Female-Specific Specialization of a Posterior End Region of the Midgut Symbiotic Organ in Plautia splendens and Allied Stinkbugs

Many stinkbugs (Insecta: Hemiptera: Heteroptera) are associated with bacterial symbionts in a posterior region of the midgut. In these stinkbugs, adult females excrete symbiont-containing materials from the anus for transmission of the beneficial symbionts to their offspring. For ensuring the vertical symbiont transmission, a variety of female-specific elaborate traits at the cellular, morphological, developmental, and behavioral levels have been reported from diverse stinkbugs of the families Plataspidae, Urostylididae, Parastrachiidae, etc. Meanwhile, such elaborate female-specific traits for vertical symbiont transmission have been poorly characterized for the largest and economically important stinkbug family Pentatomidae. Here, we investigated the midgut symbiotic system of a pentatomid stinkbug, Plautia splendens. A specific gammaproteobacterial symbiont was consistently present extracellularly in the cavity of numerous crypts arranged in four rows on the midgut fourth section. The symbiont was smeared on the egg surface upon oviposition by adult females, orally acquired by newborn nymphs, and thereby transmitted vertically to the next generation and important for growth and survival of the host insects. We found that, specifically in adult females, several rows of crypts at the posterior end region of the symbiotic midgut were morphologically differentiated and conspicuously enlarged, often discharging the symbiotic bacteria from the crypt cavity to the main tract of the symbiotic midgut. The female-specific enlarged end crypts were also found in other pentatomid stinkbugs Plautia stali and Carbula crassiventris. These results suggest that the enlarged end crypts represent a female-specific specialized morphological trait for vertical symbiont transmission commonly found among stinkbugs of the family Pentatomidae.     

Bacterial symbionts of the giant jewel stinkbug Eucorysses grandis (Hemiptera: Scutelleridae)

Microbiological characterization of gut symbiotic bacteria in a limited number of stinkbugs of the families Acanthosomatidae, Plataspidae, Pentatomidae, Scutelleridae, Parastrachiidae, Alydidae and Pyrrhocoridae has shown symbiotic association with midgut bacteria to be common in phytophagous taxa of these heteropteran insects. Here we investigated the midgut bacterial symbiont of Eucorysses grandis, a stinkbug of the family Scutelleridae. A specific gammaproteobacterium was consistently identified in insects from five different geographic origins. The bacterium was detected in 64 of 64 insects sampled from three host populations. Phylogenetic analyses revealed that the bacterium constitutes a distinct lineage in the Gammaproteobacteria, neither closely related to the gut symbiont of another scutellerid stinkbug, Cantao ocellatus, nor to gut symbionts of other stinkbugs. Diagnostic PCR, in situ hybridization and electron microscopy demonstrated that the bacterium is located extracelluarly, in the midgut fourth section, which possesses crypts. These results indicate that the primary gut symbionts have multiple evolutionary origins in the Scutelleridae. A Sodalis-allied facultative symbiont was also identified in some insects from natural populations. Biological aspects of the primary gut symbiont and the secondary Sodalis-allied symbiont are discussed.     

An ancient but promiscuous host–symbiont association between Burkholderia gut symbionts and their heteropteran hosts

Here, we investigated 124 stinkbug species representing 20 families and 5 superfamilies for their Burkholderia gut symbionts, of which 39 species representing 6 families of the superfamilies Lygaeoidea and Coreoidea were Burkholderia-positive. Diagnostic PCR surveys revealed high frequencies of Burkholderia infection in natural populations of the stinkbugs, and substantial absence of vertical transmission of Burkholderia infection to their eggs. In situ hybridization confirmed localization of the Burkholderia in their midgut crypts. In the lygaeoid and coreoid stinkbugs, development of midgut crypts in their alimentary tract was coincident with the Burkholderia infection, suggesting that the specialized morphological configuration is pivotal for establishment and maintenance of the symbiotic association. The Burkholderia symbionts were easily isolated as pure culture on standard microbiological media, indicating the ability of the gut symbionts to survive outside the host insects. Molecular phylogenetic analysis showed that the gut symbionts of the lygaeoid and coreoid stinkbugs belong to a β-proteobacterial clade together with Burkholderia isolates from soil environments and Burkholderia species that induce plant galls. On the phylogeny, the stinkbug-associated, environmental and gall-forming Burkholderia strains did not form coherent groups, indicating host–symbiont promiscuity among these stinkbugs. Symbiont culturing revealed that slightly different Burkholderia genotypes often coexist in the same insects, which is also suggestive of host–symbiont promiscuity. All these results strongly suggest an ancient but promiscuous host–symbiont relationship between the lygaeoid/coreoid stinkbugs and the Burkholderia gut symbionts. Possible mechanisms as to how the environmentally transmitted promiscuous symbiotic association has been stably maintained in the evolutionary course are discussed.     

