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Anti-insect effects of the gall wall of Baizongia pistaciae [L.], a gall-inducing aphid on Pistacia palaestina Boiss

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Abstract

The Enemy hypothesis is a theoretical framework for understanding the adaptive nature of galls induced in host plants by insects. Contrary to other gall inducing insects, like Cynipids or sawflies, this hypothesis has not been studied for the gall aphids on pistachio trees in the Middle East. Galls on plants are supposed to protect their inducers from other organisms, including herbivores feeding on the host plant and possibly feeding on the gall tissue. Assuming that among aphid enemies there are numerous insects which have to perforate the gall wall to access the aphids inside, determining whether the gall wall has anti-insect properties should be one of the first steps in dealing with this hypothesis. In the present research using Baizongia pistaciae [L.], an aphid that creates perfectly closed galls in Pistacia palaestina Boiss, laboratory experiments were first conducted on a herbivore, the stored grain pest, Tribolium castaneum Herbst, to assess chemical anti-insect activities of the gall tissue, and an effort was made to understand why these properties do not harm the aphids inside the gall. Addition of fresh gall tissue to food reduced the population growth of flour beetles. Non-polar organic extracts had contact toxicity for larvae of these insects, and an impact on the feeding preferences of the adults. These results indicate chemical anti-insect activities of the gall tissue. The research also reveals that the permeability of the gall wall to non-polar volatile compounds is important to the survival of the aphids inside the gall cavity. These findings do not allow us to reject the Enemy hypothesis in the gall-inducing aphids/Pistacia trees interactions.

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References

  • Abe Y (1988) Tropobiosis between the Gall Wasp, Andricus symbioticus and the Gall-Attending Ant, Lasius niger. Appl Entomol Zool 23(1):41–44

    Google Scholar 

  • Abe Y (1997) Well-developed gall tissues protecting the gall wasp, Andricus ukaigawe (Mukaigawa) Hymenoptera: Cynipidae) against the Gall-inhabiting Moth Oedematopoda sp. (Lepidoptera: Stathmopodidae). Appl Entomol Zool 32(1):135–141

    Google Scholar 

  • Allison SD, Schultz JC (2004) Biochemical responses of chestnut oak to a galling Cynipid. J Chem Ecol 31(1):151–166

    Article  Google Scholar 

  • Bailey R, Schönrogge K, Cook JM, Melika G, Csoka G, Thuroczy C, Stone GN (2009) Host niches and defensive extended phenotypes structure parasitoid wasp communities. Plos Biol 7(8):e1000179. doi:10.1371/journal.pbio.1000179

    Article  PubMed  Google Scholar 

  • Burstein M, Wool D (1992) Great tits exploit aphid galls as a source of food. Ornis Scandinavica 23:107–109

    Article  Google Scholar 

  • Cornell HV (1983) The secondary chemistry and complex morphology of galls formed by Cynipinae (Hymenoptera): why and how? Amr Midl Natur 110:225--234

    Article  Google Scholar 

  • Davatchi GA (1958) Etude comparative sur la biologie et le polymorphisme des aphides gallicoles des Pistacia d’Asie Centrale, du Moyen-Orient, du bassin méditerranéen et du Nord Africain. Revue de Pathologie Entomologique Agricole Française 37:85–166

    Google Scholar 

  • Dorchin N (2001) Gall midges (Diptera: Cecidomyiidae) infesting Suaeda monoica (Chenopodiaceae) in Israel. Proc Entomol Soc Wash 103(3):561–581

    Google Scholar 

  • Fernandes GW, Preszler RW, Grim J (1990) The occurrence of crystals in a cynipid leaf gall on Quercus turbinella. Beitr Biol Pflanzen 65:377--383

    Google Scholar 

  • Flamini G, Bader A, Cioni PL, Katbeh-Bader A, Morelli I (2004) Composition of the essential oil of leaves, galls, and ripe and unripe fruits of Jordian Pistacia palaestina Boiss. Agric Food Chem 52:572–576

    Article  CAS  Google Scholar 

  • Font Quer P (1993) Plantas Medicinales. El Dioscorides Renovado vol. 2. Labor Barcelona, pp 442–444

  • Giner-Larza EM, Manez S, Giner-Pons RM, Recio MC, Rios J-L (2000) On the anti-inflammatory and anti-phospholipase A2 activity of extracts from lanostane-rich species. J Ethnopharmacol 73:61–69

    Article  CAS  PubMed  Google Scholar 

  • Hocking GM (1997) A dictionary of natural products. Plexus, Medford, pp 606–607

    Google Scholar 

  • Kafkas S (2006) Phylogenetic analysis of the genus Pistacia by AFLP markers. Plant Syst Evol 262(1--2):113–124

    Article  Google Scholar 

  • Kafkas S, Perl-Treves R (2001) Molecular characterization of P. palaestina as a variety of P. terebinthus. ISHS Acta Hortic 591. Congress abstract, p 1

  • Magiatis P, Melliou E, Skaltsouni AL, Cinou IB, Mitaku S (1999) Chemical composition and antimicrobial activity of the essential oils of Pistacia lentiscus var chia. Planta Medicinalis 65:749–752

