Induced Release of a Plant-Defense Volatile ‘Deceptively’ Attracts Insect Vectors to Plants Infected with a Bacterial Pathogen

Mann, Rajinder S.; Ali, Jared G.; Hermann, Sara L.; Tiwari, Siddharth; Pelz‐Stelinski, Kirsten S.; Alborn, Hans T.; Stelinski, Lukasz L.

doi:10.1371/journal.ppat.1002610

Cited by 261 publications

(358 citation statements)

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“…For example, Tomato spotted wilt virus augments the frequency of all feeding behaviors in infected males of its thrips vector (Stafford et al, 2011), and Candidatus Liberibacter asiaticus makes the odor of infected citrus plants initially more attractive for its psyllid vector but then, after virus acquisition, causes psyllids to disperse to non-infected plants (Mann et al, 2012). Similarly, Tomato yellow leaf curl virus enhances the attractiveness of infected tomato plants to virus-free whiteflies (B. tabaci), whereas infected whiteflies lose the capacity to distinguish between infected and healthy host plants (Fang et al, 2013).…”

Section: "Fatal Attraction" When the Host Is A Plantmentioning

confidence: 99%

“…Indeed, differing persistence times might be a major explanation for the observation that manipulation effects are more frequently reported for intermediate than for final hosts, at least as long as all hosts are animals (Holmes and Bethel, 1972). Plant pathogens, by contrast, require mobile vectors for their dispersal among their immobile final hosts and, therefore, frequently manipulate the quality of their host plant for the vectors (Belliure et al, 2010;Mauck et al, 2010Mauck et al, , 2014aLuan et al, 2013;Shi et al, 2013) as well as the feeding decisions that are taken by their vectors (Stafford et al, 2011;Ingwell et al, 2012;Mann et al, 2012;Fang et al, 2013;Rajabaskar et al, 2014). These changes can be very fine-tuned: for example, plant viruses with a persistent mode of transmission require vectors to feed for a prolonged period of time on infected hosts and, thus, usually tend to improve the quality of the host plants for the vectors.…”

Section: Why Don't All Parasites Manipulate?mentioning

confidence: 99%

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Host Manipulation by Parasites: Cases, Patterns, and Remaining Doubts

Heil

2016

Front. Ecol. Evol.

105

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Parasites must overcome host immunity and change hosts for dispersal. Therefore, seemingly odd behaviors of parasitized animals, like those exhibited by "Zombie ants" or the "fatal attraction" of mammals to their predators, have been explained as the extended phenotype of parasites that manipulate their hosts for transmission enhancement. Manipulation has evolved in all major phylogenetic lineages of parasites but is not ubiquitous. In fact, the real frequency and relevance of manipulation is still matter of debate. Here, I highlight some of the most pertinent questions that arise if we aim at a broader understanding of the ecological relevance and evolutionary trajectory of manipulating parasites. Why are more parasites with a trophic mode of transmission manipulating their host than horizontally transmitted parasites? Why are the causal agents of sexually transmitted diseases (STDs) so rarely reported to manipulate their host? Why do parasites of animals usually manipulate their intermediate host, whereas many pathogens of plants manipulate their final host and then cause a "fatal attraction" of herbivores to the already infected plant? How can we distinguish manipulation effects from adaptive host responses to parasitization? Does manipulation cause a cost to certain parasites that can select against the evolution of manipulation? More emphasis should be put on direct comparisons among parasites of animals, plants, and humans. Manipulation for transmission enhancement should be studied in concert with manipulation for host immunity suppression, the molecular mechanisms that control the manipulation effect need to be deciphered, and we should test for alternative explanations for the observed phenotypic changes. Finally, we should quantify transmission rates and net fitness for manipulating and non-manipulating parasites, in ecologically realistic setups, to identify the forces that select against the evolution of manipulation. Ultimately, parasite net fitness represents the relevant outcome of any manipulation effect.Keywords: immunity, malaria, partner manipulation, pathogen, plant-enemy interaction, STDs, toxoplasmosis "FATAL ATTRACTION" AND MANIPULATING PARASITES Parasites represent a ubiquitous aspect in the life of multicellular organisms (Wood and Johnson, 2015) and most, if not all, of us have experienced how strongly an infection can interfere with our normal activities and well-being. Therefore, it might not appear to be too surprising when parasitized hosts exhibit behavioral alterations (see Glossary) as compared to healthy conspecifics.

