Infective juveniles of entomopathogenic nematodes (Steinernema and Heterorhabditis) secrete ascarosides and respond to interspecific dispersal signals

Hartley, Cathryn J.; Lillis, Peter E.; Owens, Rebecca A.; Griffin, Christine T.

doi:10.1016/j.jip.2019.107257

Cited by 21 publications

(14 citation statements)

References 43 publications

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“…Consistent with the literature, Hartley et al 39 showed that as the ascaroside content increases during storage and overall nematode dispersal was reduced from 1 to 3 weeks. When the IJs are exposed to one week-storage medium associated with high dispersal, it stimulates the IJ dispersal as expected 39 . However, the 3-week storage medium with lower dispersal activity has a different ascaroside composition.…”

Section: Conclusion and Discussionsupporting

confidence: 70%

“…In this study, S. carpocapsae IJs responded to pheromone extracts from consumed insect host cadavers of 8 different species of Steinernema and Heterorhabditis regardless of their foraging strategies. The literature and our current findings suggest that the pheromone mixtures have not diverged to the point where they are species specific 22,39,48 . However, the precise pheromone mix for each species remains to be discovered.…”

Section: Conclusion and Discussionsupporting

confidence: 50%

“…Ascarosides play a key role in EPN development and behaviors 22,29,[37][38][39][40][41] including preventing the recovery of IJs (analogous to the dauer stage in C. elegans), emergence from host cadavers after food depletion, and dispersal behavior after IJs emerge from the host 22,29 . While their significance is known, the specific compounds produced within an EPN system and their effects on behavior vary.…”

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confidence: 99%

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Conspecific and heterospecific pheromones stimulate dispersal of entomopathogenic nematodes during quiescence

Kaplan¹,

Perret-Gentil

Giurintano

et al. 2020

Sci Rep

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Ascaroside pheromones stimulate dispersal, a key nematode behavior to find a new food source. Ascarosides produced by entomopathogenic nematodes (EPNs) drive infective juvenile (IJ) emergence from consumed cadavers and dispersal in soil. Without ascarosides from host cadavers, Steinernema feltiae (EPN) reduce dispersal substantially. To determine whether other Steinernema spp. exhibit the same behavior, we compared S. feltiae and S. carpocapsae IJs without host cadaver pheromones. Unlike S. feltiae, S. carpocapsae IJs continued to disperse. However, S. carpocapsae IJs exhibited a temperature-dependent quiescent period. The IJ quiescent period increased at ≤20 °C but did not appear at ≥25 °C. Consistent with this, S. carpocapsae IJ quiescence increased from 30 min to 24 h at ≤20 °C over 60 days. The quiescent period was overcome by dispersal pheromone extracts of their own, other Steinernema spp. and Heterorhabditis spp. Furthermore, S. carpocapsae IJ ambush foraging associated behaviors (tail standing, waving, and jumping) were unaffected by the absence or presence of host cadaver pheromones. For S. feltiae, IJ dispersal declined at all temperatures tested. Understanding the interaction between foraging strategies and pheromone signals will help uncover molecular mechanisms of host seeking, pathogenicity and practical applications to improve the EPN's efficacy as biocontrol agents. Dispersing and host-finding are important behaviors for parasites' success; finding a new host involves emergence from the host, dispersal, and foraging for a new host. A combination of intrinsic chemical drivers and extrinsic cues associated with potential hosts drives dispersal, searching behaviors and infection decisions. Local environmental conditions also affect parasites' success. For example, for soil-associated parasites these environmental factors include soil type, soil moisture, salinity, and temperature, among others. Entomopathogenic nematodes (EPN) in the genera Heterorhabditis and Steinernema are insect parasites used as model organisms to study the biology of parasites 1,2. Since they kill insects, they also have commercial applications for controlling insect pests as biocontrol agents 3-5. Once EPNs consume an insect host a specialized non-developmental life stage, called the infective juvenile (IJ), emerges from the spent host and disperses to search for a new host. The IJs carry tens to hundreds of symbiotic bacteria cells (Xenorhabdus spp. for Steinernema spp. nematodes and Photorhabdus spp. for Heterorhabditis spp. nematodes). Once a host has been infected by multiple IJs, the nematodes resume development, release their symbiotic bacteria, feed on the bacteria, and one to three generations develop within a single host over a 10 to 22-day period. When nutritional quality declines and waste products increase, IJs once again develop and emerge from the host. The EPN IJ host finding process

