Abstract
A new species of soil-dwelling entomopathogenic nematode Heterorhabditis hepialus killed up to 100% (mean=72%) of root-boring caterpillars of a ghost moth Hepialus californicus in coastal shrub lands. When unchecked, ghost moth caterpillars killed bush lupine, Lupinus arboreus. Here we describe this strange food chain. Although unappreciated by ecologists, entomopathogenic nematodes are widespread and probably one of the most important groups of natural enemies for underground insects. The free-living infective juvenile (IJ) of entomopathogenic nematodes searches for host insects in the soil. A single IJ can kill a host, although several often invade together. After entering the host through a spiracle or other orifice, the IJ regurgitates its symbiotic bacterium, Photorhabdus luminescens, which kills the host within 48 h. The bacteria digest the cadaver and provide food for the exponentially growing nematode population inside. The bacteria produce antibiotics and other noxious substances that protect the host cadaver from other microbes in the soil. When the cadaver is exhausted of resources, IJs break the host integument and can disperse. As many as 420,000 IJs can be produced within a large ghost moth caterpillar. Surface soil of the lupine rhizosphere is the primary habitat of IJs of H. hepialus. Attracted to waste gases emitted by insects, the 0.5-mm-long IJs can move 6 cm/day through moist soil. Prevalences of H. hepialus ranged from as high as 78% of rhizospheres in some lupine stands to almost zero in others, but it was absent from no stand at our study site. Field intensities ranged from 0.003 IJs/cm3 of soil to 7.5 IJs/cm3, and correlated roughly with prevalences among sites. Few ghost moth caterpillars (mean=6.7) succeeded in entering lupine roots where prevalence of H. hepialus was highest, and this stand had lowest mortality (0.02) of mature bush lupine. In the three stands with lowest prevalence (mean = 2%) of this nematode, many caterpillars (mean = 38.5) entered roots, and lupine mortality was high (range = 0.41–1.0). Old aerial photographs indicate that the stands with highest recent nematode prevalence have had little or no mass die-off of lupine over the past 40 years. The photos depict repeated die-offs of lupine during the past four decades in stands with lowest recent prevalence of the nematode. This pattern leads us to entertain the hypothesis that the nematode affects vegetation dynamics indirectly through a trophic cascade. Dispersal of entomopathogenic nematodes is little understood. We found that air drying of soil extirpates H. hepialus and speculate that this nematode is dispersed during the wet season in moist soil bits on the exterior of fossorial insects and mammals. H. hepialus colonized some previously unoccupied lupine rhizospheres during the wet winter-spring season and, obversely, became extinct from some rhizosperes as soil dried in summer. Root-feeding insects have only recently been recognized as a force in communities, and the regulation of these important herbivores is still largely an ecological terra incognita. All evidence indicates that entomopathogenic nematodes are found throughout terrestril ecosystems, and we propose that trophic chains similar to those described in this report should not be uncommon.
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References
Akhurst FRJ, Boemare ME (1990) Biology and taxonomy of Xenorhabdus. In: Gaugler R, Kaya HK (eds) Entomopathogenic nematodes in biological control. CRC, Boca Raton, pp 75–87
Akhurst RJ, Bedding RA, Bull RM, Smith DRJ (1992) An epizootic of Heterorhabditis spp. (Heterorhabditidae: Nematoda) in sugar cane scarabaeids (Coleoptera). Fundam Appl Nematol 5:71–73
Barbour MG, Craig RB, Drysdale RR, Ghiselin MT (1973) Coastal ecology of Bodega Head. University of California Press, Berkeley
Bedding RA, Akhurst RJ (1975) A simple technique for the detection of insect parasitic rhabditid nematodes in soil. Nematologica 21:109–114
Bentley BL, Johnson ND (1991) Plants as food for herbivores: the roles of nitrogen fixation and carbon dioxide enrichment. In: Price PW, Fernandes GW, Lewinson TM, Benson WW (eds) Plant-animal interactions. Wiley, New York, pp 257–272
Boag B (1990) Standardisation of ecological terms in nematology. Fundam Appl Nematol 16:190–191
Brown VK, Gange AC (1990) Insect herbivory below ground. Adv Ecol Res 20:1–58
Cabanillas HE, Poinar GO, Raulston JR (1994) Steinernema riobravis n-sp (Rhabditida, Steinernematidae) from Texas. Fundam Appl Nematol 17:123–131