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Section: "Fatal Attraction" When the Host Is A Plantmentioning

confidence: 99%

Section: Why Don't All Parasites Manipulate?mentioning

confidence: 99%

Host Manipulation by Parasites: Cases, Patterns, and Remaining Doubts

Heil

2016

Front. Ecol. Evol.

105

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“…Mann et al (2012) demonstrated that infected Citrus sinensis plants emitted higher amounts of methyl salicylate, but less methyl anthranilate and Dlimonene than plants not infected by Candidatus Liberibacter asiaticus bacteria. Psyllid bugs (Diaphorina citri) initially chose infected plants but subsequently-after they became carriers of the pathogen-moved to non-infected plants.…”

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confidence: 99%

New Synthesis: A Holobiontic View on Plant-Insect Interactions

Junker

2014

J Chem Ecol

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A considerable proportion of the biomass of plants and animals consists of microbial cells, which when considered together with the host's cells, define the holobiont. The intimate and often obligate relationships between hosts and their associated microbes call into question traditional phyto-or zoocentric views on plant-insect interactions. Instead of considering only the plants' and/or animals' interests in ecological and evolutionary studies, it seems appropriate to ask whether and how the vested interests of their associated microbes, such as survival, proliferation and dispersal, are safeguarded when the macroscopic players interact. Recent findings show that microorganisms are not passive partners but manipulate either the sender or the receiver of signals and/or cues (or initiate signaling by themselves). Accordingly, for plant pathogens, the "host manipulation hypothesis" has been contrasted with the "vector manipulation hypothesis" that addresses either microbe-mediated changes in the plant's phenotype or changes in insect behavior, respectively (Ingwell et al. 2012). These effects could be generalized as a "sender or receiver manipulation hypothesis" in chemical plant-insect communication.Plant-associated microbes often induce changes in the chemical phenotype of plants or in the plants' responses to insect attacks. Mann et al. (2012) demonstrated that infected Citrus sinensis plants emitted higher amounts of methyl salicylate, but less methyl anthranilate and Dlimonene than plants not infected by Candidatus Liberibacter asiaticus bacteria. Psyllid bugs (Diaphorina citri) initially chose infected plants but subsequently-after they became carriers of the pathogen-moved to non-infected plants. This switch was presumably triggered by lower nutrient quality provided by the infected plants. While in this example the sender was manipulated, a study by Ingwell et al. (2012) reported on the manipulation of the receiver's behavioral response towards plant cues. Aphids (Rhopalosiphum padi) carrying the Barley yellow dwarf virus preferred healthy winter wheat plants, whereas aphids not serving as vectors chose plants that were already infected with the virus, which also differ in their volatile profiles compared with healthy plants (see references in Ingwell et al. 2012).The hologenome theory (Rosenberg and Zilber-Rosenberg 2011) proposes that the genetic information of the microbiome associated with a host changes with environmental conditions, affects the host's and the microbes' fitness and can be transmitted to subsequent generations. The studies mentioned above do not address all aspects required to align plantinsect-microbe tritrophic interactions with the hologenome theory. Furthermore, these studies involve plant pathogens, whose interests may not conform to Rosenberg's and Zilber-Rosenberg's definition (2011). Nevertheless, these studies offer some evidence consistent with the predictions of the theory: 1) the hosts provide a beneficial environment for the microorganisms; 2) the bacterial/viral genome i...

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“…The most important contributing factors to rapid spread of CLas by ACP are (A) the high dispersal potential of adult psyllids, which is facilitated by their good flight capabilities and small size, enabling them to be blown long distances by wind and go undetected on shipped plants and (B) rapid psyllid population growth, which results from short generation times and the high fecundity of females (Lewis-Rosenblum et al 2015). Additionally, uninfected psyllids are more attracted to CLas-infected trees than to uninfected trees, which may further facilitate rapid pathogen spread (Mann et al 2012). Thus, suppressing ACP populations is important for reducing CLas movement, which in turn maximizes orchard longevity and productivity.…”

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confidence: 99%