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An Endoparasitoid Avoids Hyperparasitism by Manipulating Immobile Host Herbivore to Modify Host Plant Morphology

  • Tomohisa Fujii,

    Affiliations Biosystematics Laboratory, Graduate School of Social and Cultural Studies, Kyushu University, Fukuoka, Japan, Japan Society for the Promotion of Science, Chiyoda-ku, Tokyo, Japan

  • Kazunori Matsuo,

    Affiliations Japan Society for the Promotion of Science, Chiyoda-ku, Tokyo, Japan, Entomological Laboratory, Graduate School of Bioresource and Bioenvironmental Sciences, Kyushu University, Fukuoka, Japan

  • Yoshihisa Abe,

    Affiliation Biosystematics Laboratory, Graduate School of Social and Cultural Studies, Kyushu University, Fukuoka, Japan

  • Junichi Yukawa,

    Affiliation Entomological Laboratory, Faculty of Agriculture, Kyushu University, Fukuoka, Japan

  • Makoto Tokuda

    tokudam@cc.saga-u.ac.jp

    Affiliation Laboratory of System Ecology, Faculty of Agriculture, Saga University, Saga, Japan

Abstract

Many parasitic organisms have an ability to manipulate their hosts to increase their own fitness. In parasitoids, behavioral changes of mobile hosts to avoid or protect against predation and hyperparasitism have been intensively studied, but host manipulation by parasitoids associated with endophytic or immobile hosts has seldom been investigated. We examined the interactions between a gall inducer Masakimyia pustulae (Diptera: Cecidomyiidae) and its parasitoids. This gall midge induces dimorphic leaf galls, thick and thin types, on Euonymus japonicus (Celastraceae). Platygaster sp. was the most common primary parasitoid of M. pustulae. In galls attacked by Platygaster sp., whole gall thickness as well as thicknesses of upper and lower gall wall was significantly larger than unparasitized galls, regardless of the gall types, in many localities. In addition, localities and tree individuals significantly affected the thickness of gall. Galls attacked by Platygaster sp. were seldom hyperparasitized in the two gall types. These results strongly suggest that Platygaster sp. manipulates the host plant's development to avoid hyperparasitism by thickening galls.

Introduction

Many parasites and parasitoids manipulate their hosts to improve their own fitness and performance. Such manipulation includes biochemical, physiological, and behavioral changes of their hosts [1], [2], [3]. Parasites often facilitate their own transmission by altering host behavior [4], [5], [6]. Some insect parasitoids are known to change their host's behavior to enhance their own fitness by reducing the risk of predation or hyperparasitism [7], [8], [9]. For example, aphids parasitized by Aphidius nigripes Ashmead (Hymenoptera: Braconidae) leave the colony and hide in concealed microhabitats to avoid the attack of hyperparasitoids [10], [11]. Larvae of Pieris brassicae (L.) (Lepidoptera: Pieridae) parasitized by a primary parasitoid, Cotesia glomerata (L.) (Hymenoptera: Braconidae), change their behavior after C. glomerata larvae quit the host larvae. The larvae protect cocoons of C. glomerata against hyperparasitoids by spinning silk webs over the cocoons [12], [13]. Larvae of Thyrinteina leucocerae Rindge (Lepidoptera: Geometridae) parasitized by a braconid wasp Glyptapanteles sp. defend cocoons of the parasitoid against approaching predators with violent head swinging [14], [15].

Up to the present, studies of host manipulation by insect parasitoids have focused mainly on those associated with mobile hosts but seldom on those associated with endophytic, immobile, or sessile hosts. Primary parasitoids of immobile hosts, such as gall inducers, cannot move with the hosts to less dangerous sites to avoid predation and hyperparasitism. However, the avoidance of hyperparasitism is very important because the rate of hyperparasitism often becomes very high [e.g. 16, 17, 18]. For gall inducers, thicker gall walls are advantageous because they prevent oviposition by late parasitoids (see reference [16] for the definition of ‘early and late parasitoid’; see the Materials and Methods) after maturation of galls [e.g. 20, 21, 22, 23]. A previous study proposed that primary parasitoids might manipulate their hosts to modify gall traits, e.g. thickness of gall wall and hardness of gall tissue, to avoid hyperparasitism [23].

