Evidence for a symbiosis island involved in horizontal acquisition of pederin biosynthetic capabilities by the bacterial symbiont of Paederus fuscipes beetles

Pederin belongs to a group of antitumor compounds found in terrestrial beetles and marine sponges. It is used by apparently all members of the rove beetle genera Paederus and Paederidus as a chemical defense against predators. However, a recent analysis of the putative pederin biosynthesis (ped) gene cluster strongly suggests that pederin is produced by bacterial symbionts. We have sequenced an extended region of the symbiont genome to gain further insight into the biology of this as-yet-unculturable bacterium and the evolution of pederin symbiosis. Our data indicate that the symbiont is a very close relative of Pseudomonas aeruginosa that has acquired several foreign genetic elements by horizontal gene transfer. Besides one functional tellurite resistance operon, the region contains a genomic island spanning 71.6 kb that harbors the putative pederin biosynthetic genes. Several decayed insertion sequence elements and the mosaic-like appearance of the island suggest that the acquisition of the ped symbiosis genes was followed by further insertions and rearrangements. A horizontal transfer of genes for the biosynthesis of protective substances could explain the widespread occurrence of pederin-type compounds in unrelated animals from diverse habitats.     

Novel oligonucleotide probes for in situ detection of pederin-producing endosymbionts of Paederus riparius rove beetles (Coleoptera: Staphylinidae)

Bacterial endosymbionts from female Paederus rove beetles are hitherto uncultured, phylogenetically related to Pseudomonas sp., and produce the polyketide pederin, which exhibits strong cytotoxic effects and antitumoral activities. The location of such endosymbionts inside beetles and on beetles' eggs is hypothesized based on indirect evidence rather than elucidated. Thus, an endosymbiont-specific and a competitor oligonucleotide probe (Cy3-labelled PAE444 and unlabelled cPAE444, respectively) were designed and utilized for FISH with semi-thin sections of Paederus riparius eggs. Cy3-PAE444-positive cells were densely packed and covered the whole eggshell. Hundred percent of EUB338-Mix-positive total bacterial cells were PAE444 positive, indicating a biofilm dominated by Paederus endosymbionts. Analysis of different egg deposition stadiums by electron microscopy and pks (polyketide synthase gene, a structural gene associated with pederin biosynthesis)-PCR supported results obtained by FISH and revealed that the endosymbiont-containing layer is applied to the eggshell inside the efferent duct. These findings suggest that P. riparius endosymbionts are located inside unknown structures of the female genitalia, which allow for a well-regulated release of endosymbionts during oviposition. The novel oligonucleotide probes developed in this study will facilitate (1) the identification of symbiont-containing structures within genitalia of their beetle hosts and (2) directed cultivation approaches in the future.     

Possible genetic basis of pederin polymorphism in rove beetles (Paederus riparius)

In Paederus riparius, (+) females able to biosynthesize the unique hemolymph toxin pederin and (-) females lacking this ability co-occur in natural populations. Larvae descended from both types of females were reared in the laboratory and the imagoes were crossed in order to get information about a possible genetic basis of this polymorphism. The daughters of (+) mothers become (+) females or (-) females, while the progeny of (-) mothers comprises only (-) females. This suggests a matrilineal trait because pederin biosynthesis cannot be inherited from the father. The rather stable proportion of nearly 90% (+) females in collected females is not maintained, however, when the beetles are reared in the laboratory. This observation is discussed with regard to artificial rearing conditions, where individuals are kept separate and cannot prey on conspecifics.     

Suppression of pederin biosynthesis through antibiotic elimination of endosymbionts in Paederus sabaeus

Biosynthesis of the unique defensive compound pederin is confined to female rove beetles of the genus Paederus (Coleoptera: Staphylinidae). These (+)-females endow their eggs with toxin whereas (-)-females, which occur both naturally and in laboratory reared specimens, do not. The latter are aposymbionts lacking biosynthetic capabilities because of endosymbiotic deficiency. They can, however, be induced to accumulate pederin if fed with (+)-eggs during larval development. The endosymbionts can thus be transmitted by ingestion of (+)-Eggs. (+)-eggs treated with benzylpenicillin, erythromycin, oxytetracycline or streptomycin show that the induction of pederin accumulation depends on the antibiotic's spectrum of efficaciousness, its dosage and duration of the treatment. Certain bacteria, probably belonging to the gram-negative type, must be transmitted to produce (+)-females.     

