Cabbage waxes affect Trissolcus brochymenae response to short‐range synomones

We show that induced synomones, emitted as a consequence of Murgantia histrionica activity on Brassica oleracea, are adsorbed by the epicuticular waxes of leaves and perceived by the egg parasitoid Trissolcus brochymenae. Leaves were exposed to M. histrionica females placed on the abaxial leaf surface. After 24 h, the leaves were treated mechanically using gum arabic, or chemically using chloroform, on the adaxial surface, and finally the adaxial surface was assayed with T. brochymenae by two‐choice tests in a closed arena. Wasp females responded to mechanically dewaxed cabbage leaf portions with feeding punctures and footprints (Ff) and with feeding punctures, oviposition and footprints (FOf), showing no effect of wax removal. In contrast, the removal of the epicuticular waxes from leaf portions close to FOf, and from leaves with oviposition and footprints (Of), determined the lack of responses by T. brochymenae. Solvent extracts of different treatments were bioassayed, but only FOf triggered parasitoid response. Thus the detection of oviposition‐induced synomones by the parasitoid depends on their adsorption by the epicuticular waxes. Mechanical wax removal from leaf portions contaminated with host footprints (f) also determined a lack of wasp responses, suggesting that the footprints might trigger the induction of a “footprint‐induced synomone” adsorbed onto the epicuticular waxes and exploited by the parasitoid. Leaf portions with the abaxial lamina previously dewaxed and then contaminated by footprints (D+f) of M. histrionica did not affect the parasitoid response, indicating that the abaxial epicuticular waxes are not directly involved in the chemicals induced by M. histrionica footprints.

[1]  M. Hilker,et al.  Insect Egg Deposition Induces Indirect Defense and Epicuticular Wax Changes in Arabidopsis thaliana , 2012, Journal of Chemical Ecology.

[2]  T. Meiners,et al.  Plants and insect eggs: how do they affect each other? , 2011, Phytochemistry.

[3]  M. Riedel,et al.  Host Sex Discrimination by an Egg Parasitoid on Brassica Leaves , 2011, Journal of Chemical Ecology.

[4]  F. Frati,et al.  Short-range allelochemicals from a plant–herbivore association: a singular case of oviposition-induced synomone for an egg parasitoid , 2010, Journal of Experimental Biology.

[5]  F. Loreto,et al.  Influence of Feeding and Oviposition by Phytophagous Pentatomids on Photosynthesis of Herbaceous Plants , 2010, Journal of Chemical Ecology.

[6]  T. Meiners,et al.  How do plants “notice” attack by herbivorous arthropods? , 2010, Biological reviews of the Cambridge Philosophical Society.

[7]  E. Peri,et al.  Plant surfaces of vegetable crops mediate interactions between chemical footprints of true bugs and their egg parasitoids , 2010, Communicative & integrative biology.

[8]  M. E. Huigens,et al.  Anti-aphrodisiac Compounds of Male Butterflies Increase the Risk of Egg Parasitoid Attack by Inducing Plant Synomone Production , 2009, Journal of Chemical Ecology.

[9]  F. Frati,et al.  A finely tuned strategy adopted by an egg parasitoid to exploit chemical traces from host adults , 2009, Journal of Experimental Biology.

[10]  E. Peri,et al.  The response of Trissolcus basalis to footprint contact kairomones from Nezara viridula females is mediated by leaf epicuticular waxes , 2009, Naturwissenschaften.

[11]  G. Salerno,et al.  Host Searching by Egg Parasitoids: Exploitation of Host Chemical Cues , 2009 .

[12]  U. Hildebrandt,et al.  Plant surface wax affects parasitoid’s response to host footprints , 2008, Naturwissenschaften.

[13]  T. Meiners,et al.  Foraging behavior of egg parasitoids exploiting chemical information , 2008 .

[14]  T. Meiners,et al.  The Plant's Response towards Insect Egg Deposition , 2008 .