In this paper, we focus on the euonymus gall midge Masakimyia pustulae Yukawa & Sunose, 1976 (Diptera: Cecidomyiidae) and its primary parasitoid, a platygastrid species (Hymenoptera). By examining the relationship between gall thickness and percentage parasitism by the platygastrid and late parasitoids, we tested the hypothesis that the primary parasitoid manipulates host larvae to induce increased gall thickness to avoid hyperparasitism.

Materials and Methods

Biology of Masakimyia pustulae

Masakimyia pustulae is univoltine and is present in Japan [24] and Korea [25]. The gall midge induces dimorphic leaf galls, both thick and thin types (Fig. 1), on Euonymus japonicus Thunb. and E. fortunei Hand-Mazz (Celastraceae) [26]. The thick type of gall is slightly swollen on the upper surface and subovate on the lower surface of the host leaf. The thin type of gall is a flat and very weak swelling on both surfaces of the host leaf. The thickness of gall ranges from 1.4 to 2.8 mm in the thick type and from 0.7 to 1.3 mm in the thin type, respectively [24]. Galls are single-chambered and each contains one gall midge larva [26]. Females of M. pustulae usually lay their eggs on the lower surface of fresh host leaves in spring and rarely on 2 or 3 year-old leaves. Immediately after hatching, first instars go into the host leaf tissue and molt into second instars before summer. They become third ( = final) instars in autumn, and pupation takes place in the following spring.

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Figure 1. Blister-like leaf galls induced by Masakimyia pustulae on Euonymus japonicus.

A: thin type gall, B: thick type gall, C: schematic illustration showing the method of measuring gall-wall thickness.

https://doi.org/10.1371/journal.pone.0102508.g001

The galls grow rapidly when the larvae are in the third instars and mature in size in the following spring [24], [27]. The adults emerge in southern Kyushu in early March and in northern Kyushu in late March. As in other gall-inducing cecidomyiids, the adult life of M. pustulae is very short, approximately 12 hours in males and mated females, and about 24 hours in unmated females [27].

The gall midge population inducing thick type galls and that inducing thin type galls are distributed almost parapatrically in Japan [27]. The former is found in the northeast areas of Honshu (Tohoku District), southern parts of Shikoku, and southern parts of Kyushu (Fig. 2). The latter is widely found in other areas of Honshu, Shikoku and Kyushu (Fig. 2). Crossing experiments between the two gall midge populations suggested that quantitative genes of the gall midge are probably responsible for the dimorphism in gall shape [27]. Populations of intermediate type galls are often found in the distributional boundaries between both gall types [27].

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Figure 2. Distribution of thick and thin types of gall induced by Masakimyia pustulae on Euonymus japonicus Thunb. in Kyushu, Japan (modified from Sunose, 1985a).

Numerals indicate localities where galls were collected (see also Table 1).

https://doi.org/10.1371/journal.pone.0102508.g002

Parasitoids associated with Masakimyia pustulae

Parasitoid wasps of gall inducers (e.g. gall wasps and gall midges) are divided into two groups according to their parasitic strategies [16], [28], [29], [30]. Early parasitoids are usually host-specific, univoltine, and koinobiont endoparasitoids, which allow hosts to continue to grow, ovipositing into eggs or first instars of hosts before the development of the gall to its full size. Late parasitoids are generally polyphagous, multivoltine, and idiobiont ectoparasitoids (rarely endoparasitoids), which kill or permanently paralyze their host, attacking older hosts, such as final instars or pupae, after the galls mature by inserting long ovipositors through the gall wall. When both early and late parasitoids attack the same host larva, only the latter idiobiont species can survive [19], [27], [31]. Thus late parasitoids are regarded as facultative hyperparasitoids attacking both the unparasitized gall midge larvae and those already parasitized by early parasitoids [19], [27].

