Introduction

Phylogeny and phylogenetic constraints are central to our understanding of ecology and evolutionary biology (McKitrick 1993). Phylogeny describes the evolutionary history and ecophysiological relationships among groups of organisms (Gould, 1977; Nei and Kumar 2000). In nature, closely related species generally exhibit traits that very strongly reflect their phylogeny, such as morphology, reproduction and development (Cheverud et al. 1985; Blomberg et al. 2003). Consequently, closely related species generally exhibit a suite of traits that overlap and which are functionally specialized (West-Eberhard, 1986). Phylogenetic constraints are defined as components or aspects of a lineage that prevent or impede any anticipated form of evolution in that lineage (McKitrick 1993). In other words, a constraint affects the potential of a species to evolve radical changes in its biology and/or ecology from its ancestors and close relatives and may hinder a species attempting to exploit novel resources or colonize novel habitats. For instance, in many families of the Hymenoptera (Aculeata) the ovipositor, which is a specialized egg-laying apparatus, has evolved into a stinger that instead of eggs injects venom into potential prey or as a means of defense against attackers (Zhao et al. 2015). A stinger is of much more utility than an ovipositor for a social wasp, because the workers are sterile and do not reproduce. In vertebrates, woodpeckers possess sharp, pointed bills for chiseling wood for nest construction and foraging, and long, barbed tongues made up of cartilage and bone for catching insects embedded in trees (Bock 1999; Zhou et al. 2009). These adaptations are specifically tailored for nesting in forest habitats and would clearly be of little utility in grasslands.

Phylogeny is not the only factor constraining organisms in nature. All species are also constrained in their ability to allocate limited metabolic resources for vital functions such as reproduction, foraging and survival (Roff 2002). Under strong selection for the acquisition, utilization and allocation of these resources to different and potentially competing fitness functions, the optimal phenotype of most organisms is determined by trade-offs in life-history traits such as between reproduction and longevity (van Noordwijk and de Jong 1986). A trade-off occurs when two fitness-related traits are limited by the same resource, such as time and/or energy, that can only be utilized once (Stearns 1989). For example, an organism that invests a disproportionate amount of metabolic resources towards early reproduction will invariably experience a reduction in its life expectancy and vice-versa. Trade-offs strongly reflect environmental limitations on food, prey, mates and other factors. Thus, a specialized herbivore that feeds on a rare or small species of plant may be limited in its reproductive capacity by a difficulty in finding many food plants and therefore invests more metabolic resources in maintenance than in egg production, allowing it to extend its lifespan in searching for suitable plants on which to oviposit.

Parasitic wasps, or ‘parasitoids’, are model organisms for addressing a range of questions in evolutionary biology. Parasitoids lay their eggs inside or on the bodies of other arthropods (‘hosts’) and their larvae grow and develop by feeding on host tissues, whereas the adult stage is free-living (Godfray 1994). The development of parasitoid offspring is dependent on resources contained in a single host: because hosts of many parasitoids are only marginally bigger than the parasitoid itself, they are under intense selection to optimize the exploitation of limited resources to vital metabolic functions (Harvey 2005; Jervis et al. 2008). By contrast, selection for resource allocation to different metabolic functions in arthropod predators is generally much more relaxed, because they are not restricted to a single prey item. For this reason, parasitoids exhibit a suite of traits that are adapted for exploiting a narrow range of host species in nature, whereas most predators will attack many prey species in order to reach maturity.

Parasitoids that are closely related and/or exhibit similar host ranges in nature often exhibit a convergence in traits such as host utilization and reproduction (Jervis et al. 2008). This is because of both phylogenetic conservatism and overlapping selection pressures on trade-offs such as between maintenance and egg production. One of the best examples on how host ecology drives similarities and differences in parasitoid traits is a study by Price (1972), who compared parasitoids attacking different stages of the Jack pine sawfly, Neodiprion swaineii. He found that parasitoids attacking early host stages, such as young larvae, exhibited traits such as the production of large numbers of small eggs that could be oviposited rapidly and adults that had short lifespans. By contrast, parasitoids attacking older hosts, such as pupae, produced small numbers of large eggs that took a considerable time to lay and adults that had extended lifespans. He attributed these differences to variation in mortality risks experienced by hosts along their ontogenetic continuum with high fecundity being an adaptive response in parasitoids attacking comparatively abundant young hosts with high mortality risks, and lower fecundity for parasitoids attacking scarce older hosts with a lower mortality risks (Price 1972; see also Pexton and Mayhew 2002). Differences in reproductive investment and longevity also appear to reflect host abundance (Price 1972).