What is the basis of pederin polymorphism in Paederus riparius rove beetles? The endosymbiotic hypothesis

Paederus riparius (Coleoptera:Staphylinidae) females are polymorphic with regard to their ability to synthesize the hemolymph toxin pederin, a character confined to that sex: (+)-females endow their eggs with pederin whereas (–)-females lay eggs devoid of the substance. When reared without access to conspecifics, (+)-females can only be obtained from (+)-mothers. Ingestion of (+)-eggs during larval development, however, enables the offspring of (–)-females to also become (+)-females. This is only the case if untreated (+)-eggs are eaten, while sterilized (+)-eggs do not alter larval fate as (–)-females. The character can thus be transferred to unrelated specimens. These experiments suggest that microorganisms might be involved in the biosynthesis of this unusual compound. Pederin appears to be the first defensive substance in insects traceable to endosymbionts.     

Effects of mass releases of Trichogramma brassicae on predatory insects in maize

Abstract Females of the rove beetle genus Paederus (Coleoptera: Staphylinidae) accumulate large amounts of the defensive compound pederin produced by an endosymbiotic bacterium. Pederin is transferred in the eggs, while the endosymbionts are transmitted via the egg shell. In all three species analyzed (P. melanurus, P. riparius, and P. sabaeus), descendants of aposymbiotic matrilines (lacking both endosymbionts and biosynthetic capabilities) acquire biosynthetic capability by the ingestion of eggs with endosymbionts during larval development. Successful colonization by endosymbionts depends on the number of eggs consumed and the age of the feeding larvae. During the adult stage, however, the females cannot acquire biosynthetic capabilities. Adult females are able to sequester pederin from eggs eaten, and they transfer the substance into their own eggs. Lack of intrinsic biosynthesis after ingestion of endosymbionts indicates that these are not biosynthetically active within the gut and have to reach an unknown internal location before completion of metamorphosis. These results are discussed with regard to the benefit of intraspecific cannibalism.     

DO VARIABLE COMPENSATORY MECHANISMS EXPLAIN THE POLYMORPHISM OF THE DEPENDENCE PHENOTYPE IN THE ASOBARA TABIDA‐WOLBACHIA ASSOCIATION?

Wolbachia are symbiotic intracellular bacteria, which are classified as reproductive parasites. Although generally facultative, Wolbachia is necessary for Asobara tabida (Hymenoptera), because aposymbiotic females do not produce any offspring. Interestingly, the ovarian phenotype of aposymbiotic females is variable: some females do not produce any eggs, whereas others do produce some eggs, but these are aborted. Here, we show that the ovarian phenotype of aposymbiotic females is highly polymorphic within populations, although dependence remains complete in both cases. We also identified some lines in which aposymbiotic females were able to produce a very few viable offspring, further extending the range of variation observed. These results suggest that various factors actively maintain polymorphism. We demonstrated that Wolbachia is necessary to trigger oogenetic processes, but that the ovarian phenotype was determined by the host only. Phenotypic variation was also correlated with the differential expression of genes controlling iron homeostasis and oxidative stress, which are potentially involved in the evolution of dependence. This suggests that variation in the ovarian phenotype could reflect selection for different levels of compensatory mechanisms in response to Wolbachia infection, and that polymorphism is maintained through selection on different antagonist traits influenced by oxidative stress.     

Differential efficacy of toxic pederin in deterring potential arthropod predators of Paederus (Coleoptera: Staphylinidae) offspring

This study investigates the effects of pederin, a hemolymph toxin that is accumulated in the eggs of most Paederus females, on potential arthropod predators of the offspring of P. fuscipes and P. riparius. Insects generally do not respond to pederin present in the prey. Paederus larvae are sufficiently agile to escape from these predators by running away, and the eggs are hidden by the females. Unlike insects, (wolf) spiders are deterred by prey with pederin. They turn away from larvae they have already captured and exhibit cleansing behavior. Larvae containing pederin survive the attacks of spiders without damage, whereas larvae descended from females that do not transfer pederin into their eggs are often killed and eaten. In the case of sudden attacks by spiders, the larvae have no chance of escape. Their survival thus depends on chemical defense. These investigations show for the first time why pederin might be of considerable importance for Paederus in the field.     