[15]  M. Dicke,et al.  The Response Specificity of Trichogramma Egg Parasitoids towards Infochemicals during Host Location , 2007, Journal of Insect Behavior.

[16]  R. Jetter,et al.  Nanotubules on plant surfaces: chemical composition of epicuticular wax crystals on needles of Taxus baccata L. , 2006, Phytochemistry.

[17]  Markus Riederer,et al.  Plant Surface Properties in Chemical Ecology , 2005, Journal of Chemical Ecology.

[18]  M. Dicke,et al.  Oviposition‐induced plant cues: do they arrest Trichogramma wasps during host location? , 2005 .

[19]  S. Colazza,et al.  Identification of Volatile Synomones, Induced by Nezara viridula Feeding and Oviposition on Bean spp., That Attract the Egg Parasitoid Trissolcus basalis , 2004, Journal of Chemical Ecology.

[20]  S. Eigenbrode,et al.  Waxy bloom in peas influences the performance and behavior of Aphidius ervi, a parasitoid of the pea aphid , 2004 .

[21]  G. Salerno,et al.  Insect oviposition induces volatile emission in herbaceous plants that attracts egg parasitoids , 2004, Journal of Experimental Biology.

[22]  S. Eigenbrode The effects of plant epicuticular waxy blooms on attachment and effectiveness of predatory insects. , 2004, Arthropod structure & development.

[23]  G. Salerno,et al.  Chemical Cues from Murgantia histrionica Eliciting Host Location and Recognition in the Egg Parasitoid Trissolcus brochymenae , 2004, Journal of Chemical Ecology.

[24]  T. Meiners,et al.  Induction of Plant Synomones by Oviposition of a Phytophagous Insect , 2004, Journal of Chemical Ecology.

[25]  S. Eigenbrode,et al.  Effects of a simple plant morphological mutation on the arthropod community and the impacts of predators on a principal insect herbivore , 2003, Oecologia.

[26]  T. Meiners,et al.  Induction of plant responses to oviposition and feeding by herbivorous arthropods: a comparison , 2002 .

[27]  R. Jetter,et al.  Chemical composition of the Prunus laurocerasus leaf surface. Dynamic changes of the epicuticular wax film during leaf development. , 2001, Plant physiology.

[28]  C. Schaefer,et al.  Possible Causes of Disease Symptoms Resulting from the Feeding of Phytophagous Heteroptera , 2000 .

[29]  K. Hori Possible Causes of Disease Symptoms Resulting from the Feeding of Phytophagous Heteroptera , 2000 .

[30]  R. Jetter,et al.  Leaf cuticular waxes are arranged in chemically and mechanically distinct layers: evidence from Prunus laurocerasus L. , 2000 .

[31]  Sanford D. Eigenbrode,et al.  Effects of Brassica oleracea waxblooms on predation and attachment by Hippodamia convergens , 1999 .

[32]  T. Shanower,et al.  Physical and chemical plant characters inhibiting the searching behaviour of Trichogramma chilonis , 1998 .

[33]  Wilhelm Barthlott,et al.  Classification and terminology of plant epicuticular waxes , 1998 .

[34]  T. Meiners,et al.  Host location in Oomyzus gallerucae (Hymenoptera: Eulophidae), an egg parasitoid of the elm leaf beetle Xanthogaleruca luteola (Coleoptera: Chrysomelidae) , 1997, Oecologia.

[35]  S. Eigenbrode,et al.  Effects of Plant Epicuticular Lipids on Insect Herbivores , 1995 .

[36]  L. Noldus,et al.  Moth sex pheromone adsorption to leaf surface: bridge in time for chemical spies , 1991 .

[37]  P. W. Miles The Saliva of Hemiptera , 1972 .

[38]  Norm Johnson,et al.  Etude biologique et ecologique des hymenopteres parasites des oeufs des punaises de cereales. , 1968 .