Sex determination in parasitoids is haplodiploid, where unfertilized (haploid) eggs develop into males and fertilized (diploid) eggs develop into females. This gives females the choice of deciding what sex to lay during oviposition. In parasitoids, numerous studies have shown that mothers prefer to oviposit daughters on larger hosts of perceived higher quality, and sons on smaller hosts (Charnov et al. 1981; Charnov 1982; King 1987, 1989). This is because eggs are typically more costly to produce than sperm, with large females gaining much higher fitness returns than large males (Jervis et al. 2008). Importantly, offspring sex ratios in parasitoids in the field are dependent on more than host quality, such as population-related factors. For example, when plenty of resources are available, mating patterns in parasitoid populations generally select for equal parental investment into both sexes. However, when vital resources, such as mates or hosts, are scarce or limiting, increased competition can generate conditions that bias sex ratios in the direction of either sex (King 1987; Visser et al., 2016).

In this study we examined development and reproductive strategies in three congeneric species of parasitoids. Gelis agilis Fabricius, G. proximus Forster and G. hortensis Christ (Hymenoptera: Ichmeumonidae) are three species of facultative hyperparasitoids that are virtually morphologically and behaviorally indistinguishable, apart from differences in cuticle color. The three species exhibit a suite of overlapping traits that are phylogenetically conserved. These include (1) the production of large, yolky anhydropic eggs that are only produced in small numbers daily (Jervis & Kidd 1986). (2) Obligate host-feeding behavior among adult females to secure proteins for oogenesis (Jervis and Kidd, 1986; Heimpel and Collier 1996). (3) Complete synovigeny where adult females emerge with no mature eggs (Jervis et al. 2001). (4) Ectoparasitic idiobisis, whereby eggs are laid by female parasitoids on the body surface of paralyzed hosts (Mayhew and Blackburn, 1999). (5) Wingless adults, which contrasts with most parasitoid taxa that are fully winged (Schwarz and Shaw 1999; Harvey et al. 2018). Despite these overlapping traits, the three species successfully co-occur in grassy meadow and forest edges across much of Eurasia, including the Netherlands. Little is known about the ecology or host range of most gelines, although previous work has shown that the three species studied here attack cocoons of primary parasitoids (Cotesia spp.) in the field (Lei and Hanski 1997; van Nouhuys and Hanski 2000; Harvey et al. 2014; Heinen and Harvey 2019). Thus far 280 species of Gelis have been described (Catalogue of Life, 2019), although there are certainly many more as the genus is not well-studied.

We compared fecundity schedules, lifetime reproductive success and offspring sex ratios in the three Gelis species when reared on cocoons of the gregarious parasitoid, Cotesia glomerata L. (Hyemoptera: Braconidae). Previous work with different Gelis species, including the wingless G. acororum and the fully winged G. areator, reported significant interspecific differences in fecundity schedules over two day periods and lifetime reproductive success, especially between the winged and wingless gelines. Furthermore, sex ratios in both species were highly male-biased throughout reproductive life (Visser et al. 2014, 2016). The authors speculated that the male bias was attributable to anticipation of limited hosts in nature by both parasitoids, with a high production of males reducing competition for these scarce hosts among the low number of remaining females (Visser et al. 2014). Given that the three species studied here are all wingless, we hypothesize that reproduction and longevity among them will be more similar than among the gelines in the Visser et al. (2014, 2016) studies. We also discuss how these several closely-related species exhibiting overlapping traits are able to co-exist locally at small scale in nature.