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Section: Conclusion and Discussionsupporting

confidence: 70%

Section: Conclusion and Discussionsupporting

confidence: 50%

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confidence: 99%

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Conspecific and heterospecific pheromones stimulate dispersal of entomopathogenic nematodes during quiescence

Kaplan¹,

Perret-Gentil

Giurintano

et al. 2020

Sci Rep

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“…Therefore, the accumulation of the ascaroside signal effectively functions to counteract the IJ recovery activity of the bacteria-derived IPS molecule, thus allowing the nematode to halt reproduction in a nematode population-dependent manner. Indeed, it appears that, similar to what has been reported in C. elegans, Heterorhabditis nematodes produce a range of ascaroside-like molecules that can regulate both nematode development and behaviour [124][125][126]. However, it remains to be seen if Photorhabdus makes any contribution to the production and/or modification of these, or any other, nematode-derived signals.…”

Section: The Nematode Contribution To Pathogenicity and Mutualismmentioning

confidence: 72%

Photorhabdus: a tale of contrasting interactions

Clarke

2020

Microbiology

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Different model systems have, over the years, contributed to our current understanding of the molecular mechanisms underpinning the various types of interaction between bacteria and their animal hosts. The genus Photorhabdus comprises Gram-negative insect pathogenic bacteria that are normally found as symbionts that colonize the gut of the infective juvenile stage of soil-dwelling nematodes from the family Heterorhabditis. The nematodes infect susceptible insects and release the bacteria into the insect haemolymph where the bacteria grow, resulting in the death of the insect. At this stage the nematodes feed on the bacterial biomass and, following several rounds of reproduction, the nematodes develop into infective juveniles that leave the insect cadaver in search of new hosts. Therefore Photorhabdus has three distinct and obligate roles to play during this life-cycle: (1) Photorhabdus must kill the insect host; (2) Photorhabdus must be capable of supporting nematode growth and development; and (3) Photorhabdus must be able to colonize the gut of the next generation of infective juveniles before they leave the insect cadaver. In this review I will discuss how genetic analysis has identified key genes involved in mediating, and regulating, the interaction between Photorhabdus and each of its invertebrate hosts. These studies have resulted in the characterization of several new families of toxins and a novel inter-kingdom signalling molecule and have also uncovered an important role for phase variation in the regulation of these different roles.

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“…Recent research has shown a commonality in the production of and sensitivity to ascaroside pheromones among free-living, plantparasitic, and insect-parasitic nematode species (Choe et al, 2012). Given that these small signaling molecules coordinate development, can have multi-trophic effects (Noguez et al, 2012;Hsueh et al, 2013;Zhao et al, 2016), and affect social behaviors (Hartley et al, 2019;Kaplan et al, 2020;Meng et al, 2020), it follows that they may be involved in trail following, particularly for species where individuals would face challenges to their reproductive success without signals to attract potential mates. However, the implication of ascarosides here is speculative and needs careful analysis of chemicals involved.…”

Section: Discussionmentioning

confidence: 99%

Nematodes Follow a Leader

et al. 2021

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Aggregated movement and population structure are known in entomopathogenic nematodes, which are obligate insect parasites. Aggregation behavior in the absence of external stimuli suggests communication among individuals, often in the form of trail-following, which has not been shown by nematodes of any kind. Interactions among individuals are an essential basis of following behaviors and can have significant fitness consequences. We explored intraspecific and interspecific interactions among three Steinernema species (S. glaseri, S. carpocapsae, and S. feltiae) in terms of trail following, and fitness outcomes of following heterospecific individuals. We found that the following behavior is context dependent. Following behavior among conspecifics was significantly increased when the lead nematode had prior contact with host cuticle. However, we did not find a clear association between the following response to heterospecific IJs and their reproductive success in a co-infected host.

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Infective juveniles of entomopathogenic nematodes (Steinernema and Heterorhabditis) secrete ascarosides and respond to interspecific dispersal signals

Cited by 21 publications

References 43 publications

Conspecific and heterospecific pheromones stimulate dispersal of entomopathogenic nematodes during quiescence

Conspecific and heterospecific pheromones stimulate dispersal of entomopathogenic nematodes during quiescence

Photorhabdus: a tale of contrasting interactions

Nematodes Follow a Leader

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