspring sex ratio, classified by host instar. For instar 3 (dashed line), the fitted line is extrapolated to illustrate the bounded nature of the relationship: note that broods on 3rd instar hosts never exceeded 2 offspring. Sex ratios of broods developing on host instars 4, 5, and 6 did not differ significantly and were combined across instar classes (solid line). Lines were fitted by logistic ANCOVA. Data are shown as the mean values for each host instar group at each brood size ±1 standard error. Note that standard errors cannot be calculated for means of zero and also that they are asymmetrical around the non-zero means due to back-transformation from logit-scale estimates. Some estimates are slightly horizontally displaced to avoid visual overlap.

Figure 6

Figure 5. Parasitoid size and resource availability. Relationship between emerging parasitoid size and host weight, classified by host instar, for male (a) and female (b) offspring. Effect of increasing resource index on parasitoid size for male and female offspring (c).