Methods and Materials

Insects

All insects were reared at a temperature of 22 + 2 °C under a 16:8 h L:D regime with a relative humidity of 50%. Cultures of the parasitoid C. glomerata and its host, the large cabbage white butterfly P. brassicae, were obtained from insects reared at Wageningen University (WUR), the Netherlands, that were originally collected from agricultural fields in the vicinity of the University. All C. glomerata cocoons used in this experiment were generated from P. brassicae caterpillars reared on Brassica oleracea var. Cyrus (Brussels sprouts) at the Netherlands Institute of Ecology (NIOO, Wageningen, The Netherlands).

In the field, C. glomerata females generally oviposit between 10 and 40 eggs into first (L1) to third (L3) instars of P. brassicae. Fully grown parasitoid larvae emerge from the host caterpillar late during its final instar, spinning cocoons adjacent to the host, which perishes within a few days. Once weekly, several hundred L2 P. brassicae larvae were presented to C. glomerata in rearing cages (30 × 30 × 30 cm) for parasitism. Parasitized caterpillars were then transferred to steel and plexiglass cages (30 × 30 × 60 cm) containing cabbage plants. Fresh parasitoid cocoons were collected from these cages.

Adult G. agilis, G. proximus and G. hortensis were collected from cocoons of C. glomerata that had been pinned onto the lower shoots and stems of black mustard (Brassica nigra) or garlic mustard (Alliaria petiolata) at several locations in the provinces of Gerlderland and South Holland, the Netherlands. Species identification was made by Dr. Martin Schwarz, one of the world’s leading experts on the Cryptinae, who is based at the Biologiezentrum in Linz, Austria. A recent phylogenetic reconstruction of the three geline species is shown in Harvey et al. (2018).

Each species was therefore obtained from multiple populations that were reared collectively. In culture, hyperparasitoids were maintained exclusively on fresh cocoons of C. glomerata. After adult emergence, each species was separately kept in closed, meshed rearing cages (30 × 30 × 30 cm) with honey and water and stored at 10 + 1 °C in incubators.

Fecundity Schedules, Lifetime Reproductive Success, Longevity and Sex Allocation

Newly emerged females of G. proximus and G. hortensis were sexed, fed with honey and allowed to mate with males in Petri dishes (8 cm dia.). After mating, which was ascertained visually, females were transferred to new Petri dishes (12 cm dia.) containing 10 cocoons of <12 h-old C. glomerata with drops of honey smeared on the underside of the lid and water absorbed into a small ball of cotton wool. Every 48 h cocoons were removed and placed in marked vials with the species, female number, dates, and days of exposure marked on the vials. Fresh cocoons, honey and water were presented to female wasps in new Petri dishes. This procedure was repeated throughout the lives of female wasps. Vials were checked daily for adult eclosion and newly emerged wasps were sexed and counted. These data make it possible to determine fecundity schedules of the three wasps, total fecundity, offspring sex ratios over time and longevity. The experiment was repeated with 10 females of each species. In order to measure longevity for female wasps without host access (=control), the procedure was repeated with 10 females of each species in Petri dishes without host access. To measure male longevity, the procedure was repeated in Petri dishes with 10 males each of the sexual species G. proximus and G. hortensis.

Statistics

All statistics were performed using IBM SPSS Statistics (IBM Corp. Released 2017. IBM SPSS Statistics for Windows, Version 25.0. Armonk, NY: IBM Corp). To compare total number of offspring and longevity of females provided with hosts, we used general linear model ANOVAs with species as main factor. Offspring numbers were log-transformed to meet assumptions of equal variance. If the effect of species was significant, means were compared using Tukey multiple comparison tests (Fig. 1).