Wolbachia requirement for oogenesis: occurrence within the genus Asobara (Hymenoptera, Braconidae) and evidence for intraspecific variation in A. tabida

Wolbachia are symbiotic bacteria that induce a diversity of phenotypes on their numerous invertebrate host species. In the wasp Asobara tabida (Braconidae), each individual harbours three Wolbachia strains: wAtab3, which is required for host oogenesis, and wAtab1 and wAtab2, that do not have this function but induce cytoplasmic incompatibility. In this study, we surveyed and identified Wolbachia strains in four additional Asobara species. We detected Wolbachia in one of these species, but both the identity (based on wsp gene) and prevalence of the Wolbachia detected in natural population indicate that this host species is not dependent on Wolbachia for oogenesis. We also compared A. tabida lines of different geographical origin for their dependence on Wolbachia. All individuals from 16 A. tabida lines proved to be infected by the three Wolbachia strains wAtab1, wAtab2 and wAtab3, but, interestingly, we found variation among lines in the degree to which females were dependent on Wolbachia to produce their oocytes. In three lines, aposymbiotic females (cured from the three Wolbachia strains by antibiotics) can produce some oocytes. However, these aposymbiotic females produce fewer and smaller oocytes than symbiotic ones, and the larvae they produce die before full development. Thus, depending on which nuclear genotype they have, A. tabida females depend on Wolbachia either because they fail to produce any oocyte or because the few oocytes they do produce generate unviable offspring. We discuss the implications of these findings for the understanding of the physiological and genetic deficiency of aposymbiotic females.     

Targeting modular polyketide synthases with iteratively acting acyltransferases from metagenomes of uncultured bacterial consortia

Bacterial type I polyketide synthases (PKSs) produce a wide range of biomedically important secondary metabolites. These enzymes possess a modular structure that can be genetically re-engineered to yield novel drug candidates not found in nature. Recently, we have reported the putative pederin PKS from an uncultured bacterial symbiont of Paederus fuscipes beetles. It belongs to an architecturally unusual PKS group, the members of which contain iteratively acting acyltransferases that are not integrated into the PKS modules but are encoded by isolated genes. As these systems are rare, often contain additional unusual features and are of smaller size than regular PKSs, the development of a method for the targeted isolation of new group members would be of great interest. Here, we present a phylogenetic approach to identify these systems rapidly in highly complex metagenomic DNA samples. To demonstrate its practical value, we located two pederin-type PKS systems putatively involved in the biosynthesis of antitumour polyketides in the metagenomic DNA of beetles, sponges and their uncultivated bacterial symbionts.     

Injection of essential amino acids substitutes for bacterial supply in aposymbiotic pea aphids (Acyrthosiphon pisum)

The symbiotic bacteria Buchnera contribute to the nutrition of pea aphids, Acyrthosiphon pisum, through the provision of essential amino acids which are lacking in the diet. However, chemically defined diets, containing nutritionally adequate amounts of essential amino acids, fail to rescue aposymbiotic aphids, in which the bacteria have been disrupted with antibiotics. In this study the injection of a mixture of essential amino acids into the haemocoel of aposymbiotic aphids was shown to alleviate, at least partially, the impact of symbiont loss. Specifically, the total amino acid content in the tissues of aposymbiotic aphids was reduced by approximately 40% to levels comparable with symbiotic insects, and there was a 1.7-fold increase in the number of embryos, suggesting that the availability of essential amino acids promotes aphid protein synthesis by rejuvenating the free amino acid pool of aposymbiotic aphids. In addition, a similar effect on the total amino acid content was observed when phenylalanine alone, but not glutamine, lysine or tryptophan, was injected into the haemocoel of aposymbiotic aphids, and there was also a significant increase in the number of embryos following injection of phenylalanine or tryptophan alone. The impact of amino acid injection on the embryo complement of aposymbiotic aphids was limited to an increase in the number of embryos, with no increase in basal embryo size. It is proposed that older embryos may rely on their own complement of symbiotic bacteria for essential amino acid provisioning. Taken together, the data highlight the importance of bacterial provisioning of essential amino acids, particularly the aromatic amino acids, in the intact symbiosis.     