Eight species of solitary parasitoids consisting of five eulophids, one pteromalid, one braconid and one platygastrid are parasitic on M. pustulae [19], [27]. The platygastrid is a koinobiont early parasitoid ovipositing into eggs of M. pustulae. The larva of this parasitoid starts to grow rapidly after M. pustulae larvae have developed to the final instar, pupates inside the host body in late winter, and the adult emerges in early spring [19]. At the time of pupation, the host integument enclosing the platygastrid becomes hard and turns brown. The other seven species are idiobiont late parasitoids attacking the final instars or pupae of M. pustulae from autumn to the following spring [19]. They are Chrysocharis sunosei Kamijo, Chrysonotomyia sp., Pnigalio sp., Tetrastichus sp. A, Tetrastichus sp. B (Eulophidae), Spaniopus japonicas Kamijio (Pteromalidae) and Bracon tamabae Maetô (Braconidae). Among the late parasitoids, three species of eulophids, Chrysonotomyia sp., Tetrastichus sp. A and sp. B, and the braconid are ectoparasitoids, while the pteromalid and the other two eulophids are endoparasitoids.

Collection, measurements and dissection of galls

Host leaves with M. pustulae galls were collected from nine localities in Kyushu in February and March 2009, 2010 and 2012 (Table 1). In 2009, 10 to 50 galled leaves (depending on the size of tree) were randomly collected from a single host tree in each locality. In 2010, one or two trees were selected in each locality to examine differences in gall thickness between trees. In Munakata, only one host tree was available for sampling. Then, five current shoots with galled leaves were randomly collected from each tree. After measuring gall thickness with digital slide calipers (Fig. 1), galls were dissected under a stereoscopic microscope to examine inhabitants to record their developmental stage. In 2012, two and nine shoots with galled leaves were collected from a single host tree in Munakata and Tenjin, respectively, to measure upper and lower gall wall thicknesses under a stereoscopic microscope with an ocular micrometer to confirm whether or not the increase in gall thickness is related to the thickness of both upper and lower gall walls.

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Table 1. Collecting sites of galls induced by Masakimyia pustulae in Kyushu, Japan.

https://doi.org/10.1371/journal.pone.0102508.t001

Parasitoids and percentage parasitism

Parasitoids were identified using Sunose [19]. Percentage parasitism was calculated for each parasitoid species in each locality. In particular, a parasitoid pupated inside the skin of full-grown host larva was identified as one of the platygastrid species. The gall thickness was compared between galls containing host larvae attacked by the platygastrid (parasitized galls, hereafter) and those with unparasitized larvae (unparasitized galls, hereafter). The thicknesses of upper and lower gall walls were also compared between galls parasitized by the platygastrid and unparasitized galls. The percentage parasitism by late parasitoids was compared between galls with or without the platygastrid. In this case, platygastrids attacked by late parasitoids were recognized by the presence of late parasitoid larvae or pupae in the galls, together with brownish fragments of cecidomyiid larval integument that had been sclerotized by the platygastrid. To examine whether late parasitoids preferably attack inhabitants in thinner galls, the thickness of gall was compared between galls attacked by late parasitoids and those that were not.

Statistical analyses

Statistical analyses were performed using R 2.12.1 [32]. Differences in the thickness between galls of unparasitized hosts and those parasitized by the platygastrid or late parasitoids were analyzed using two-way ANOVA for the 2009 data. The mean values were compared between inhabitants in each tree by Student's t-test using p values adjusted by Holm’s method [33] to reduce the family wide error rate. Nested ANOVA was used for comparing the thickness between galls of unparasitized hosts and those parasitized by the platygastrid, in which tree individuals are nested within localities and inhabitants (unparasitized hosts or those parasitized by parasitoids) are nested within tree individuals within localities. When significant effects of individual trees were detected, the mean values were compared between inhabitants in each census tree by Student's t-test using p values adjusted by the Holm’s method. In case the sample size was less than three in any category, they were excluded from the analysis. Differences in the thickness of upper and lower gall walls between parasitized and unparasitized galls were compared using one-way ANOVA. Percentage parasitism by late parasitoids between galls with and without the platygastrid was compared with chi-square test or paired Fisher’s exact test when the minimum expected value was less than 5.0, using p values adjusted by the Holm’s method. Nested ANOVA was used for comparing the thickness between galls of unparasitized hosts and those parasitized by the late parasitoids. When significant effects of individual trees were detected, the comparison of mean values between inhabitants in each tree by Student's t-test using p values adjusted by the Holm’s method.