Gut symbiotic bacteria in the cabbage bugs <Emphasis Type="Italic">Eurydema rugosa</Emphasis> and <Emphasis Type="Italic">Eurydema dominulus</Emphasis> (Heteroptera: Pentatomidae)

The cabbage bugs Eurydema rugosa Motschulsky and Eurydema dominulus (Scopoli) (Heteroptera: Pentatomidae: Strachiini) possess a number of crypts in a posterior region of the midgut, which are filled with bacterial symbiont cells. Here we characterized the gut symbionts of Eurydema stinkbugs using molecular phylogenetic and histological techniques. Specific gammaproteobacteria were consistently identified from the posterior midgut of E. rugosa representing nine populations and E. dominulus representing six populations, respectively. The bacterial 16S rRNA gene sequences were identical within the species but slightly different (98.2% sequence identity) between the species. Molecular phylogenetic analysis revealed that the Eurydema symbionts formed a well-defined monophyletic group in the Gammaproteobacteria. The symbionts were phylogenetically distinct from the gut symbionts of the stinkbug families Acanthosomatidae, Plataspidae, Parastrachiidae, Scutelleridae, and other pentatomid species, suggesting multiple evolutionary origins of the gut symbiotic bacteria among diverse stinkbugs. In situ hybridization confirmed that the symbiont is located in the cavity of the midgut crypts. Aposymbiotic insects of E. rugosa, which were produced by egg surface sterilization, were viable but suffered retarded growth, reduced body weight, and abnormal body color, suggesting the biological importance of the symbiont for the host.     

Primary Gut Symbiont and Secondary,Sodalis-Allied Symbiont of the Scutellerid Stinkbug Cantao ocellatus

