CHEMOTAXIS RESPONSE OF PHASMARHABDITIS CALIFORNICA (FAMILY: RHABDITIDAE) AND PRISTIONCHUS ENTOMOPHAGUS (FAMILY: NEODIPLOGASTERIDAE) TO THE MUCUS OF FOUR SLUG SPECIES.

The chemotaxis responses of soil nematodes have been well studied in bacteriophagic nematodes, plant-parasitic nematodes, entomopathogenic nematodes, and to a lesser extent malacopathogenic nematodes. Free-living stages of parasitic nematodes often use chemotaxis to locate hosts. In this study, we compared the chemotaxis profile of 2 slug-associated nematodes with overlapping host ranges. Phasmarhabditis californica is a facultative parasite that has been shown to express strain-dependent variation in chemoattraction profile. We tested 4 slug species to determine the attraction index of a Canadian strain of Ph. californica and a sympatric necromenic nematode, Pristionchus entomophagus. When tested against a control (distilled water), Ph. californica showed a clear (positive) attraction towards the mucus of slugs Ambigolimax valentianus, Arion rufus, and Arion fasciatus, but not Deroceras reticulatum. However, when given a choice between the mucus of D. reticulatum and Ar. fasciatus in a pairwise test, Ph. californica was strongly attracted to the former. Other pairwise comparisons did not reveal a clear preference for either slug species in the following pairs: D. reticulatum-Ar. rufus, Am. valentianus-Ar. rufus, D. reticulatum-Am. valentianus. The chemotaxis assay for Pr. entomophagus showed an attraction toward D. reticulatum and Ar. fasciatus (tested against controls); the attraction index for Am. valentianus was positive, but this was not statistically significant. In contrast, the attraction index for Ar. rufus was negative, suggesting possible repulsion to the mucus of this slug species. Given that Pr. entomophagus and Ph. californica occupy overlapping habitats, utilize similar hosts, and exhibit similar chemotaxis profiles, there is a potential for direct interaction between these 2 nematodes. Like other members of the genus Pristionchus, Pr. entomophagus may be able to prey upon the co-occurring Ph. californica, such antagonistic interactions could have important implications for the coexistence of these 2 species and Ph. californica in particular as a biocontrol agent against pestiferous slugs.

Parasites and the ecology of fear: Nonconsumptive effects of ectoparasites on larvae reduce growth in simulated Drosophila populations.

Predators negatively affect prey outside of direct attack, and these nonconsumptive effects (NCEs) may cause over half the impacts of predators on prey populations. This "ecology of fear" framework has been extended to host-parasite interactions. The NCEs of parasites are thought to be small relative to those of predators. However, recent research shows ectoparasites exert NCEs on multiple life stages of Drosophila. In this study, we apply recent data to a matrix-based model of fly populations experiencing infection/consumption and NCEs from an ectoparasitic mite. We found the NCEs of parasites on larvae, which are not actively parasitized, decreased the size of simulated host populations. By contrast, the NCEs on adult flies increased population size through compensatory egg production. The negative NCEs on larvae outweighed the positive effects on adults to reduce population size. This study suggests that parasitic NCEs can suppress host populations independent of infection.

PHASMARHABDITIS CALIFORNICA (NEMATODA: RHABDITIDAE) HAS REDUCED ESTABLISHMENT SUCCESS AND PROGENY PRODUCTION IN THE PRESENCE OF PRISTIONCHUS ENTOMOPHAGUS (NEMATODA: DIPLOGASTRIDAE).

Phasmarhabditis (syn. Pellioditis) californica is a facultative parasite that has been marketed as a popular biocontrol agent against pestiferous slugs in England, Scotland, and Wales. The necromenic nematode Pristionchus entomophagus has also been recovered from slugs infected with Ph. californica. In this study, we experimentally investigated the outcome of single and mixed applications of Pr. entomophagus and Ph. californica on the slug Deroceras reticulatum (Müller). Host mortality was comparable for single and mixed applications of Ph. californica, with time to death significantly shorter in both treatment groups compared with controls. However, trials with Pr. entomophagus alone did not cause any significant host mortality relative to controls. Compared with the single Ph. californica applications, mixed applications resulted in 67% fewer infective juveniles establishing in the host, and subsequently far fewer infective juveniles were recovered in the next generation. In contrast, the establishment rate and progeny production in Pr. entomophagus were not impacted by the presence of Ph. californica (i.e., mixed applications). Hence, the presence of Pr. entomophagus had a deleterious effect on the establishment success and progeny production of Ph. californica. Our findings reveal an asymmetrical, antagonistic interaction between Ph. californica and Pr. entomophagus and highlight the importance of understanding the ecological relationships between co-occurring species. A decrease in parasite establishment success and progeny production has the potential to directly impact the persistence, sustainability, and efficacy of Ph. californica as a biological control agent.

A tale of two parasites: Responses of honey bees infected with Nosema ceranae and Lotmaria passim.

Nosema ceranae and Lotmaria passim are two commonly encountered digestive tract parasites of the honey bee that have been associated with colony losses in Canada, the United States, and Europe. Though honey bees can be co-infected with these parasites, we still lack basic information regarding how they impact bee health at the individual and colony level. Using locally-isolated parasite strains, we investigated the effect of single and co-infections of these parasites on individual honey bee survival, and their responsiveness to sucrose. Results showed that a single N. ceranae infection is more virulent than both single L. passim infections and co-infections. Honey bees singly infected with N. ceranae reached < 50% survival eight days earlier than those inoculated with L. passim alone, and four days earlier than those inoculated with both parasites. Honey bees infected with either one, or both, parasites had increased responsiveness to sucrose compared to uninfected bees, which could correspond to higher levels of hunger and increased energetic stress. Together, these findings suggest that N. ceranae and L. passim pose threats to bee health, and that the beekeeping industry should monitor for both parasites in an effort correlate pathogen status with changes in colony-level productivity and survival.