Patterns, causes and consequences of defensive microbiome dynamics across multiple scales

Smith, Andrew H.; Łukasik, Piotr; O’Connor, Michael; Lee, Amanda; Mayo, Garrett; Drott, Milton T.; Doll, Steven G.; Tuttle, R.N.; Disciullo, Rachael A.; Messina, Andrea; Oliver, Kerry M.; Russell, Jacob A.

doi:10.1111/mec.13095

Cited by 122 publications

(170 citation statements)

References 84 publications

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“…Alternative explanations for X-type maintenance include improved rates of vertical transmission in superinfections relative to single infections or frequent lateral transfer, but neither of these was supported in preliminary lab trials. While X-type appears to be an atypical case, superinfections are common in many insect species (8,10,52) and this hitchhiking strategy, or similar scenarios, may occur in other systems, even among conditional beneficial symbionts not under direct selection (e.g., coinfecting antifungal HFS spread with H. defensa under parasitism pressure [11]). Of course, confirming a purely exploitative hitchhiking status of symbionts will remain troublesome, due to the difficulty in "proving a negative," as there is always the possibility that the hitchhiker confers some unknown conditional benefit.…”

Section: Discussionmentioning

confidence: 99%

“…Moreover, individual hosts are often infected with multiple inherited symbionts and antagonistic or synergistic interactions between superinfecting symbionts may enhance or reduce mutualistic services or costs, influencing symbiont spread within the host population (8)(9)(10). Instances of heritable pathogens are expected to be exceedingly rare (1), yet under some conditions, a heritable symbiont that was neither providing conditional benefits nor manipulating host reproduction could spread by "hitchhiking" alongside a beneficial symbiont (11). A hitchhiking symbiont could be maintained in host populations even when superinfection causes harm to host fitness as long as the conditional benefits provided by the mutualist in the superinfection context outweigh these costs.…”

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confidence: 99%

“…This common HFS often infects up to 40% of individuals in some North American populations (8,11). Sequences of the X-type 16S rRNA gene place this HFS in the Enterobacteriaceae (Gammaproteobacteria), along with other aphid symbionts, including Buchnera and H. defensa, as well as notable human pathogens, such as Salmonella (25).…”

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confidence: 99%

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Aphid Heritable Symbiont Exploits Defensive Mutualism

Doremus

Oliver

2017

Appl Environ Microbiol

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Insects and other animals commonly form symbioses with heritable bacteria, which can exert large influences on host biology and ecology. The pea aphid, Acyrthosiphon pisum, is a model for studying effects of infection with heritable facultative symbionts (HFS), and each of its seven common HFS species has been reported to provide resistance to biotic or abiotic stresses. However, one common HFS, called X-type, rarely occurs as a single infection in field populations and instead typically superinfects individual aphids with Hamiltonella defensa, another HFS that protects aphids against attack by parasitic wasps. Using experimental aphid lines comprised of all possible infection combinations in a uniform aphid genotype, we investigated whether the most common strain of X-type provides any of the established benefits associated with aphid HFS as a single infection or superinfection with H. defensa. We found that X-type does not confer protection to any tested threats, including parasitoid wasps, fungal pathogens, or thermal stress. Instead, component fitness assays identified large costs associated with X-type infection, costs which were ameliorated in superinfected aphids. Together these findings suggest that X-type exploits the aphid/H. defensa mutualism and is maintained primarily as a superinfection by "hitchhiking" via the mutualistic benefits provided by another HFS. Exploitative symbionts potentially restrict the functions and distributions of mutualistic symbioses with effects that extend to other community members.IMPORTANCE Maternally transmitted bacterial symbionts are widespread and can have major impacts on the biology of arthropods, including insects of medical and agricultural importance. Given that host fitness and symbiont fitness are tightly linked, inherited symbionts can spread within host populations by providing beneficial services. Many insects, however, are frequently infected with multiple heritable symbiont species, providing potential alternative routes of symbiont maintenance. Here we show that a common pea aphid symbiont called X-type likely employs an exploitative strategy of hitchhiking off the benefits of a protective symbiont, Hamiltonella. Infection with X-type provides none of the benefits conferred by other aphid symbionts and instead results in large fitness costs, costs lessened by superinfection with Hamiltonella. These findings are corroborated by natural infections in field populations, where X-type is mostly found superinfecting aphids with Hamiltonella. Exploitative symbionts may be common in hosts with communities of heritable symbionts and serve to hasten the breakdown of mutualisms.KEYWORDS Hamiltonella defensa, PAXS, entomopathogenic fungi, heat stress, heritable symbionts, parasitoids, pea aphid resistance H eritable bacterial symbionts are ubiquitous in arthropod species, especially insects occupying terrestrial ecosystems (1). These heritable symbionts are usually maternally transmitted and cannot survive outside host tissues and consequently have limited s...

