Oral toxicity of double-stranded RNA (dsRNA) specific to integrin β1 subunit (SeINT) was known in a polyphagous insect pest, Spodoptera exigua. For an application of the dsRNA to control the insect pest, this study prepared a recombinant Escherichia coli expressing dsRNA specific to SeINT. The dsRNA expression was driven by T7 RNA polymerase overexpressed by an inducer in the transformed E. coli. The produced dsRNA amount was proportional to the number of the cultured bacteria. The bacteria gave a significant oral feeding mortality to S. exigua larvae with a significant reduction of the SeINT expression. The resulting insect mortality increased with the fed number of the bacteria. Pretreatment with a sonication to disrupt bacteria cell wall membrane significantly increased the insecticidal activity of the transformed bacteria. Compared to the control bacteria transformed by non-recombinant vector, the larvae fed the bacteria expressing dsRNA specific to SeINT suffered tissue damage in the midgut epithelium, which was characterized by a loose cell-cell contact and a significant cell death. The dsRNA-treated larvae were significantly more susceptible to a Cry toxin derived from Bacillus thuringinesis (Bt) than the larvae treated only with Cry toxin. This study demonstrates that a transformed bacterium expressing dsRNA specific to SeINT has a significant insecticidal activity by oral application against S. exigua and makes the target insects to be highly susceptible to Bt toxin.

Double-stranded RNA(dsRNA) had been used to specitically suppress target gene expression at post-tanscription level. Injection of dsRNA to hemocoel is the most efficient to knockdown target mRNA. However, some insects have shown to be susceptible to feeding dsRNA. Spodoptera exigua was susceptible to dsRNA at oral treatment. Especially dsRNA specific to β-integrin was potent to survival of S.exigua larvae. This study advanced our dsRNA application technology by generating recombinant E.coli expressing dsRNA specific the β-integrin. A recombinant vector L4440 was constructed with a partial β-integrin gene under T7 RNA polymerase promoter. The recombinant vector was used to transform HT115 competent cells of E.coli. The transformed E.coli expressed the dsRNA. The production of dsRNA was proportional to the bacterial number. By feeding the recombinant E.coli, S.exigua underwent significant mortality. By adding E.coli expressing Cry1Ca Bt toxin to E.coli expressing dsRNA, S.exigua exhibited highly enhanced mortality. This study suggests a possibility to use a recombinant E.coli expressing dsRNA to control S.exigua.

Glycerol is a polyol that is responsible for the cold hardiness of insects. Glycerol kinase gene, which is an important key enzyme for glycerol biosynthesis, was predicted from whole genome sequencing data from the diamondback moth, Plutella xylostella. Four of P. xylostella glycerol kinase genes (PxGKs) were determined as a functional glycerol kinase through in silico study. Pre-exposure of P. xylostella larvae to 4°C for 7 h significantly enhanced survival (rapid cold hardiness: RCH) under a freezing temperature (-10°C) and increased glycerol titers. To determination of functional GK gene, expressions of all GK genes were measured by RT-PCR analysis. All GK genes were expressed in all larval stage and tissues (gut, hemocyte, and fat body). Expressions of all GK genes were suppressed by its specific dsRNA treatment into 4 th instar larva. Each 150 ng of dsRNA PxGK2 treatment significantly decreased glycerol amount in hemolymph by HPLC analysis. Larval treated by dsRNA PxGK2 also significantly lost the RCH under -10°C exposure. These results indicate that glycerol is a crucial RCH agent and its synthesis is regulated by a specific PxGK2 gene among GK gene isoforms in P. xylostella. In addition, the beet armyworm, Spodpotera exigua, encodes RCHassociated SeGK1, which has been functionally identified by RNA interference.

Cotesia plutellae has been known as a natural enemy against the Diamondback moth, Plutella xylostella via laying eggs into a larva. When the larva hatches from the egg, teratocytes also are released and expected to work as immune suppressor via secreting immune suppressive factors such as venom proteins, teratocytes and polydnavirus. In order to identify immune suppressive factors from teratocytes, we collected the supernatant from serum-free culture media of teratocytes. Concentration of secreted proteins from teratocytes was successfully performed with using centricons among tested methods such proteins precipitation and electrophoresed in sodium dodecyl sulfate polyacrylamide gel. The gel slices were directly digested with trypsin using in-gel digestion method and analyzed via LC-Ms-Ms. Molecular weight of peptide fragments were compared with protein database predicted by full-genome sequences of C. plutellae. We identified two immune responsive proteins, which are calreticulin, host cellular response-related gene and neprilysin 2, immune regulator. This result suggests that host immune response is suppressed or regulated by the immune suppressive factors of teratocytes.