Carpenter SR, Kitchell J (1993) The trophic cascade in lakes. Cambridge University Press, Cambridge
Davidson ED, Barbour MG (1977) Germination, establishment, and demography of coastal bush lupine at Bodega Head, California. Ecology 58:592–600
Estes JA, Palmisano J (1974) Sea otters; their role in structuring near-shore communities. Science 185:1058–1060
Fan X, Hominick WM (1991) Efficiency of the Galleria (wax moth) baiting technique for recovering infective stages of entomopathogenic rhabditids (Steinernematidae and Heterorhabditidae) from sand and soil. Rev Nematol 14:381–387
Gaugler R, Kaya HK (1990) (eds) Entomopathogenic nematodes in biological control. CRC Press, Boca Raton
Hara AH, Gaugler R, Kaya HK, LeBeck LM (1991) Natural populations of entomopathogenic nematodes (Rhabditida: Heterorhabditidae, Steinernematidae) from the Hawaiian Islands. Environ Entomol 20:211–216
Hominick WM, Briscoe BR (1990) Occurrances of entomopathogenic nematodes (Rhabditida: Steinernematidae and Heterorhabditidae) in British soils. Parasitology 100:289–294
Hominick WM, Reid AP (1990) Perspectives on entomopathogenic entomology. In: Gaugler R, Kaya HK (eds) Entomopathogenic nematodes in biological control. CRC Press, Boca Raton, pp 327–349
Jaffee BJ, Strong DR, Muldoon AE (in press) Nematode trapping fungi of a natural shrubland: tests of foodchain involvement. Mycologia
Kaya HK (1985) Entomogenous nematodes for insect control in IPM systems. In: Hoy MA, Herzog DC (eds) Biological control in agricultural IPM systems. Academic Press, New York, pp 283–302
Kaya HK (1990) Soil ecology. In: Gaugler R, Kaya HK (eds) Entomopathogenic nematodes in biological control. CRC Press, Boca Raton, pp 93–111
Mauleon H, Brian S, Laumond C, Bonifassi E (1993) Utilisation d'enzymes digestives pour l'etude du parasitisme des Steinernema et des Heterorhabditis envers les larves d'insectes. Fundam Appl Nematol 16:185–191
Minard CR (1971) Quaternary beaches and coasts between the Russian River and Drakes Bay, California. University of California Press, Berkeley
Opler PA (1968) Unusual numbers of Hepialus sequoiolus Behrens in Sonoma County. Pan Pac Entomol 44:83
Pitelka LF (1974) Energy allocation in annual and perennial lupines (Lupinus: Leguminosae). Ph. D. dissertation, Stanford University, Palo Alto, California
Poinar G (1990) Biology and taxonomy of Steinernematidae and Heterorhabditidae. In: Gaugler R, Kaya HK (eds) Entomopathogenic nematodes in biological control. CRC Press, Boca Raton, pp 23–58
Power ME (1990) Effects of fish in river food webs. Science 250:811–814
Sexton S, Williams P (1981) A natural occurance of parasitism of Graphognathus leucoloma (Boheman) by the nematode Heterorhabditis sp. J Austr Entomol Soc 20:253–255
Stock SP, Gardner SL, Strong DR (in press) Description of Heterorhabditis hepialus n. sp. (Nemata: Heterorhabditidae), an entomopathogenic nematode isolated from ghost moth larvae Hepialus californicus(Lepidoptera: Hepialidae) from California, USA. Fundam Appl Nematol
Strong DR, Maron JL, Connors PG, Whipple AV, Harrison S, Jeffries JL (1995) High mortality, fluctuation in numbers, and heavy subterranean herbivory in bush lupine, Lupinus arboreus. Oecologia 104:85–92
Stuart RJ, Gaugler R. (1994) Patchiness in populations of entomopathogenic nematodes. J Invert Pathol 64:39–45
Surrey MR, Wharton DA (1995) Dessication survival of the infective larvae of the insect parasitic nematode Heterorhabditis zealandica Int J Parasitol 25:749–752
Tanada Y, Kaya HK (1993) Insect pathology. Academic Press, New York
Trussel ME (1960) Settlement of the Bodega Bay region. Thesis, University California Berkeley
Tuomy H (1926) History of Sonoma Co, vol 1. S.J. Clark, San Francisco
Wagner DL (in press) Hepialid biology and behavior. Invert Taxon
Williams FX (1905) Notes on the Life History of Hepilaus sequiolus Behrens. Entomol News 16:285
Womersley CZ (1990) Dehydration survival and anhydrobiotic potential. In: Gaugler R, Kaya HK (eds) Entomopathogenic nematodes in biological control. CRC Press, Boca Raton, pp 75–87
Woodring J, Kaya HK (1988) Steinernematid and heterorhabditid nematodes: a handbook of biology and techniques. Arkansas Agricultural Experiment Station, Fayetteville
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Strong, D.R., Kaya, H.K., Whipple, A.V. et al. Entomopathogenic nematodes: natural enemies of root-feeding caterpillars on bush lupine. Oecologia 108, 167–173 (1996). https://doi.org/10.1007/BF00333228
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DOI: https://doi.org/10.1007/BF00333228