Symbiotic associations with midgut bacteria have been commonly found in diverse phytophagous heteropteran groups, where microbiological characterization of the symbiotic bacteria has been restricted to the stinkbug families Acanthosomatidae, Plataspidae, Pentatomidae, Alydidae, and Pyrrhocoridae. Here we investigated the midgut bacterial symbiont of Cantao ocellatus, a stinkbug of the family Scutelleridae. A specific gammaproteobacterium was consistently identified from the insects of different geographic origins. The bacterium was detected in all 116 insects collected from 9 natural host populations. Phylogenetic analyses revealed that the bacterium constitutes a distinct lineage in the Gammaproteobacteria, not closely related to gut symbionts of other stinkbugs. Diagnostic PCR and in situ hybridization demonstrated that the bacterium is extracellularly located in the midgut 4th section with crypts. Electron microscopy of the crypts revealed a peculiar histological configuration at the host-symbiont interface. Egg sterilization experiments confirmed that the bacterium is vertically transmitted to stinkbug nymphs via egg surface contamination. In addition to the gut symbiont, some individuals of C. ocellatus harbored another bacterial symbiont in their gonads, which was closely related to Sodalis glossinidius, the secondary endosymbiont of tsetse flies. Biological aspects of the primary gut symbiont and the secondary Sodalis-allied symbiont are discussed.Insects are among the largest animal groups on the earth, embracing 750,000 to several millions of species (37, 52). Diverse insects are symbiotically associated with microorganisms, especially bacteria (5-7). In some insects, symbiotic bacteria are harbored in specialized host cells called bacteriocytes (or mycetocytes), constituting obligate mutualistic associations. For example, Buchnera aphidicola is harbored within bacteriocytes in the abdominal body cavity of almost all aphids and provides essential amino acids that are lacking in the phloem sap diet of the insects (9, 47). Wigglesworthia glossinidia is localized in a midgut-associated bacteriome of tsetse flies and plays pivotal roles in biosynthesis of B vitamins that are deficient in the vertebrate blood diet of the insects (2, 34). These obligate endocellular symbionts are often collectively referred to as “primary symbionts.”In contrast, there are facultative endosymbiotic microorganisms not essential for their host insects, often collectively called “secondary symbionts.” For example, many aphids are known to harbor various facultative symbionts, which belong to distinct lineages in the Gamma- and Alphaproteobacteria (33, 43) and the Mollicutes (10). While the majority of those facultative bacteria are either parasitic or commensalistic for their hosts, some of them affect the host fitness beneficially in particular ecological contexts (29, 32, 36, 44, 51). In addition to the obligate primary symbiont Wigglesworthia, tsetse flies harbor the facultative secondary symbiont Sodalis glossinidius, whose biological function for the hosts is currently elusive (3, 8).Members of the suborder Heteroptera, known as true bugs and consisting of over 38,000 described species, are characterized by their sucking mouthparts, half-membranous forewings, and incomplete metamorphosis (46). In the Heteroptera, symbiotic associations with bacteria are mainly found in phytophagous groups, especially in stinkbugs of the infraorder Pentatomomorpha. These stinkbugs generally possess many sacs or tubular outgrowths, called crypts or ceca, in a posterior region of the midgut, whose lumen is densely populated by a specific bacterial symbiont (7, 16). In some cases, experimental elimination of the symbiotic bacteria resulted in retarded growth and high mortality of the host insects (1, 13, 21, 26, 27, 39), indicating that these gut symbionts play important biological roles. Most of the gut symbionts are vertically transmitted through host generations by such mechanisms as egg surface contamination in the families Pentatomidae and Acanthosomatidae (1, 27, 39, 40, 42), coprophagy in the Cydnidae and Coreidae (22, 45), and capsule transmission in the Plataspidae (20), whereas a case of environmental acquisition has been reported from the Alydidae (26). Thus far, gut symbiotic bacteria of some members of the Acanthosomatidae, Plataspidae, Pentatomidae, Alydidae, and Pyrrhocoridae have been characterized using molecular techniques (21, 23, 25, 27, 38), while phylogenetic and biological aspects of gut symbiotic bacteria have been untouched in many other stinkbug groups.These gut symbiotic bacteria are, despite their extracellular localization, regarded as “primary symbionts” of the stinkbugs. On the other hand, some stinkbugs may, in addition to the gut symbiotic bacteria, also be associated with facultative “secondary symbionts.” For example, Wolbachia infections have been detected from diverse stinkbugs, most of which are probably of parasitic or commensalistic nature (24). Besides Wolbachia, there has been no report on facultative, secondary symbionts from stinkbugs.Members of the family Scutelleridae, often referred to as jewel bugs or shield-backed bugs, are stinkbugs characterized by their greatly enlarged convex scutellum that usually covers the entire abdomen. Some tropical species are also known for their vivid and beautiful body coloration (46). The family contains approximately 80 genera and 450 species, and in Japan, at least 7 genera and 9 species have been recorded (50). In the early 20th century, the presence of symbiotic bacteria was histologically described in midgut crypts of several scutellerid species (16, 31, 42). Since these pioneer works, however, no studies have been conducted on the symbiotic bacteria of scutellerid stinkbugs.Here we investigated the midgut symbiont of Cantao ocellatus, a scutellerid stinkbug widely distributed in Asian countries, including Japan, and known to guard their eggs and newborn nymphs (Fig. ​(Fig.1A)1A) (50). In addition to the gut symbiont, we also identified a Sodalis-allied facultative secondary symbiont from gonads of the insect.Open in a separate windowFIG. 1.(A) Adult female of Cantao ocellatus, guarding hatchlings under her body. (B) Dissected midgut from an adult female of C. ocellatus. 1st, midgut 1st section; 2nd, midgut 2nd section; 3rd, midgut 3rd section; 4th, midgut 4th section with crypts; hg, hindgut. (C) Enlarged image of the midgut 4th section with crypts. Arrowheads indicate three rows of crypts, while a fourth row is hidden behind. Glandular crypts (gc) are developed in adult females specifically, which may be involved in egg surface contamination with the symbiont. (D) An in situ hybridization image of the midgut 4th section, in which red and green signals indicate the gut symbiont and the host nucleus, respectively. Each arrow shows a crypt. (E) An enlarged image of the symbiotic bacteria in the crypts.     

