배추나비고치벌(Cotesia glomerata L.)은 배추흰나비(Artogeia rapae L.)와 배추좀나방(Plutella xylostella L.) 유충을 공격하는 내부기생 천적으로, 여름배추를 주로 생산하는 고랭지 채소밭에서 배추흰나비와 배추좀나방을 동시에 생물적 방제하기 위한 천적자원으로서 활용 가능성이 높다. 배추나비고치벌에 대한 온도별 생육반응과 성비, 먹이에 따른 수명을 실험실내에서 조사한 결과, 배추나비고치벌의 알-유충 기간 및 번데기 기간은 20℃에서 각각 12.1 ± 2.1일, 6.4 ± 1.8일이었으며, 생육온도가 높아질수록 짧아지는 경향을 보였다. 이를 바탕으로 산출한 알-유충 및 번데기 시기의 발육영점온도는 각각 7.7℃, 8.5℃였다. 여러 상이한 온도에서 사육한 배추나비고치벌 우화성충의 암수를 조사한 결과, 15℃에 서 61.0 ± 4.5%, 20℃에서 44.2 ± 1.0%, 25℃에서 39.0 ± 2.3%의 성비를 보여 온도가 낮아질수록 암컷의 발생률이 높아지는 경향을 보였다. 배추나비고치벌 성충에 10% 설탕액을 급여한 결과 수명은 20.4 ± 0.2일이었으며, 아무것도 급여하지 않은 경우는 3.6 ± 0.1일이었다. 실내 대량 사육을 통해 확보한 배추나비고치벌 성충을 2007년부터 2018년까지 매년 8월 초에 고랭지 배추밭에 방사하고 노지 기생률을 조사하였다. 그 결과 햇수가 지날수록 노지 기생률이 증가하는 것을 확인하였다(Y=0.2696X+2.8633, R2=0.3994). 가장 높은 기생률을 보인 연도는 2013년의 7.6%이었고, 가장 최근인 2018년에는 6.5%의 기생률을 나타내었다.
Cotesia plutellae, an endoparasitoid wasp, parasitizes larvae of Plutella xylostella, and disrupt immune response of the host through parasitic factors. These immune disruption factors are maternal (venom proteins, polydnavirus, and ovary proteins) and embryonic (teratocytes) factors. In this study, we performed transcriptome analysis of venom glands of C. plutellae and identified neprilysin-1 (NEP1) known to be potential immunosuppression gene. Cp-NEP1 encoded 451 amino acid and belongs to hymeopteran NEP1 via phylogenetic analysis. Based on the structural comparison Cp-NEP1 lacks in conserved motifs such as substrate binding (NAYY/F), zinc-binding site (HExxH), zinc-binding site, protein folding and maturation (CxxW). To investigate function of Cp-NEP1, we constructed a recombinant Cp-NEP1 harboring N-terminally fused 6X His tag. Peptide sequencing revealed successful expression of the recombinant Cp-NEP1 in Escherichia coli. Pre-heated E. coli as antigen induced spike of nodule formation whereas co-injection of the recombinant Cp-NEP1 and pre-heated E. coli exhibited suppression of nodule formation in the host. Quantitative real-time PCR revealed that expression of phenoloxidase related to nodule formation was suppressed under co-injection of the recombinant Cp-NEP1 and E. coli. These results suggest that Cp-NEP1 contributes to immunosuppression of P. xylostella via phenoloxidase suppression and conserved motifs of neprilysin family are not required for host immune suppression.
One of the endoparasitoid wasp, Cotesia plutellae (Braconidae), parasitizes young larvae of the diamondback moth, Plutella xylostella. For the successful parasitization, C. plutellae required suppression of immune response in P. xylostella. Maternal (polydnavirus, venom proteins and ovary proteins) and embryonic (teratocytes) factors have been involved in immune-suppression. In this study, we performed transcriptome analysis of venom of C. plutellae and identify neprilysin-1 (Cp-NEP1) as a potential immunosuppressive protein. Cp-NEP1 encoded 451 amino acids and largely belongs to the hymeopteran neprilysin family via phylogenetic analysis. It is of interest that Cp-NEP1 has no conserved motifs such as zinc-binding domain (HExxH), substate binding domain (NAYY/F) and protein folding and maturation domain (CxxW) generally identified in other neprilysin family. In order to examine the biochemical function of Cp-NEP1, the recombinant Cp-NEP1 tagged with N-terminally 6X His was constructed and expressed in Escherichia coli. Expression of Cp-NEP1 was confirmed with SDS-PAGE and peptide sequencing. Recombinant Cp-NEP1 significantly suppressed nodule formation when the co-injection with E. coli. These results suggest that Cp-NEP1 contributes to suppression of immune response in P. xylostella and that the conserved motifs reported from other neprilysin do not involve immunosupperssion.