Results

Percentage parasitism by early and late parasitoids

We obtained three of eight known parasitoids of M. pustulae through the current surveys in Kyushu. They were an early parasitoid, platygastrid and two species of late parasitoids, Pnigalio sp. and Chrysonotomyia sp. One of us, KM identified the platygastrid as Platygaster sp. based on a literature [34].

Platygaster sp. was found in most localities surveyed and its percentage parasitism was higher in many areas than that by Pnigalio sp. and Chrysonotomyia sp., except in some localities (Tables 2 & 3). Either Pnigalio sp. or Chrysonotomyia sp. exhibited relatively high percentage parasitism in Shikanoshima in 2009, on Tree 1 and 3 in Shikanoshima in 2010. In particular, percentage parasitism by the late parasitoids exceeded 50% on Tree 1 in Nishikata and on Trees 1 and 2 in Satsumataki in 2010.

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Table 2. Percentage parasitism by early and late parasitoids in galls induced by Masakimyia pustulae in 2009.

https://doi.org/10.1371/journal.pone.0102508.t002

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Table 3. Percentage parasitism by early and late parasitoids in galls induced by Masakimyia pustulae in 2010.

https://doi.org/10.1371/journal.pone.0102508.t003

Comparison in thickness between galls unparasitized and parasitized by Platygaster sp

Regardless of the gall type, the thicknesses of galls parasitized by Platygaster sp. were significantly higher (0.1–0.5 mm) than those unparasitized in three out of the nine trees surveyed in 2009 (Fig. 3). In 2010, the thickness was significantly different between unparasitized and parasitized galls on four out of the 18 trees surveyed in five out of nine localities, but not significantly different on the remaining trees and localities (Fig. 4; see Table 4 for the result of nested ANOVA). Based on the survey in 2012, both upper and lower gall walls were significantly thicker in galls parasitized by Platygaster sp. than those unparasitized (Fig. 5).

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Figure 3. The thickness of galls containing unparasitized Masakimyia pustulae and those parasitized by Platygaster sp. in 2009.

1: Munakata, 2: Shikanoshima, 3: Itoshima, 4: Nishikata, 5: Satsumataki, 6: Meiwa, 7: Sanwa, 8: Tenjin, 9: Takasu. The number of galls examined was shown in each column. Asterisk indicates significant differences at *5% level or **1% level (two-way ANOVA followed by Student’s t-test in each tree with adjusted p values by Holm’s method).

https://doi.org/10.1371/journal.pone.0102508.g003

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Figure 4. The thickness of galls containing unparasitized Masakimyia pustulae and those parasitized by Platygaster sp. in 2010.

The number of galls examined was shown in each column. Sample size is shown in parentheses. Abbreviations are as follows, T1: Tree 1, T2: Tree 2, and T3: Tree 3. Asterisk indicates significant differences at 1% level (nested ANOVA followed by Student’s t-test in each tree with adjustment of p values by Holm’s method; asterisk indicates significant difference).

https://doi.org/10.1371/journal.pone.0102508.g004

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Figure 5. The thickness of upper and lower gall walls of unparasitized Masakimyia pustulae galls and those parasitized by Platygaster sp. in 2012.

The number of galls examined was shown in each column. Asterisk indicates significant differences, *P<0.05, **P<0.01, ***P<0.001 (one-way ANOVA).

https://doi.org/10.1371/journal.pone.0102508.g005

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Table 4. Results of nested ANOVA to detect the effects of the platygastrid, tree individual and locality on the thickness of gall induced by Masakimyia pustulae.

https://doi.org/10.1371/journal.pone.0102508.t004

Comparison in parasitism by the late parasitoids between galls unparasitized and parasitized by Platygaster sp

In 2009, the late parasitoids were not found in the galls parasitized by Platygaster sp., and the percentage parasitism by the late parasitoids was significantly lower in the galls parasitized by Platygaster sp. in three of five trees surveyed in 2009 (Table 5). In 2010, the parasitism by the late parasitoids in the galls parasitized by Platygaster sp. was found only on Tree 1 in Nishikata, where the gall thickness was not significantly different between unparasitized and parasitized galls (Fig. 4). The percentage parasitism by the late parasitoids was remarkably high (90%) in the unparasitized galls on Tree 1 in Nishikata (Table 6). The percentage parasitism by the late parasitoids was significantly lower in the galls parasitized by Platygaster sp. than in those unparasitized on five trees in four localities. In two of the four localities, the gall thickness was significantly different between unparasitized and parasitized galls. The percentage parasitism by the late parasitoids also tended to be lower on the remaining trees and localities regardless of the gall thickness (Table 6).