The making of symbiont capsule in the plataspid stinkbug Megacopta punctatissima

In stinkbugs of the family Plataspidae, adult females deposit small brownish particles, containing specific symbiotic bacteria inside, on the underside of their egg mass. Newborn nymphs ingest the content of the unique structure, called "symbiont capsule", whereby vertical transmission of the symbiont occurs. We investigated the fine structure and the formation process of the symbiont capsule in the Japanese common plataspid stinkbug, Megacopta punctatissima, by using light and electron microscopy. It was demonstrated that (i) the capsule consists of three structural components, namely "symbionts", "matrix" and "envelope"; (ii) the posterior midgut of adult females is characterized by several specific sections with peculiar anatomical traits, including "thin crypt-bearing midgut (TCM) section", "swollen crypt-bearing midgut (SCM) section" and "brownish enlarged midgut (BEM) end section"; (iii) the different capsule components, symbionts, matrix and envelope, are produced and/or supplied by the specialized midgut sections, TCM, SCM and BEM, respectively; and (iv) the capsule components are stored in BEM and excreted during oviposition to produce the symbiont capsules. These results strongly suggested that the host insect incurs a substantial cost for the symbiont transmission. Ecological and evolutionary implications of the highly developed, female-specific system for symbiont transmission were discussed.     

Strict host-symbiont cospeciation and reductive genome evolution in insect gut bacteria

Host-symbiont cospeciation and reductive genome evolution have been identified in obligate endocellular insect symbionts, but no such example has been identified from extracellular ones. Here we first report such a case in stinkbugs of the family Plataspidae, wherein a specific gut bacterium is vertically transmitted via “symbiont capsule.” In all of the plataspid species, females produced symbiont capsules upon oviposition and their gut exhibited specialized traits for capsule production. Phylogenetic analysis showed that the plataspid symbionts constituted a distinct group in the γ-Proteobacteria, whose sister group was the aphid obligate endocellular symbionts Buchnera. Removal of the symbionts resulted in retarded growth, mortality, and sterility of the insects. The host phylogeny perfectly agreed with the symbiont phylogeny, indicating strict host-symbiont cospeciation despite the extracellular association. The symbionts exhibited AT-biased nucleotide composition, accelerated molecular evolution, and reduced genome size, as has been observed in obligate endocellular insect symbionts. These findings suggest that not the endocellular conditions themselves but the population genetic attributes of the vertically transmitted symbionts are probably responsible for the peculiar genetic traits of these insect symbionts. We proposed the designation “Candidatus Ishikawaella capsulata” for the plataspid symbionts. The plataspid stinkbugs, wherein the host-symbiont associations can be easily manipulated, provide a novel system that enables experimental approaches to previously untouched aspects of the insect-microbe mutualism. Furthermore, comparative analyses of the sister groups, the endocellular Buchnera and the extracellular Ishikawaella, would lead to insights into how the different symbiotic lifestyles have affected their genomic evolution.     