Translational control is a strategy for various viruses to manipulate their hosts to suppress any acute antiviral activity. Some cys-motif genes encoded in polydnaviruses or teratocytes act as host translation inhibitory factor (HTIF) to defend the host antiviral activity. A novel cys-motif gene, TSP13, was encoded in the genome of an endoparasitoid wasp, Cotesia plutellae. TSP13 consists of 129 amino acid residues with a predicted molecular weight of 13.987 kDa and pI value at 7.928. Genomic DNA region encoding open reading frame is interrupted with three introns. TSP13 was expressed in Plutella xylostella larvae parasitized by C. plutellae. C. plutellae bracovirus (CpBV) was purified and injected to nonparasitized P. xylostella. In the virus-injected P. xylostella, TSP13 was shown to be expressed by RT-PCR analysis. Thus, TSP13 was turned out to be encoded in the proviral CpBV genome. TSP13 was cloned into a eukaryotic expression vector, which was then used to infect Sf9 cells to transiently express TSP13. The synthesized TSP13 was detected in the culture broth. Purified TSP13 significantly inhibited cellular immune responses. Furthermore, TSP13 entered the target cells and was localized in the cytosol. This study reports a novel cys-motif gene, which is encoded in CpBV genome localized on chromosome(s) of C. plutellae and replicated to be encapsidated in the episomal viral particles during parasitization.
Cotesia plutellae known as an endoparasitoid parasitizes larvae of the diamondback moth, Plutella xylostella which is a major pest in cruciferous crops. For the successful parasitization, maternal and embryonic factors of C. plutellae such as polydnavirus, ovarian proteins, teratocytes and venom are required. In this study, we identified calreticulin (Cp-CRT) gene from transcriptome data of the venom gland in C. plutellae. cDNA of CRT was cloned from total RNA of the venom gland via PCR and encodes 403 amino acids harboring several structural motifs such as a signal peptide sequence, a repetitive sequence, a putative coiled-coil sequence encompassing, and endoplasmic reticulum-recognizing domain (-KDEL). Phylogenetic analysis showed that the Cp-CRT gene formed a unique cluster with other hymenopteran CRT genes, indicating that the Cp-CRT belongs to the CRT family. To examine the physiological function of Cp-CRT, recombinant Cp-CRT, fused with 6X-His at N-terminal was constructed and expressed in E. coli. Recombinant Cp-CRT was successfully expressed via Western blot analysis and suppressed significant nodule formation when co-injected with E. coli as immune response inducer. These results suggest that the Cp-CRT involves in suppression of cellular immune response in the host
국내 배추좀나방(Plutella xylostella) 집단은 피레스로이드 농약에 대해서 저항성을 보이며, 이는 이 살충제의 작용점인 소듐이온채널 유전자의 돌연변이에 기인된다. 더욱이 배추좀나방은 대부분 상용화된 살충제에 대해서 저항성을 발달시킬 수 있다. 본 연구는 배추좀나방을 효과적으로 방제하기 위해 내부기생성 천적인 프루텔고치벌(Cotesia plutellae)과 미생물농약인 Bacillus thuringiensis의 혼합처리 기술을 개발하기 위해 수행되었다. 프루텔고치벌이 감수성과 저항성 배추좀나방에 대한 기생 선호성에 차등이 있는 지 조사하기 위해 다섯 개 서로 다른 집단에 대해서 살충제 감수성과 프루텔고치벌 기생성 차이를 비교하였다. 이들 배추좀나방 집단들은 피레스로이드, 유기인계, 네오니코틴계 및 곤충성장조절제를 포함하는 세 종류의 상용 살충제에 대한 약제 감수성에서 뚜렷한 차이를 보였다. 그러나 이들 집단들은 프루텔고치벌에 의한 기생률에서는 차이를 보이지 않았다. 더욱이 기생된 배추좀나방은 B. thuringiensis에 대해서 감수성이 증가되었다. 프루텔고치벌이 갖는 면역억제인자 가운데 바이러스 유래 ankyrin 유전자(vankyrin)를 비기생된 배추좀나방에 발현시켰다. Vankyrin의 발현은 배추좀나방 3령충의 B. thuringiensis에 대한 감수성을 현격하게 증가시켰다. 즉, 프루텔고치벌에 의해 야기된 면역저하가 B. thuringiensis의 살충력을 증가시켰다. 이러한 결과들은 프루텔고치벌과 미생물농약인 B. thuringiensis의 혼합처리가 살충제 저항성 배추좀나방을 효과적으로 방제할 수 있다고 제시하고 있다.