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Table 5. Percentage parasitism by late parasitoids in galls containing only unparasitized Masakimyia pustulae larvae (Unparasitized MP) and in those containing host larvae parasitized by Platygaster sp. (Parasitized by PL) in 2009.

https://doi.org/10.1371/journal.pone.0102508.t005

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Table 6. Percentage parasitism by late parasitoids in galls containing only unparasitized Masakimyia pustulae larvae (Unparasitized MP) and in those containing host larvae parasitized by Platygaster sp. (Parasitized by PL) in 2010.

https://doi.org/10.1371/journal.pone.0102508.t006

Comparison in thickness between galls unparasitized and parasitized by the late parasitoids

Galls parasitized by Pnigalio sp. were significantly thinner than those unparasitized on one out of the three trees surveyed in 2009 (Fig. 6). Data of Itoshima and Nishikata in 2009 are not shown because the late parasitoids were seldom recorded (Table 2). In 2010, galls parasitized by Chrysonotomyia sp. were significantly thinner than those unparasitized on Tree 1 in Satsumataki (Fig. 6). Although no significant differences were detected on the remaining nine trees, five of them exhibited similar tendency to the tree (Fig. 6; see Table 7 for the result of nested ANOVA). Galls parasitized by Pnigalio sp. were significantly thicker than those unparasitized on Tree 2 in Itoshima, but not significantly different on the remaining trees and in other localities. The thickness of galls parasitized by Platygaster sp. was not significantly different between those subsequently parasitized and not parasitized by Pnigalio sp. (Fig. 6).

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Figure 6. The thickness of galls containing unparasitized Masakimyia pustulae larvae and those parasitized by the late parasitoids.

The number of galls examined was shown in each column. Abbreviations are as follows, T1 : Tree 1, T2: Tree 2, and T3: Tree 3. Different letters indicate significant differences at 5% level (nested ANOVA followed by pairwise comparisons of Student’s t-test in each tree with adjustment of p values by Holm’s method). The thickness of galls parasitized by Platygaster sp. and those hyperparasitized by the late parasitoids was shown at the bottom right.

https://doi.org/10.1371/journal.pone.0102508.g006

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Table 7. Results of nested ANOVA to detect the effects of late parasitoids, tree individual and localities on the thickness of gall induced by Masakimyia pustulae.

https://doi.org/10.1371/journal.pone.0102508.t007

Discussion

Our study clearly indicated that the hypertrophy of M. pustulae galls was associated with a decreased rate of parasitism by the late parasitoids. In contrast to the relatively high percentage parasitism by the early parasitoid both in the thick and thin types of gall (Tables 2 & 3), parasitism by the late parasitoids was seldom found in the thick type gall at Meiwa and Sanwa (Tables 2 & 3). On the contrary, more than 50% of galls were parasitized by the late parasitoids on Tree 1 in Nishikata and on Trees 1 and 2 in Satsumataki in 2010 (Table 3). These results strongly suggest that the hypertrophy of galls is effective in preventing parasitism by the late parasitoids, as mentioned by Sunose [26].