Obligate gut symbiotic association in the sloe bug <Emphasis Type="Italic">Dolycoris baccarum</Emphasis> (Hemiptera: Pentatomidae)

A number of phytophagous stinkbugs are associated with specific bacterial symbionts in their alimentary tracts. The sloe bug Dolycoris baccarum (Linnaeus), a notorious pest of diverse crops, possesses a number of sac-like tissues, called crypts, in a posterior section of the midgut, wherein a specific bacterial symbiont colonizes. Here we characterized the symbiotic bacterium of D. baccarum by histological analysis, molecular phylogeny, and diagnostic PCR with a specific primer set. The cloning and sequencing analyses of bacterial 16S rRNA genes and fluorescent in situ hybridization demonstrated that the sloe bug is associated with a single species of Gammaproteobacteria in the midgut crypts. Molecular phylogenetic analysis strongly suggested that the symbiont should be placed in the genus Pantoea of the Enterobacteriaceae. Diagnostic PCR and egg surface sterilization with formalin indicated the stinkbug vertically transmits the Pantoea symbiont via egg-smearing. The sterilization-produced aposymbiotic nymphs showed high mortality and no insects reached adulthood. In addition, the Pantoea symbiont was uncultivable outside the insect host, indicating an obligate and intimate host-symbiont association.     

Specific Midgut Region Controlling the Symbiont Population in an Insect-Microbe Gut Symbiotic Association

Many insects possess symbiotic bacteria that affect the biology of the host. The level of the symbiont population in the host is a pivotal factor that modulates the biological outcome of the symbiotic association. Hence, the symbiont population should be maintained at a proper level by the host''s control mechanisms. Several mechanisms for controlling intracellular symbionts of insects have been reported, while mechanisms for controlling extracellular gut symbionts of insects are poorly understood. The bean bug Riptortus pedestris harbors a betaproteobacterial extracellular symbiont of the genus Burkholderia in the midgut symbiotic organ designated the M4 region. We found that the M4B region, which is directly connected to the M4 region, also harbors Burkholderia symbiont cells, but the symbionts therein are mostly dead. A series of experiments demonstrated that the M4B region exhibits antimicrobial activity, and the antimicrobial activity is specifically potent against the Burkholderia symbiont but not the cultured Burkholderia and other bacteria. The antimicrobial activity of the M4B region was detected in symbiotic host insects, reaching its highest point at the fifth instar, but not in aposymbiotic host insects, which suggests the possibility of symbiont-mediated induction of the antimicrobial activity. This antimicrobial activity was not associated with upregulation of antimicrobial peptides of the host. Based on these results, we propose that the M4B region is a specialized gut region of R. pedestris that plays a critical role in controlling the population of the Burkholderia gut symbiont. The molecular basis of the antimicrobial activity is of great interest and deserves future study.     

Bacterial Symbionts of a Devastating Coffee Plant Pest,the Stinkbug Antestiopsis thunbergii (Hemiptera: Pentatomidae)

Stinkbugs of the genus Antestiopsis, so-called antestia bugs or variegated coffee bugs, are notorious pests of coffee plants in Africa. We investigated the symbiotic bacteria associated with Antestiopsis thunbergii, a major coffee plant pest in Rwanda. PCR, cloning, sequencing, and phylogenetic analysis of bacterial genes identified four distinct bacterial lineages associated with A. thunbergii: a gammaproteobacterial gut symbiont and symbionts representing the genera Sodalis, Spiroplasma, and Rickettsia. In situ hybridization showed that the gut symbiont densely occupied the lumen of midgut crypts, whereas the Sodalis symbiont, the Spiroplasma symbiont, and the Rickettsia symbiont sparsely and sporadically infected various cells and tissues. Diagnostic PCR survey of 154 A. thunbergii individuals collected at 8 localities in Rwanda revealed high infection frequencies (100% for the gut symbiont, 51.3% for the Sodalis symbiont, 52.6% for the Spiroplasma symbiont, and 24.0% for the Rickettsia symbiont). These results suggest that the gut symbiont is the primary symbiotic associate of obligate nature for A. thunbergii, whereas the Sodalis symbiont, the Spiroplasma symbiont, and the Rickettsia symbiont are the secondary symbiotic associates of facultative nature. We observed high coinfection frequencies, i.e., 7.8% of individuals with quadruple infection with all the symbionts, 32.5% with triple infections with the gut symbiont and two of the secondary symbionts, and 39.6% with double infections with the gut symbiont and any of the three secondary symbionts, which were statistically not different from the expected coinfection frequencies and probably reflected random associations. The knowledge of symbiotic microbiota in A. thunbergii will provide useful background information for controlling this devastating coffee plant pest.     

