Abstract
Insects are solely dependent on an innate immune system. Antimicrobial peptide production is the main immune response of insects. The molecular mechanisms underlying this reaction in Drosophila melanogaster involves the induction of antimicrobial peptide genes, which is regulated by the Toll and IMD pathways. The Toll pathway is mainly activated by fungi or Gram-positive bacteria and the IMD pathway by Gram-negative bacteria. In terms of comparative immunology, we investigated the antimicrobial peptide production system in the beetle, Tribolium castaneum, which differs from that in D. melanogaster. To obtain a more detailed understanding, we examined whether Pelle and Tube, orthologues of which in D. melanogaster are the Toll pathway components, contributed to antimicrobial peptide production and immune reactions. These two genes were not induced by challenges from any type of microbe, which in this case were Gram-positive bacteria, -negative bacteria and an eukaryote. Using Pelle and Tube knockdown pupae, it was demonstrated that Pelle and Tube are involved in the induction of Cec2 as a representative Toll pathway-dependent gene in T. castaneum by Gram-positive and -negative bacteria and eukaryote challenges. Furthermore, neither Pelle nor Tube contributed to immune defences against two entomopathogenic bacteria. These results, taken together with our previous findings, led to the conclusion that the Toll pathway immune signaling reported in D. melanogaster indeed occurs in T. castaneum, and the gene sets involved in Toll signal transduction in T. castaneum did not differ significantly from those in D. melanogaster, but transduced immune signals to challenges from Gram-positive bacteria, -negative bacteria and an eukaryote, which differed from those in D. melanogaster.
Highlights
Insects do not possess an adaptive immune defense system; they rely solely on an innate immune system
We investigated whether Pelle or Tube in T. castaneum play a role in the production of antimicrobial peptides (AMPs), one of the main immune reactions in insects, using RNA interference (RNAi)
The results indicate that neither Pelle nor Tube was induced by challenges from three microbes, namely, heatkilled E. coli (Gram-negative bacteria) M. luteus (Grampositive bacteria) and S. cerevisiae, and Pelle and Tube mainly contributed to the induction of Cecropin 2 (Cec2) by these microbe challenges, which was mainly regulated by the Toll pathway (Yokoi et al, 2012b)
Summary
Insects do not possess an adaptive immune defense system; they rely solely on an innate immune system. In D. melanogaster, the Toll pathway is activated by lysine-type peptidoglycans derived from Gram-positive bacteria or β-1,3 glucan from fungi or yeast, which are recognized by the Gram-negative binding protein 1 (GNBP1) and peptidoglycan recognition protein SA (PGRP-SA) complex and GNBP3, respectively (Gottar et al, 2006; Wang et al, 2006). The protein MyD88 is recruited through the TID domain, which recruits another adapter protein, Tube and the kinase Pelle (Medzhitov et al, 1998; Horng & Medzhitov, 2001). These three proteins form heterotrimer complexes, which phosphorylate and degrade the inhibitor of NF-κB, cactus by an unknown mechanism (Horng & Medzhitov, 2001; Valanne et al, 2011). The IMD pathway is mainly activated by Meso-diaminopimelic acid-type peptidoglycans derived from Gramnegative bacteria through PGRP-LC, and an immune
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