    Article  CAS  Google Scholar 

  • Martinez J-JI, Mokady O, Wool D (2005) Patch size and patch quality of gall-inducing aphids in a mosaic landscape in Israel. Landscape Ecol 20:1013–1024

    Article  Google Scholar 

  • McNaughton J, Tarrants JL (1983) Grass leaf salicification: natural selection for an inducible defense against herbivores. Proc Natl Acad Sci USA 80:790–791

    Article  PubMed  Google Scholar 

  • Pascual-Villalobos MJ, Robledo A (1998) Screening for anti-insect activity in Mediterranean plants. Ind Crop Prod 8:183–194

    Article  CAS  Google Scholar 

  • Price PW, Pschorn-Walcher H (1988) Are galling insects better protected against parasitoids than exposed feeders? a test using tenthredinid sawflies. Ecol Entomol 13:195–205

    Article  Google Scholar 

  • Price PW, Waring GL, Fernandes GW (1986) Hypotheses on the adaptive nature of galls. Proc Entomol Soc Wash 88:361–363

    Google Scholar 

  • Price PW, Fernandes GW, Waring GL (1987) Adaptive nature of insect galls. Environ Entomol 16:15–24

    Google Scholar 

  • Sattler K (1982) A review of the western paleartic Gelechidae (Lepidoptera) associated with Pistacia, Rhus and Cotinus (Anacardiaceae). Entomol Gazette 33:203–210

    Google Scholar 

  • Schultz BB (1992) Insect herbivores as potential causes of mortality and adaptation in gall forming insects. Oecologia 90:297–299

    Google Scholar 

  • STATISTIX.SX (1992) Analytical Software (Version 4.0). P.O. Box 12185. Tallahassee, FL 32317-2185, USA

  • Stone GN, Schönrogge K (2003) The adaptive significance of insect gall morphology. Trends Ecol Evol 18:512–522

    Article  Google Scholar 

  • Tscharntke T (1989) Changes in shoot growth of Pragmites australis caused by the gall maker Giraudiella inclusa (Diptera: Cecidomyiidae). Oikos 54:370–377

    Article  Google Scholar 

  • Werner RA (1995) Toxicity and repellency of 4-allylanisole and monoterpenes from white spruce and tamarack to the spruce beetle and eastern larch beetle (Coleoptera: Scolytidae). Environ Entomol 24:372–379

    CAS  Google Scholar 

  • Wool D (1995) Aphid-induced galls on Pistacia in natural Mediterranean forest of Israel: which, where, and how many? Isr J Zool 41:591–600

    Google Scholar 

  • Wool D (1997) The shapes of insect galls: insect control, plant constraints and phylogeny. In: Raman A (ed) Ecology and evolution of plant-feeding insects in natural and man-made environments. International Scientific Publications, New Delhi, pp 203–212

    Google Scholar 

  • Wool D (2003) Gall-inducing aphids: biology, ecology and evolution. In: Raman R, Schaefer CW, Withers TM (eds) Biology, ecology, and evolution of gall-inducing arthropods. Science Publishers Inc. Enfield, New Hempshire, pp 73–132

    Google Scholar 

  • Wool D, Ben Zvi O (1998) Population ecology and clone dynamics of the galling aphid Geoica wertheimae Brown and Blackman (Pemphigidae: Fordinae). Eur J of Entomol 75:509–518

    Google Scholar 

  • Wool D, Burstein M (1991) Parasitoids of the gall-forming aphid Smynthurodes betae (Aphidoidea: Fordinae) in Israel. Entomophaga 36:531–538

    Article  Google Scholar 

  • Wool D, Manheim O (1986) Population ecology of the gall-forming aphid. Aploneura lentisci (Pass.) in Israel. Res Popul Ecol 28:151–162

    Article  Google Scholar 

  • Wool D, Aloni R, Ben-Zvi O, Wolberg M (1999) A galling aphid furnishes its home with a built-in pipeline to the host food supply. Entomologia Experimentalis et Applicata 91:183–186

    Article  Google Scholar 

  • Zar JH (1984) Biostatistical analysis, 2nd edn. Prentice-Hall, Englewood Cliffs, p 241

    Google Scholar 

  • Zohary M (1952) A monographical study of the genus Pistacia. Palestine Journal of Botanica 5:187–228

    Google Scholar 

Download references

Acknowledgments

I thank the staff of the IPM Laboratory at Anne Frank School (Upper Galilee), who permitted me to use their equipment, Tamar Berkowitz for proofreading a previous draft, Oren Pearlson and two anonymous reviewers who provided very helpful comments on an earlier version of the manuscript. This work was partly supported by the Research Authority of Tel Hai Academic College.

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  1. Department of Environmental Sciences, the Faculty of Sciences, Tel Hai Academic College, 12210, Upper Galilee, Israel

    Jean-Jacques Itzhak Martinez

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Correspondence to Jean-Jacques Itzhak Martinez.

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Handling Editor: Graham Stone.

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Martinez, JJ.I. Anti-insect effects of the gall wall of Baizongia pistaciae [L.], a gall-inducing aphid on Pistacia palaestina Boiss. Arthropod-Plant Interactions 4, 29–34 (2010). https://doi.org/10.1007/s11829-009-9081-8

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