The elimination of intracellular microorganisms from insects: an analysis of antibiotic-treatment in the pea aphid (Acyrthosiphon pisum)

Antibiotics are routinely used to eliminate intracellular prokaryotic microorganisms from a wide range of insect species, but concerns about deleterious effects of antibiotic therapy on the insect host are seldom addressed. Here, the impact of antibiotic therapy in the symbiosis between the pea aphid Acyrthosiphon pisum and bacteria of the genus Buchnera is reviewed. Antibiotic-treatment produces aposymbiotic (i.e. symbiont-free) aphids, but does not depress the mitochondrial complement, the assimilation of dietary amino acids or the incorporation of amino acids into protein in these insects and does not impair osmoregulation, feeding rate and the capacity to penetrate plant tissues. It is concluded that the general malaise associated with aposymbiotic aphids is not attributable to a direct effect of the antibiotic. However, an important implication of this study is that aposymbiotic insects exhibit substantial metabolic adjustments to loss of the symbiosis; they are not simply aphids from which the symbiotic bacteria have been removed.     

The etiological agent of cytoplasmic incompatibility in Culex pipiens

All individuals of Culex pipiens (wide sense) which have been examined were infected with Wolbachia pipientis. Larvae reared in tetracycline were freed of these symbiotes and remained free (aposymbiotic) in future generations. When males were freed of their symbiotes, they no longer displayed incompatibility. Aposymbiotic males were compatible with all females, whether infected or not. Aposymbiotic females, on the other hand, laid fertile eggs after mating with aposymbiotic males, but not after mating with normal males. Most eggs laid by aposymbiotic females after mating with normal males showed no development at all, even though the females had been inseminated.     

Symbiosis initiation in the bacterially luminous sea urchin cardinalfish Siphamia versicolor

To determine how each new generation of the sea urchin cardinalfish Siphamia versicolor acquires the symbiotic luminous bacterium Photobacterium mandapamensis, and when in its development the S. versicolor initiates the symbiosis, procedures were established for rearing S. versicolor larvae in an aposymbiotic state. Under the conditions provided, larvae survived and developed for 28 days after their release from the mouths of males. Notochord flexion began at 8 days post release (dpr). By 28 dpr, squamation was evident and the caudal complex was complete. The light organ remained free of bacteria but increased in size and complexity during development of the larvae. Thus, aposymbiotic larvae of the fish can survive and develop for extended periods, major components of the luminescence system develop in the absence of the bacteria and the bacteria are not acquired directly from a parent, via the egg or during mouth brooding. Presentation of the symbiotic bacteria to aposymbiotic larvae at 8-10 dpr, but not earlier, led to initiation of the symbiosis. Upon colonization of the light organ, the bacterial population increased rapidly and cells forming the light-organ chambers exhibited a differentiated appearance. Therefore, the light organ apparently first becomes receptive to colonization after 1 week post-release development, the symbiosis is initiated by bacteria acquired from the environment and bacterial colonization induces morphological changes in the nascent light organ. The abilities to culture larvae of S. versicolor for extended periods and to initiate the symbiosis in aposymbiotic larvae are key steps in establishing the experimental tractability of this highly specific vertebrate and microbe mutualism.     

Nutrient availability for zooxanthellae derived from physiological activities of Condylactus spp

Differences in phosphate metabolism of symbiotic and aposymbiotic Condylactus suggest that the host animal makes available quantities of phosphate to support growth of zooxanthellae. Nitrite may serve as a nitrogen source for symbionts as indicated by host removal of nitrite from sea water.The presence of zooxanthellae is responsible for removal of phosphate from sea water in the dark whereas there is excretion during light periods. There is a greater uptake of nitrite from sea water in the light compared with the dark in symbiotic animals.Since nitrate is removed from sea water by aposymbiotic animals, the presence of nitrate reducing bacteria is proposed.     

Gill filament differentiation and experimental colonization by symbiotic bacteria in aposymbiotic juveniles of Codakia orbicularis (Bivalvia: Lucinidae)

Summary

Codakia orbicularis is a tropical lucinid harboring gill endosymbionts which are environmentally transmitted from a free living-symbiont form to the new host generation after metamorphosis. Structural changes occurring in the cellular organization from incomplete gill filaments in young aposymbiotic juveniles to full differentiated gill filaments containing bacterial endosymbionts in reared symbiotic juveniles, were analyzed for juveniles from 250 μm to 2 μm shell-length. Aposymbiotic juveniles possess differentiated gill filaments with ciliated, intermediary, and lateral zones similar to those described in wild juveniles, except for the bacteriocytes which are lacking. Granule cells, which progressively differentiate during the morphogenesis of the gill filament, do not appear as a consequence of symbiosis. Experimental colonization of aposymbiotic juveniles by the free-living symbiont form has been obtained through the addition of unsterilized sand collected from the natural habitat of C. orbicularis. Two days after exposure to crude sand, symbiosis-competent bacteria enter by endocytosis at the apical pole of undifferentiated cells which progressively differentiate into classical bacteriocytes similar to those found in the adult gill filaments. Undifferentiated cells of aposymbiotic gill filaments remain receptive to bacteria several months after metamorphosis, and become bacteriocytes when aposymbiotic juveniles get contact with the symbiont free-living form. Therefore, the environmental transmission of symbionts does not appear to be restrained to a defined period of time during post-larval development in C. orbicularis.     