Next‐generation sequencing sheds light on intricate regulation of insect gut microbiota

Next‐generation sequencing (NGS) technologies are getting cheaper and easier and hence becoming readily accessible for many researchers in biological disciplines including ecology. In this issue of Molecular Ecology, Sudakaran et al. (2012) show how the NGS revolution contributes to our better and more comprehensive understanding of ecological interactions between gut symbiotic microbiota and the host organism. Using the European red firebug Pyrrhocoris apterus as a model system, they demonstrated that the gut microbiota consists of a small number of major bacterial phylotypes plus other minor bacterial associates. The major bacteria are localized in a specific anoxic section of the midgut and quantitatively account for most of the gut microbiota irrespective of host's geographic populations. The specific gut microbiota is established through early nymphal development of the host insect. Interestingly, the host feeding on different food, namely linden seeds, sunflower seeds or wasp larvae, scarcely affected the symbiont composition, suggesting homoeostatic control over the major symbiotic microbiota in the anoxic section of the midgut. Some of the minor components of the gut microbiota, which conventional PCR/cloning/sequencing approaches would have failed to detect, were convincingly shown to be food‐derived. These findings rest on the robust basis of high‐throughput sequencing data, and some of them could not be practically obtained by conventional molecular techniques, highlighting the significant impact of NGS approaches on ecological aspects of host–symbiont interactions in a nonmodel organism.     

Polyphyly of gut symbionts in stinkbugs of the family Cydnidae

Symbiotic bacteria associated with midgut crypts of stinkbugs of the family Cydnidae, representing seven species and 13 populations, were investigated. All of the symbionts were species specific, and constituted at least four distinct lineages in the Gammaproteobacteria, indicating multiple evolutionary origins of the gut symbionts among the burrower bugs.     

Re-opening of the symbiont sorting organ with aging in Riptortus pedestris

Because environments are full of diverse microorganisms including parasites and pathogens, how to select and maintain a beneficial microbial partner is a critical issue for host organisms. The bean bug Riptortus pedestris (Heteroptera: Alydidae) acquires a specific gut symbiont, Burkholderia insecticola, from environmental soil in the second instar stage and houses it in a crypt-bearing midgut region called M4. To sort the Burkholderia symbiont from a wide variety of soil microbes, R. pedestris develops a specialized organ named “constricted region (CR)”. The CR, located in front of the crypt-bearing symbiotic region, is immediately closed after colonization of M4 by the Burkholderia symbiont to block any contamination of microbes ingested with food. By using a food coloring and a red fluorescent protein (RFP)-expressing Burkholderia symbiont, we here revealed that the closed CR is re-opened at a later developmental stage of R. pedestris. Although the CR was re-opened at the late phase of the fifth instar, oral administration of food coloring and green fluorescent protein (GFP)-expressing symbiont demonstrated that ingested food and bacteria were stopped at the M4B despite the opened CR. Observations using confocal microscopy revealed reverse flow of gut content from M4 to M3 through the opened CR, the flow pressure of which seemed to prevent any contamination of the symbiotic M4 region. The morphological change of the CR with aging may cause a risk of contamination, but another mechanism, the reverse flow, plausibly maintains the specificity of gut symbiont in R. pedestris.     