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

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Aphid Heritable Symbiont Exploits Defensive Mutualism

Doremus

Oliver

2017

Appl Environ Microbiol

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“…; Smith et al . ). For example, the symbiont Serratia symbiotica protects its host against heat shock and is found at highest frequency in hot environments (Montllor, Maxmen & Purcell ; Henry et al .…”

Section: Introductionmentioning

confidence: 97%

Symbionts modify interactions between insects and natural enemies in the field

Hrček

McLean

Godfray

2016

Journal of Animal Ecology

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Summary Eukaryotes commonly host communities of heritable symbiotic bacteria, many of which are not essential for their hosts' survival and reproduction. There is laboratory evidence that these facultative symbionts can provide useful adaptations, such as increased resistance to natural enemies. However, we do not know how symbionts affect host fitness when the latter are subject to attack by a natural suite of parasites and pathogens.Here, we test whether two protective symbionts, Regiella insecticola and Hamiltonella defensa, increase the fitness of their host, the pea aphid (Acyrthosiphon pisum), under natural conditions.We placed experimental populations of two pea aphid lines, each with and without symbionts, in five wet meadow sites to expose them to a natural assembly of enemy species. The aphids were then retrieved and mortality from parasitoids, fungal pathogens and other causes assessed.We found that both Regiella and Hamiltonella reduce the proportion of aphids killed by the specific natural enemies against which they have been shown to protect in laboratory and cage experiments. However, this advantage was nullified (Hamiltonella) or reversed (Regiella) by an increase in mortality from other natural enemies and by the cost of carrying the symbiont. Symbionts therefore affect community structure by altering the relative success of different natural enemies.Our results show that protective symbionts are not necessarily advantageous to their hosts, and may even behave more like parasites than mutualists. Nevertheless, bacterial symbionts may play an important role in determining food web structure and dynamics.

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“…Facultative symbiont coinfections are common in aphids and X-type is rarely found in single infections [30,31]. The presence of a second symbiont potentially changes the phenotypic effect seen in a single infection, possibly because two symbionts consume more resources [22].…”

Section: Introductionmentioning

confidence: 99%

Heat Stress Affects Facultative Symbiont-Mediated Protection from a Parasitoid Wasp

Heyworth

Ferrari

2016

PLoS ONE

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Many insects carry facultative bacterial symbionts, which provide benefits including resistance to natural enemies and abiotic stresses. Little is known about how these beneficial phenotypes are affected when biotic or abiotic threats occur simultaneously. The pea aphid (Acyrthosiphon pisum) can host several well-characterized symbiont species. The symbiont known as X-type can protect against both parasitoid wasps and heat stress. Here, we used three pea aphid genotypes that were naturally infected with X-type and the symbiont Spiroplasma sp. We compared aphids coinfected with these two symbionts with those cured from X-type and infected with only Spiroplasma to investigate the ability of X-type to confer benefits to the host when two threats are experienced simultaneously. Our aim is to explore how robust symbiont protection may be outside a benign laboratory environment. Aphids were subjected to heat shock either before or after attack by parasitoid wasps. Under a benign temperature regime, the aphids carrying X-type tended to be better protected from the parasitoid than those cured. When the aphids experienced a heat shock before being parasitized aphids carrying X-type were more susceptible than those cured. Regardless of infection with the symbiont, the aphids benefitted from being heat shocked after parasitization. The results demonstrate how resistance to parasitoid wasps can be strongly environment-dependent and that a beneficial phenotype conferred by a symbiont under controlled conditions in the laboratory does not necessarily equate to a consistently useful effect in natural populations.

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Patterns, causes and consequences of defensive microbiome dynamics across multiple scales

Cited by 122 publications

References 84 publications

Aphid Heritable Symbiont Exploits Defensive Mutualism

Aphid Heritable Symbiont Exploits Defensive Mutualism

Symbionts modify interactions between insects and natural enemies in the field

Heat Stress Affects Facultative Symbiont-Mediated Protection from a Parasitoid Wasp

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