Parasitism by an endoparasitoid wasp, Cotesia plutellae, results in significant immunosuppression of the diamondback moth, Plutella xylostella. Parasitized larvae significantly suffered higher susceptibility to a microbial biopesticide, Bacillus thuringiensis (Bt) than nonparasitized (NP) larvae. To find out an immunosuppressive agent causing the enhanced Bt efficacy, viral ankyrin (=vankyrin) genes encoded in C. plutellae bracovirus (CpBV) were analyzed by transient expression in NP larvae. CpBV segments containing different vankyrins were microinjected to NP larvae and expressed their encoded vankyrins. Expression of some vankyrins significantly inhibited immune response and enhanced Bt efficacy. This study suggests that expression of vankyrins suppress a cellular immune response and lose Bt tolerance of P. xylostella larvae.
An endoparasitoid wasp, Cotesia plutellae, parasitizes young larvae of the diamondback moth, Plutella xylostella, with its parasitic factors of polydnavirus, venom, ovarian proteins, and teratocytes (TC). TCs are originated from embryonic serosal membrane at hatch of C. plutellae eggs. TCs, after released in hemocoel of parasitized larvae, increased their average cell size from 20.6 μm to 77 μm during whole developmental period of the parasitoid larvae, but did not increase their cell number by maintaining about 150 cells per larvae. TCs of C. plutellae, are considered to be involved to extend the host larval development period and to arrest larval-pupal metamorphosis, were cultured in an insect cell culture medium for 21 days. Like TCs in parasitized larvae, in vitro cultured TCs showed increase in cell size, but did not show increase of cell number. Microinjection of in vitro cultured TCs significantly inhibited larva-to-pupa metamorphosis of nonparasitized P. xylostella, in which pupated host also showed extended larval period. Larvae injected with TCs exhibited alteration in expression of ecdysone receptor (EcR) and insulin receptor (InR) as well as in parasitized larvae. Teratocyte-secretory factors in culture medium showed this antimetamorphic effect on P. xylostella, while heat treated TC culture medium lost the effect. However, a successful parasitization of C. plutellae required both TCs and polydnavirus to alter host physiology.
Parasitization by an endoparasitoid wasp, Cotesia plutellae, extends a larval period of Plutella xylostella and inhibits a larva-to-pupa metamorphosis. To determine antimetamorphic parasitic factor(s) in this host-parasitoid interaction, an effect of its symbiotic polydnavirus, Cotesia plutellae bracovirus (CpBV), was investigated by injecting purified virus particles to nonparasitized larvae of P. xylostella. Larvae injected with CpBV exhibited antimetamophosis in a viral dose-dependent manner. Also, the susceptibility to the viral injection was increased at young larval stages. Parasitized or virus-injected larvae shwed significant decrease in cell size of prothoracic gland and reduction in expression of ecdysone receptor (EcR) gene. However, they increased and maintained expression of insulin receptor (InR) gene. Twenty four CpBVsegments were individually injected to nonparasitized larvae. Only two segments (S22 and S27) had significant antimetamorphic effect. Subsequent RNA interference using double stranded RNA (dsRNA) was performed in each of encoded genes in each segment. Protein tyrosine phosphatase, ELP, and three hypothetical genes were determined to be antimetamorphic factors.
An endoparasitoid wasp, Cotesia plutellae parasitized young larval of diamondback moth, Plutella xylostella. Parasitized larva exhibit significant immunosuppression and fail to metamorphose to pupal stage. Especially, during last instar of parasitized P. xylostella, massive nutrients divert from host to wasp development. HTIF (host translation inhibitory factor) encoded in C. Plutella bracovirus (CpBV) play a crucial role in suppressing host usage of amino acids. However, its inhibitory activity is selective by discriminating mRNAs based on their 5’UTR secondary structures. Our RT-PCR and proteomic analysis indicated that arginine kinase mRNA was inhibited by HTIF, but imaginal disc growth factor was not. Arginine kinase and IDGF were persistently expressed in parasitized P. .xylotella with the gradual decrease at the late parasitisation period. Expression of arginine kinase and IDGF were also tissue specific in the gut/epidermis and haemocyte but not in fat bodies. Subsequent analysis of these gene functions by RNA interference explained the benefit of parasitoid for the mRNA discrimination by HTIF.