Symbiotic bacteria associated with gut symbiotic organs and female genital accessory organs of the leaf beetle <Emphasis Type="Italic">Bromius obscurus</Emphasis> (Coleoptera: Chrysomelidae)

Leaf beetles (Coleoptera: Chrysomelidae) constitute one of the most species-rich insect families, and live exclusively on leaves or other plant parts. Early histological works described the presence of symbiotic bacteria in gut-associated symbiotic organs of some chrysomelid species, but their microbiological nature has been poorly characterized except for those associated with reed beetles of the subfamily Donaciinae. Here we investigated symbiotic bacteria of the leaf beetle Bromius obscurus (L.) belonging to the subfamily Eumolpinae. Specific bacterial 16S ribosomal RNA and gyrB gene sequences were consistently obtained from the symbiotic organs, which radially surround the foregut-midgut junction, of all adult males and females examined. In adult females, the same sequences were also obtained from a pair of genital accessory organs, which are presumably for vertical symbiont transmission. Whole mount in situ hybridization specifically detected the symbiont in the gut symbiotic organs endocellularly and also in the female genital accessory organs extracellularly. In the gut symbiotic organs, the endocellular symbiont cells were small and rosette-like or aggregated and granule-like, whereas in the female genital organs the extracellular symbiont cells were of a condensed form. Molecular phylogenetic analysis showed that the symbiont of B. obscurus constitutes a distinct lineage in the Gammaproteobacteria. Molecular evolutionary analysis has identified significantly accelerated molecular evolution and a highly adenine–thymine-biased nucleotide composition of the symbiont genes, presumably reflecting reductive evolution of the symbiont genome. These results suggest an intimate and stable host-symbiont association in B. obscurus, in which the symbiont may play some important, though hitherto unknown, biological roles in its herbivorous insect host.     

Insecticide applications to soil contribute to the development of Burkholderia mediating insecticide resistance in stinkbugs

Some soil Burkholderia strains are capable of degrading the organophosphorus insecticide, fenitrothion, and establish symbiosis with stinkbugs, making the host insects fenitrothion‐resistant. However, the ecology of the symbiotic degrading Burkholderia adapting to fenitrothion in the free‐living environment is unknown. We hypothesized that fenitrothion applications affect the dynamics of fenitrothion‐degrading Burkholderia, thereby controlling the transmission of symbiotic degrading Burkholderia from the soil to stinkbugs. We investigated changes in the density and diversity of culturable Burkholderia (i.e. symbiotic and nonsymbiotic fenitrothion degraders and nondegraders) in fenitrothion‐treated soil using microcosms. During the incubation with five applications of pesticide, the density of the degraders increased from less than the detection limit to around 10⁶/g of soil. The number of dominant species among the degraders declined with the increasing density of degraders; eventually, one species predominated. This process can be explained according to the competitive exclusion principle using V_max and K_m values for fenitrothion metabolism by the degraders. We performed a phylogenetic analysis of representative strains isolated from the microcosms and evaluated their ability to establish symbiosis with the stinkbug Riptortus pedestris. The strains that established symbiosis with R. pedestris were assigned to a cluster including symbionts commonly isolated from stinkbugs. The strains outside the cluster could not necessarily associate with the host. The degraders in the cluster predominated during the initial phase of degrader dynamics in the soil. Therefore, only a few applications of fenitrothion could allow symbiotic degraders to associate with their hosts and may cause the emergence of symbiont‐mediated insecticide resistance.     

Purine Biosynthesis,Biofilm Formation,and Persistence of an Insect-Microbe Gut Symbiosis

The Riptortus-Burkholderia symbiotic system is an experimental model system for studying the molecular mechanisms of an insect-microbe gut symbiosis. When the symbiotic midgut of Riptortus pedestris was investigated by light and transmission electron microscopy, the lumens of the midgut crypts that harbor colonizing Burkholderia symbionts were occupied by an extracellular matrix consisting of polysaccharides. This observation prompted us to search for symbiont genes involved in the induction of biofilm formation and to examine whether the biofilms are necessary for the symbiont to establish a successful symbiotic association with the host. To answer these questions, we focused on purN and purT, which independently catalyze the same step of bacterial purine biosynthesis. When we disrupted purN and purT in the Burkholderia symbiont, the ΔpurN and ΔpurT mutants grew normally, and only the ΔpurT mutant failed to form biofilms. Notably, the ΔpurT mutant exhibited a significantly lower level of cyclic-di-GMP (c-di-GMP) than the wild type and the ΔpurN mutant, suggesting involvement of the secondary messenger c-di-GMP in the defect of biofilm formation in the ΔpurT mutant, which might operate via impaired purine biosynthesis. The host insects infected with the ΔpurT mutant exhibited a lower infection density, slower growth, and lighter body weight than the host insects infected with the wild type and the ΔpurN mutant. These results show that the function of purT of the gut symbiont is important for the persistence of the insect gut symbiont, suggesting the intricate biological relevance of purine biosynthesis, biofilm formation, and symbiosis.     