Galls parasitized by Platygaster sp. were significantly thicker than those unparasitized in most individual trees (Figs. 3 & 4). Because gall thickness was strongly affected by tree individualities (Table 4), it was not significantly different between unparasitized galls and those parasitized by Platygaster sp. on some trees (Fig. 4). However, galls parasitized by Platygaster sp. were mostly thicker than those unparasitized. Both the upper and lower gall walls were significantly thicker in galls parasitized by Platygaster sp. than in those unparasitized (Fig. 5). These results strongly suggest that galls parasitized by Platygaster sp. are adapted for avoiding hyperparasitism by the late parasitoids, because hypertrophy of gall wall is well known to decrease their parasitism rates [e.g. 31, 35] probably by preventing their ovipositors from penetrating the gall wall. Significant interaction effects of individual trees and localities were also detected (Table 4). Although the mechanism is still unknown, these results suggest that some trees and some local populations of M. pustulae may not respond to the manipulation by Platygaster sp.

The percentage parasitism by the late parasitoids was significantly lower in galls parasitized by Platygaster sp. than those unparasitized (Tables 5 & 6). These results strongly suggest that Platygaster sp. manipulates the behavior of M. pustulae larvae, possibly by enhancing their feeding activity, to thicken the gall wall to avoid hyperparasitism. An alternative possibility is that females of Platygaster sp. may be able to detect differences in host egg size, if any. They then prefer to lay their eggs in large host eggs, which are expected to give rise gall midge larvae that induce thick galls.

There were no significant differences in gall thickness between unparasitized and parasitized galls by Platygaster sp. on Tree 1 in Nishikata (Fig. 4), but percentage parasitism by the late parasitoids was significantly lower in galls parasitized by Platygaster sp. (Table 6). This suggests that Platygaster sp. avoids hyperparasitism by the late parasitoids not only by manipulation of the gall shape but also by other mechanisms, such as manipulation of gall wall hardness or of chemical components in gall tissue including volatiles emitted by the gall and attracting the late parasitoids. Otherwise, the late parasitoids may have an ability to recognize the existence of pupae of the early parasitoid inside the gall midge body, as has been known for some other parasitoids [e.g. 36], or may avoid attacking gall midge larvae that had been parasitized by Platygaster sp. Galls parasitized by Chrysonotomyia sp. were significantly thinner than unparasitized galls on two out of the ten trees surveyed in Shikanoshima and Satsumataki (Fig. 6). These results suggest that Chrysonotomyia sp. attack inhabitants in thinner galls more frequently and that Platygaster sp. increases their own survival rates by the hypertrophy of galls.

A recent study suggested that a braconid parasitoid Cotesia rubecula Marshall parasitizing Pieris rapae (L.) (Lepidoptera: Pieridae) decreased the survival rate of another parasitoid C. glomerata in different host individuals that feed on the same plant, through the manipulation of plant traits, probably plant-induced secondary metabolites [37]. However, quite a few studies have demonstrated the manipulation of plant characteristics by parasitoids to avoid the risk of predation and hyperparasitism. As far as we know, such a phenomenon was reported by a literature [23], in which the author briefly mentioned that galls induced by the gall wasp Andricus quadrilineatus Hartig (Hymenoptera: Cynipidae) became thicker and harder when they were attacked by an early parasitoid Aulogymnus euedoreschus Walker (Hymenoptera: Eulophidae). Moreover, the literature supposed that galls attacked by A. euedoreschus might be hardly penetrable by other parasitoids [23].

Our study demonstrated for the first time that the manipulation of plant morphology through the host insect by the early parasitoid was associated with a decreased rate of hyperparasitism by the late parasitoids. Therefore such manipulation is adaptive for the early parasitoid. Future investigations to clarify the mechanism underlying the host manipulation by the Platygaster sp. are necessary to understand its parasitic strategy and evolutionary process of tri-trophic interactions centered upon the immobile larvae of M. pustulae. Moreover, further studies focusing on immobile host–parasitoid systems may reveal various manipulation mechanisms by primary parasitoids to avoid the risk of hyperparasitism and predation.

Acknowledgments

We thank K. M. Harris for his critical reading of an early draft, T. Sunose for providing us with useful information on M. pustulae, and K. Tanaka for statistical advice. TF thanks Sk. Yamane, K. Araya, T. Tachi, J. Kusumi, and T. Hosoya for their support.

Author Contributions

Conceived and designed the experiments: TF YA JY MT. Performed the experiments: TF KM MT. Analyzed the data: TF MT. Contributed reagents/materials/analysis tools: TF KM MT. Wrote the paper: TF YA JY MT.

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