This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Baiocchi, T., Li, C. and Dillman, A. R. 2020. EPNs exhibit repulsion to prenol in pluronic gel assays. Insects 118:457.BaiocchiT.LiC. and DillmanA. R.2020. EPNs exhibit repulsion to prenol in pluronic gel assays. 118:457.10.3390/insects11080457746894832707750Search in Google Scholar
Boff, M. I. C. and Smits, P. H. 2001. Effects of density, age and host cues on the dispersal of Heterorhabditis megidis. Biocontrol Science and Technology 114:505–514.BoffM. I. C. and SmitsP. H.2001. Effects of density, age and host cues on the dispersal of Heterorhabditis megidis. 114:505–514.10.1080/09583150120067535Search in Google Scholar
Boff, M. I., Zoon, F. C. and Smits, P. H. 2001. Orientation of Heterorhabditis megidis to insect hosts and plant roots in a Y-tube sand olfactometer. Entomologia Experimentalis et Applicata 983:329–337.BoffM. I.ZoonF. C. and SmitsP. H.2001. Orientation of Heterorhabditis megidis to insect hosts and plant roots in a Y-tube sand olfactometer. 983:329–337.10.1046/j.1570-7458.2001.00789.xSearch in Google Scholar
De Brida, A. L., Rosa, J. M. O., De Oliveira, C. M. G., de Castro e Castro, B. M., Serrão, J. E., Zanuncio, J. C., Leite, L. G. and Wilcken, S. R. S. 2017. Entomopathogenic nematodes in agricultural areas in Brazil. Scientific Reports 7:45254.De BridaA. L.RosaJ. M. O.De OliveiraC. M. G.de Castro e CastroB. M.SerrãoJ. E.ZanuncioJ. C.LeiteL. G. and WilckenS. R. S.2017. Entomopathogenic nematodes in agricultural areas in Brazil. 7:45254.10.1038/srep45254538277228382937Search in Google Scholar
Denno, R. F., Gruner, D. S. and Kaplan, I. 2008. Potential for entomopathogenic nematodes in biological control: a meta-analytical synthesis and insights from trophic cascade theory. Journal of Nematology 402:61–72.DennoR. F.GrunerD. S. and KaplanI.2008. Potential for entomopathogenic nematodes in biological control: a meta-analytical synthesis and insights from trophic cascade theory. 402:61–72.Search in Google Scholar
El-Borai, F. E., Campos-Herrera, R., Stuart, R. J. and Duncan, L. W. 2011. Substrate modulation, group effects and the behavioral responses of entomopathogenic nematodes to nematophagous fungi. Journal of Invertebrate Pathology 106:347–356.El-BoraiF. E.Campos-HerreraR.StuartR. J. and DuncanL. W.2011. Substrate modulation, group effects and the behavioral responses of entomopathogenic nematodes to nematophagous fungi. 106:347–356.10.1016/j.jip.2010.12.00121145324Search in Google Scholar
Georgis, R., Koppenhöfer, A. M., Lacey, L. A., Bélair, G., Duncan, L. W., Grewal, P. S., Samish, M., Tan, L., Torr, P. and Van Tol, R. H. W. M. 2006. Successes and failures in the use of parasitic nematodes for pest control. Biological Control 381:103–123.GeorgisR.KoppenhöferA. M.LaceyL. A.BélairG.DuncanL. W.GrewalP. S.SamishM.TanL.TorrP. and Van TolR. H. W. M.2006. Successes and failures in the use of parasitic nematodes for pest control. 381:103–123.10.1016/j.biocontrol.2005.11.005Search in Google Scholar
Grewal, P. S., Gaugler, R. and Selvan, S. 1993. Host recognition by entomopathogenic nematodes: behavioral response to contact with host feces. Journal of Chemical Ecology 196:1219–1231.GrewalP. S.GauglerR. and SelvanS.1993. Host recognition by entomopathogenic nematodes: behavioral response to contact with host feces. 196:1219–1231.10.1007/BF0098738224249139Search in Google Scholar
Groot, A. T., Dekker, T. and Heckel, D. G. 2016. The genetic basis of pheromone evolution in moths. Annual Review of Entomology 61:99–117.GrootA. T.DekkerT. and HeckelD. G.2016. The genetic basis of pheromone evolution in moths. 61:99–117.10.1146/annurev-ento-010715-02363826565898Search in Google Scholar
Hartley, C. J., Lillis, P. E., Owens, R. A. and Griffin, C. T. 2019. Infective juveniles of entomopathogenic nematodes Steinernema and Heterorhabditis secrete ascarosides and respond to interspecific dispersal signals. Journal of Invertebrate Pathology 168:107257.HartleyC. J.LillisP. E.OwensR. A. and GriffinC. T.2019. Infective juveniles of entomopathogenic nematodes Steinernema and Heterorhabditis secrete ascarosides and respond to interspecific dispersal signals. 168:107257.10.1016/j.jip.2019.10725731634473Search in Google Scholar