Insect Gut Symbiont Susceptibility to Host Antimicrobial Peptides Caused by Alteration of the Bacterial Cell Envelope

The molecular characterization of symbionts is pivotal for understanding the cross-talk between symbionts and hosts. In addition to valuable knowledge obtained from symbiont genomic studies, the biochemical characterization of symbionts is important to fully understand symbiotic interactions. The bean bug (Riptortus pedestris) has been recognized as a useful experimental insect gut symbiosis model system because of its cultivatable Burkholderia symbionts. This system is greatly advantageous because it allows the acquisition of a large quantity of homogeneous symbionts from the host midgut. Using these naïve gut symbionts, it is possible to directly compare in vivo symbiotic cells with in vitro cultured cells using biochemical approaches. With the goal of understanding molecular changes that occur in Burkholderia cells as they adapt to the Riptortus gut environment, we first elucidated that symbiotic Burkholderia cells are highly susceptible to purified Riptortus antimicrobial peptides. In search of the mechanisms of the increased immunosusceptibility of symbionts, we found striking differences in cell envelope structures between cultured and symbiotic Burkholderia cells. The bacterial lipopolysaccharide O antigen was absent from symbiotic cells examined by gel electrophoretic and mass spectrometric analyses, and their membranes were more sensitive to detergent lysis. These changes in the cell envelope were responsible for the increased susceptibility of the Burkholderia symbionts to host innate immunity. Our results suggest that the symbiotic interactions between the Riptortus host and Burkholderia gut symbionts induce bacterial cell envelope changes to achieve successful gut symbiosis.     

Viral cystatin evolution and three-dimensional structure modelling: A case of directional selection acting on a viral protein involved in a host-parasitoid interaction

Background  

In pathogens, certain genes encoding proteins that directly interact with host defences coevolve with their host and are subject to positive selection. In the lepidopteran host-wasp parasitoid system, one of the most original strategies developed by the wasps to defeat host defences is the injection of a symbiotic polydnavirus at the same time as the wasp eggs. The virus is essential for wasp parasitism success since viral gene expression alters the immune system and development of the host. As a wasp mutualist symbiont, the virus is expected to exhibit a reduction in genome complexity and evolve under wasp phyletic constraints. However, as a lepidopteran host pathogenic symbiont, the virus is likely undergoing strong selective pressures for the acquisition of new functions by gene acquisition or duplication. To understand the constraints imposed by this particular system on virus evolution, we studied a polydnavirus gene family encoding cyteine protease inhibitors of the cystatin superfamily.     

Obligate association with gut bacterial symbiont in Japanese populations of the southern green stinkbug <Emphasis Type="Italic">Nezara viridula</Emphasis> (Heteroptera: Pentatomidae)

The southern green stinkbug Nezara viridula (Linnaeus) has a number of sac-like outgrowths, called crypts, in a posterior section of the midgut, wherein a specific bacterial symbiont is harbored. In previous studies on N. viridula from Hawaiian populations, experimental elimination of the symbiont caused few fitness defects in the host insect. Here we report that N. viridula from Japanese populations consistently harbors the same gammaproteobacterial gut symbiont, but, in contrast with previous work, experimental sterilization of the symbiont resulted in severe nymphal mortality, indicating an obligate host–symbiont relationship. Considering worldwide host–symbiont association and these experimental data, we suggest that N. viridula is generally and obligatorily associated with the gut symbiont, but that the effect of the symbiont on host biology may be different among geographic populations. Possible environmental factors that may affect the host–symbiont relationship are discussed.