A polydnavirus, Cotesia plutellae bracovirus (CpBV), possesses segmented genome located on chromosome(s) of an endoparasitoid wasp, C. plutellae. An episomal viral segment (CpBV-S3) consists of 11,017 bp encoding two putative open reading frames (ORFs). ORF301 shows amino acid sequence homologies (28~50%) with RNase T2s of various organisms. It also contains BEN domain in C-terminal region. ORF302 is a hypothetical gene, which is also found in other bracoviruses. Both genes were expressed in larvae of Plutella xylostella parasitized by C. plutellae. ORF301 and ORF302 were transiently expressed in hemocyte, fat body, gut, and epidermis of P. xylostella. To analyze effects of these genes on the parasitism, the segment of CpBV-S3 was injected to non parasitized larvae of P. xylostella, in which the two genes were expressed at least for four days post-injection. The P. xylostella larvae injected with CpBV-S3 exhibited significant immunosuppression, such as reduction in total hemocyte population, suppression of immune associated genes including cecropin, pro-phenoloxidase (PO) and serpin1, and impairment in nodule formation behavior of hemocytes in response to bacterial challenge. Each gene expression in the treated larvae was inhibited by co-injecting respective double strand RNA (dsRNA) specific to each ORF. Injection of dsRNA of ORF301 could rescue the immunosuppression by the viral segmenttreated larvae, but not by ORF302 specific dsRNA. The larval injected with CpBV-S3 exhibited an enhanced susceptibility to baculovirus infection. These results indicate that ORF301 of CpBV-S3, which containing BEN domain, suppresses both cellular and humoral immune responses in P. xylostella.
DNA in the eukaryotic nucleus is packaged into highly organized chromatin. The basic structural unit of chromatin is the nucleosome, which consists of approximately 146 base pairs of DNA wrapped around a histone octamer core containing two molecules each of core histones H2A, H2B, H3, and H4. Histone covalent modification at the protruding N-terminal region from the nucleosomal core can change the chromatin conformation in order to regulate gene expression. A viral H4 was found in the genome of Cotesia plutellae bracovirus (CpBV). The obligate host of the virus is an endoparasitoid wasp, C. plutellae, which parasitizes the diamondback moth, Plutella xylostella, and interrupts host development and immune reactions. CpBV-H4 has been regarded as an immunosuppressive gene. Its extended N-terminal region contains nine lysine residues which are the target for modification. Previous report showed that CpBV-H4 inhibited hemocyte-spreading after transient expression. Here, transient expression of truncated CpBV-H4 (without N-terminal region) did not show high inhibitory effects on hemocyte-spreading. Moreover, the truncated CpBV-H4 induced acetylation of nucleus histone H4. Host H4 was found to be decreased in transcription after parasitization compared to nonparasitized larvae. Atransient expression of CpBV-H4 significantly inhibited host H4 transcription, suggesting a role of CpBV-H4 in controlling gene expression. Point mutagenesis study showed that two lysines (K6 and K16) of CpBV-H4 were found to have high inhibitory effects on hemocyte spreading. These results indicate the importance of CpBV-H4 and its N-terminal region to control gene expression and suppress host immunity.
Inhibitor <SUB>K</SUB>B (I<SUB>K</SUB>B)-like gene has been found ill the genome of Cotesia plutellae bracovirus (CpBV), which is the obligatory symbiont of an endoparsitoid wasp, C. plutellae. The open reading frame of CpBV-I<SUB>K</SUB>B was 417 bp and encoded 138 amino acids. Four ankyrin repeat domains were found in CpBV-I<SUB>K</SUB>B, which shared high homology with other known polydnavirus I<SUB>K</SUB>Bs. Considering a presumptive cellular I<SUB>K</SUB>B based on Drosophila Cactus, CpBV-I<SUB>K</SUB>B exhibited a truncated structure with deletion of signal-receiving domains, which suggested its irreversible inhibitory role in NF<SUB>K</SUB>B signal transduction pathway of the parasitized host in response to the wasp parasitization. CpBV-I<SUB>K</SUB>B was expressed only in the parasitized diamondback moth, Plutella xylostella. Its expression was estimated by quantitative RT-PCR during parasitization period, showing a constitutive expression pattern from the first day of parasitization. An indirect functional analysis of CpBV-I<SUB>K</SUB>B was conducted and suggested a hypothesis of host antivirus inhibition.