Hiltpold, I., Jaffuel, G. and Turlings, T. C. 2015. The dual effects of root-cap exudates on nematodes: from quiescence in plant-parasitic nematodes to frenzy in entomopathogenic nematodes. Journal of Experimental Botany 662:603–611.HiltpoldI.JaffuelG. and TurlingsT. C.2015. The dual effects of root-cap exudates on nematodes: from quiescence in plant-parasitic nematodes to frenzy in entomopathogenic nematodes. 662:603–611.10.1093/jxb/eru345428640325165149Search in Google Scholar
Hofstetter, R. W., Gaylord, M. L., Martinson, S. and Wagner, M. R. 2012. Attraction to monoterpenes and beetle-produced compounds by syntopic Ips and Dendroctonus bark beetles and their predators. Agricultural and Forest Entomology 142:207–215.HofstetterR. W.GaylordM. L.MartinsonS. and WagnerM. R.2012. Attraction to monoterpenes and beetle-produced compounds by syntopic Ips and Dendroctonus bark beetles and their predators. 142:207–215.10.1111/j.1461-9563.2011.00560.xSearch in Google Scholar
Kaplan, F., Alborn, H. T., von Reuss, S. H., Ajredini, R., Ali, J. G., Akyazi, F., Stelinski, L. L., Edison, A. S., Schroeder, F. C. and Teal, P. E. 2012. Interspecific nematode signals regulate dispersal behavior. PloS one 7:e38735.KaplanF.AlbornH. T.von ReussS. H.AjrediniR.AliJ. G.AkyaziF.StelinskiL. L.EdisonA. S.SchroederF. C. and TealP. E.2012. Interspecific nematode signals regulate dispersal behavior. 7:e38735.10.1371/journal.pone.0038735336888022701701Search in Google Scholar
Kaplan, F., Perret-Gentil, A., Giurintano, J., Stevens, G., Erdogan, H., Schiller, K. C., Mirti, A., Sampson, E., Torres, C., Sun, J. and Lewis, E. E. 2020. Conspecific and heterospecific pheromones stimulate dispersal of entomopathogenic nematodes during quiescence. Scientific Reports 10:1–12.KaplanF.Perret-GentilA.GiurintanoJ.StevensG.ErdoganH.SchillerK. C.MirtiA.SampsonE.TorresC.SunJ. and LewisE. E.2020. Conspecific and heterospecific pheromones stimulate dispersal of entomopathogenic nematodes during quiescence. 10:1–12.10.1038/s41598-020-62817-y710902632235877Search in Google Scholar
Kin, K., Baiocchi, T. and Dillman, A. R. 2019. Dispersal and repulsion of entomopathogenic nematodes to prenol. Biology 83:58.KinK.BaiocchiT. and DillmanA. R.2019. Dispersal and repulsion of entomopathogenic nematodes to prenol. 83:58.10.3390/biology8030058678391231382480Search in Google Scholar
Kruitbos, L. M., Heritage, S., Hapca, S. M. and Wilson, M. J. 2010. The influence of habitat quality on the foraging strategies of the entomopathogenic nematodes Steinernema carpocapsae and Heterorhabditis megidis. Parasitology 1372:303–309.KruitbosL. M.HeritageS.HapcaS. M. and WilsonM. J.2010. The influence of habitat quality on the foraging strategies of the entomopathogenic nematodes Steinernema carpocapsae and Heterorhabditis megidis. 1372:303–309.10.1017/S003118200999132619835647Search in Google Scholar
Oliveira-Hofman, C., Kaplan, F., Stevens, G., Lewis, E., Wu, S., Alborn, H. T., Perret-Gentil, A. and Shapiro-Ilan, D. I. 2019. Pheromone extracts act as boosters for entomopathogenic nematodes efficacy. Journal of Invertebrate Pathology 164:38–42.Oliveira-HofmanC.KaplanF.StevensG.LewisE.WuS.AlbornH. T.Perret-GentilA. and Shapiro-IlanD. I.2019. Pheromone extracts act as boosters for entomopathogenic nematodes efficacy. 164:38–42.10.1016/j.jip.2019.04.00831034842Search in Google Scholar
Ram, K., Gruner, D. S., McLaughlin, J. P., Preisser, E. L. and Strong, D. R. 2008. Dynamics of a subterranean trophic cascade in space and time. Journal of Nematology 402:85–92.RamK.GrunerD. S.McLaughlinJ. P.PreisserE. L. and StrongD. R.2008. Dynamics of a subterranean trophic cascade in space and time. 402:85–92.Search in Google Scholar
