Gall wasp transcriptomes unravel potential effectors involved in molecular dialogues with oak and rose

Sébastien Cambier, Olivia Ginis, Sébastien J. M. Moreau, Philippe Gayral, Jack Hearn, Graham Stone, David Giron, Elisabeth Huguet, Jean-Michel Drezen

Research output: Contribution to journalArticlepeer-review

Abstract / Description of output

To gain insight into wasp factors that might be involved in the initial induction of galls on woody plants, we performed high throughput (454) transcriptome analysis of ovaries and venom glands of two cynipid gall wasps, Biorhiza pallida and Diplolepis rosae, inducing galls on oak and rose, respectively. De novo assembled and annotated contigs were compared to sequences from phylogenetically related parasitoid wasps. The relative expression levels of contigs were estimated to identify the most expressed gene sequences in each tissue. We identify for the first time a set of maternally expressed gall wasp proteins potentially involved in the interaction with the plant. Some genes highly expressed in venom glands and ovaries may act to suppress early plant defense signaling. We also identify gall wasp cellulases that could be involved in observed local lysis of plant tissue following oviposition, and which may have been acquired from bacteria by horizontal gene transfer. We find no evidence of virus-related gene expression, in contrast to many non-cynipid parasitoid wasps. By exploring gall wasp effectors, this study is a first step toward understanding the molecular mechanisms underlying cynipid gall induction in woody plants, and the recent sequencing of oak and rose genomes will enable study of plant responses to these factors.
Original languageEnglish
JournalFrontiers in physiology
Issue number926
Publication statusPublished - 24 Jul 2019

Keywords / Materials (for Non-textual outputs)

  • oak gall wasp
  • rose gall wasp
  • gall induction
  • venom
  • ovary secretions


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