Viability of Culex pipiens pipiens eggs affected by nutrition and aposymbiosis

Raisins were a better source of carbohydrate than sucrose for reproduction by autogenous Culex pipiens. A blood meal increased the number of eggs per raft from 49 autogenously to 114. Eggs of aposymbiotic females produced autogenously did not hatch, but 34% of the eggs were viable if the mosquitoes fed on chickens. With repeated blood meals the number of eggs per raft and the rate of embryonation and hatching declined in each successive gonotrophic cycle. In about $\text{1}\text{4}$ of the unhatched eggs of normal females there were no fully developed embryos, while many more of the unhatched eggs of aposymbiotic females contained no evidence of embryonic development. After the fifth blood meal, neither normal nor aposymbiotic insects oviposited. The ovaries of the nulliparous females contained approximately 10% of the potential number of mature terminal oocytes. Proximally in the ovarioles there were dilatations and coiled tracheoles indicating egg resorption. There were fewer parous follicles in aposymbiotic than in normal females. Larval rearing water, i.e., infusion in which larvae had been reared, was more attractive than fresh infusion for oviposition by normal, autogenous mosquitoes. The degree of embryonation of the eggs was lower and the hatching success rate was poorer in fresh infusion than in larval rearing water.     

Body size and symbiotic status influence gonad development in <Emphasis Type="Italic">Aiptasia pallida</Emphasis> anemones

Pale anemones (Aiptasia pallida) coexist with dinoflagellates (primarily Symbiodinium minutum) in a mutualistic relationship. The purpose of this study was to investigate the role of these symbionts in gonad development of anemone hosts. Symbiotic and aposymbiotic anemones were subjected to light cycles that induced gametogenesis. These anemones were then sampled weekly for nine weeks, and gonad development was analyzed histologically. Anemone size was measured as mean body column diameter, and oocytes or sperm follicles were counted for each anemone. Generalized linear models were used to evaluate the influence of body size and symbiotic status on whether gonads were present and on the number of oocytes or sperm follicles produced. Body size predicted whether gonads were present, with larger anemones being more likely than smaller anemones to develop gonads. Both body size and symbiotic status predicted gonad size, such that larger and symbiotic anemones produced more oocytes and sperm follicles than smaller and aposymbiotic anemones. Overall, only 22 % of aposymbiotic females produced oocytes, whereas 63 % of symbiotic females produced oocytes. Similarly, 6 % of aposymbiotic males produced sperm follicles, whereas 60 % of symbiotic males produced sperm follicles. Thus, while gonads were present in 62 % of symbiotic anemones, they were present in only 11 % of aposymbiotic anemones. These results indicate that dinoflagellate symbionts influence gonad development and thus sexual maturation in both female and male Aiptasia pallida anemones. This finding substantiates and expands our current understanding of the importance of symbionts in the development and physiology of cnidarian hosts.     

Comparison of sarcosine and methionine sulfoxide levels in symbiotic and aposymbiotic larvae of two sibling species,Sitophilus oryzae L. and S. zeamais mots. (Coleoptera: Curculionidae)

Sarcosine and methionine sulfoxide were investigated in several wild or laboratory-reared symbiotic and aposymbiotic strains of Sitophilus oryzae and S. zeamais. The amino acid composition of fourth-instar larvae indicated that a high level in sarcosine found together with a low level of methionine sulfoxide were biochemical characteristics of the aposymbiotic state in this genus. Nutritional experiments demonstrated that the synthesis of these two amino acids depended on dietary precursors. Since sarcosine and methionine sulfoxide are both methionine derivatives, it is therefore suggested that methionine metabolism in Sitophilus larvae might differ according to the presence or the absence of the symbiotic bacteria.