Salmon, S., Rebuffat, S., Prado, S., Sablier, M., d’Haese, C., Sun, J. S. and Ponge, J. F. 2019. Chemical communication in springtails: a review of facts and perspectives. Biology and Fertility of Soils 55:425–438.SalmonS.RebuffatS.PradoS.SablierM.d’HaeseC.SunJ. S. and PongeJ. F.2019. Chemical communication in springtails: a review of facts and perspectives. 55:425–438.10.1007/s00374-019-01365-8Search in Google Scholar
San-Blas, E., Gowen, S. R. and Pembroke, B. 2008. Steinernema feltiae: ammonia triggers the emergence of their infective juveniles. Experimental Parasitology 1191:180–185.San-BlasE.GowenS. R. and PembrokeB.2008. Steinernema feltiae: ammonia triggers the emergence of their infective juveniles. 1191:180–185.10.1016/j.exppara.2008.01.00818316080Search in Google Scholar
Shapiro, D. I. and Glazer, I. 1996. Comparison of entomopathogenic nematode dispersal from infected hosts versus aqueous suspension. Environmental Entomology 25:1455–1461.ShapiroD. I. and GlazerI.1996. Comparison of entomopathogenic nematode dispersal from infected hosts versus aqueous suspension. 25:1455–1461.10.1093/ee/25.6.1455Search in Google Scholar
Shapiro, D. and Lewis, E. E. 1999. Infectivity of entomopathogenic nematodes from cadavers vs. aqueous applications. Environmental Entomology 28:907–911.ShapiroD. and LewisE. E.1999. Infectivity of entomopathogenic nematodes from cadavers vs. aqueous applications. 28:907–911.10.1093/ee/28.5.907Search in Google Scholar
Shapiro-Ilan, D. I., Lewis, E. E. and Son, Y. S. 2003. Superior efficacy observed in entomopathogenic nematodes applied in infected-host cadavers compared with application in aqueous suspension. Journal of Invertebrate Pathology 83:270–272.Shapiro-IlanD. I.LewisE. E. and SonY. S.2003. Superior efficacy observed in entomopathogenic nematodes applied in infected-host cadavers compared with application in aqueous suspension. 83:270–272.10.1016/S0022-2011(03)00101-0Search in Google Scholar
Shapiro-Ilan, D. I., Kaplan, F., Oliveira-Hofman, C., Schliekelman, P., Alborn, H. T. and Lewis, E. E. 2019.Search in Google Scholar
Shapiro, D. I., Lewis, E. E., Paramasivam, S. and McCoy, C. W. 2000. Nitrogen partitioning in Heterorhabditis bacteriophora-infected hosts and the effects of nitrogen on attraction/repulsion. Journal of Invertebrate Pathology 761:43–48.ShapiroD. I.LewisE. E.ParamasivamS. and McCoyC. W.2000. Nitrogen partitioning in Heterorhabditis bacteriophora-infected hosts and the effects of nitrogen on attraction/repulsion. 761:43–48.10.1006/jipa.2000.494410963402Search in Google Scholar
Spiridonov, S. E., Subbotin, S. A.2016. Phylogeny and phylogeography of Heterorhabditis and Steinernema Hunt, D. J. and Nguyen, K. B. Advances in Entomopathogenic Nematode Taxonomy and Phylogeny. Brill, Leiden, pp. 413–427.SpiridonovS. E.SubbotinS. A.2016. Phylogeny and phylogeography of Heterorhabditis and SteinernemaHuntD. J. and NguyenK. B.. Brill, Leiden, pp. 413–427.10.1163/9789004285347_007Search in Google Scholar
Symonds, M. R. and Elgar, M. A. 2008. The evolution of pheromone diversity. Trends in Ecology and Evolution 234:220–228.SymondsM. R. and ElgarM. A.2008. The evolution of pheromone diversity. 234:220–228.10.1016/j.tree.2007.11.00918308422Search in Google Scholar
White, G. F. 1927. A method for obtaining infective nematode larvae from cultures. Science Washington 66:1709.WhiteG. F.1927. A method for obtaining infective nematode larvae from cultures. 66:1709.10.1126/science.66.1709.302.bSearch in Google Scholar
Wu, S., Kaplan, F., Lewis, E. E., Alborn, H. T. and Shapiro-Ilan, D. I. 2018. Infected host macerate enhances entomopathogenic nematode movement towards hosts and infectivity in a soil profile. Journal of Invertebrate Pathology 159:141–144.WuS.KaplanF.LewisE. E.AlbornH. T. and Shapiro-IlanD. I.2018. Infected host macerate enhances entomopathogenic nematode movement towards hosts and infectivity in a soil profile. 159:141–144.10.1016/j.jip.2018.10.00730336144Search in Google Scholar