Fig. 1
figure 1

Adult females of Gelis agilis (a), Gelis proximus (b) and Gelis hortensis (c) parasitizing cocoons of Cotesia glomerata

Results

Fecundity Schedules and Lifetime Reproductive Success in the Three Geline Wasps

Total offspring numbers differed among the three species (F2,26 = 15.5, p < 0.001), with G. proximus producing most offspring (126.7 ± 14.5, mean ± 1SE), followed by G. hortensis (87.5 ± 9.2) and G. agilis producing the fewest total offspring (41.9 ± 4.5) (Fig. 2). Total reproduction was also reflected in the fecundity schedules of the three species. Gelis agilis had a pre-oviposition period after eclosion of several days and then typically produced a maximum of ~ 2 progeny every two days until this declined around day 50. By contrast, G. hortensis had the shortest pre-ovipositon period of the three species and produced a maximum of ~ 3–4 progeny every two days which dropped off rapidly after around 35 days. Lastly, the pre-ovipositon period of G. proximus was intermediate in length and this species also produced ~ 3–4 progeny every two days, but the decline in progeny production was much more gradual than in G. hortensis, and also dropped off sharply only after around 90 days (Fig. 3).

Fig. 2
figure 2

Mean total progeny (± SE) produced by females of Gelis agilis, Gelis proximus, and Gelis hortensis. Data from 10 adult females for G. proximus and G. hortensis and 9 adult females for G. agilis. Bars with different letters are statistically different (Tukey tests, p < 0.05)

Fig. 3
figure 3

Fecundity schedules (± SE) of (a) Gelis agilis (b) Gelis hortensis (c) Gelis proximus. Data from 10 adult females for G. proximus and G. hortensis and 9 adult females for G. agilis

Longevity

Although G. agilils tended to have a shorter lifespan than the other two species, the longevity of females provided with hosts did not statistically differ among them (F2,26 = 2.26, p = 0.12, Fig. 4). Each of the three species lived on average between 80 and 120 days. At the upper end of the longevity distribution, some G. proximus females lived for almost 6 months.

Fig. 4
figure 4

Mean longevity (± SE) of females of Gelis agilis, Gelis proximus, and Gelis hortensis when provided with hosts. Data from 10 adult females for G. proximus and G. hortensis and 9 adult females for G. agilis

Sex ratios

Overall sex ratios did not differ between the two sexually reproducing species, G. proximus and G. hortensis (F1, 18 = 1.30, p = 0.270), but allocation of male and female progeny did differ throughout the life of each species (Likelihood Ratio Test = 19.33, p < 0.0001; Fig. 5). In G. proximus there was a much more dramatic shift from the production of female to male offspring later in reproductive life than in G. hortensis.

Fig. 5
figure 5

Sex allocation patterns (proportion of males, mean ± SE) during life of Gelis hortensis (blue line) and Gelis proximus (orange line). Sex ratios were determined for progeny produced by 10 females of each species in consecutive 6-day intervals

Discussion

Females of the three Gelis species are morphologically similar, aside from differences in the color of their cuticle (Fig. 1). Despite these similarities, we found that there were interspecific differences in fecundity schedules and lifetime reproductive success among the three species. Total progeny production was significantly lower in G. agilis than in the other two Gelis species; female G. proximus produced three times as many progeny as G. agilis females, with G. hortensis producing intermediate numbers of progeny. Moreover, despite the fact that the three species only produce eggs in small numbers, a peak in mean number of progeny produced over two days was higher in G. proximus and G. hortensis (~ 3–4) than in G. agilis (~ 1–2). However, progeny production declined in G. hortensis somewhat more rapidly than in G. proximus. Longevity among females provided with hosts did not differ significantly among the three gelines.

Our study shows that there are both interspecific similarities and differences among the three gelines in terms of trait expression. Traits like behavior, general appearance (morphology, winglessness) and physiology (ectoparasitism, host-feeding and the production of small numbers of large, yolky eggs) were present in all three species and are typical among most species in the Gelinae (Schwarz and Shaw 1999). However, differences in longevity and reproduction, although subtle when compared with many more distantly related parasitoids (e.g. koinobionts) were nevertheless observed. This suggests that selection on these traits differs among the three species. It is difficult to understand what these divergent selection pressures might be, although trade-offs may be involved. For instance, Gelis species may differ in their competitive (intrinsic and extrinsic) abilities, with the better competitor producing less offspring (Harvey et al. 2013). On the other hand, differences in reproduction may simply reflect marginal differences in host range or else some aspect of niche differentiation. Gelis spp. are generalists and can probably attack a range of hosts in nature (in addition to the cocoons of other parasitoids). However, the lack of wings in most gelines probably limits the number of suitable hosts they are able to find and parasitize in the field. In spite of this, in the.

Netherlands, the three species studied here co-occur in the same habitats with at least two other morphologically similar species, G. acororum and G. spurius, and perhaps more (Harvey et al. 2014).

Offspring sex ratios in G. proximus and G. hortensis were highly variable among individual females, at least during the first several weeks of reproductive life. In most G. hortensis females, offspring sex ratios favored the production of sons over this time (>70%), whereas in G. proximus ca. 60% of progeny were daughters. However, in both species there was an abrupt shift from the production of mixed sex to all-male offspring after about 40 days, leading to the production of all-male progeny later in life. There are two possible explanations. The first, and less likely, is that sperm is unlimited, but that females produce more daughters early to gain a competitive edge for access to potentially limiting hosts in the field. This argument assumes, however, that adult cohorts of different Gelis species strongly overlap temporally and that host availability decreases rapidly over time. Consequently, the first daughters that emerge have the greatest chance of exploiting hosts before they are depleted. This scenario is highly unlikely because gelines are long-lived and there are probably no discrete generations in nature but a constant turnover of wasps as long as hosts are available. In another laboratory experiment, Visser et al. (2014) reported male-biased sex ratios throughout life in two other Gelis species, the wingless G. acororum and the winged G. areator. The authors attributed the male bias in these species to a perceived scarcity of hosts in the field, meaning that just enough daughters are produced to diffuse competition among the parasitoids.

The second and more likely explanation is that G. proximus and G. hortensis are sperm-limited and thus deplete their sperm stores abruptly. For many years it was assumed that eggs are much more limiting than sperm in parasitoids, and this notion was often used as the basis of optimization models for sex allocation strategies in these insects (Charnov 1982; King 1987, 1989; Visser 1994; Mackauer, 1996). However, it has more recently been revealed that many female parasitoids mate only once in their lifetimes and store low numbers of sperm (Henter 2004; Boivin et al. 2005; Boivin 2013). If males inseminate females with just enough sperm to produce daughters early in reproductive life, this may imply that Gelis spp. will only ever encounter small numbers of hosts and that the sudden switch to all-male progeny is an artefact: in nature, no females therefore survive long enough to encounter enough hosts to deplete their sperm. What is remarkable in G. proximus and G. hortensis is that the switch from mixed broods to all-male progeny occurred when females had only laid around 50 or so eggs – much lower than in other parasitoids so far studied. However, given that suitable hosts are probably scarce it is unlikely that females ever exhaust their supply of sperm in nature. Our experimental females thus experienced a ‘jackpot’ of hosts that far exceeds what females would normally ever encounter. Males thus inseminate just enough sperm to ensure that females do not become sperm-depleted.

Given that at least several Gelis species are found in the same microhabitats, an interesting question is how multiple species that presumably compete for hosts at small, local scales can co-exist. One important assumption in ecology is that co-existing species differ in their niches (Adler et al., 2007) and that intense competition among similar species for the same resources, such as hosts by parasitoids, will lead to competitive exclusion of others by a dominant species (Harvey et al. 2013; Pekas et al. 2016). Co-existence theory has been posited as a framework to better understand how species with strongly overlapping traits can co-exist in ecologically similar environments (Leibold and McPeek, 2006). This theory may partly explain niche differentiation among species with overlapping traits. One important factor that may enable multiple Gelis species to co-exist locally is that they are extreme generalists, parasitizing whatever suitable hosts are available. Although the biology of most Gelis species is unknown, other species in this genus parasitize a wide range of hosts including spider egg sacs and moth pupae in addition to parasitoid cocoons (Bezant 1956; Schwarz & Boriani 1994; Cobb and Cobb 2004). They may also differ in other, more subtle ways that diffuse competition. For instance, species may co-exist by differing their usage of limiting resources, their ability to colonize habitats and their temporal patterns of habitat occupancy (Leibold and McPeek 2006; Adler et al. 2007). Furthermore, interspecific differences in egg production, sex allocation and fecundity may reflect subtle differences in host preference or host-finding ability that will be the focus of future research in the field.