Molecular diagnostic markers are necessary for establishing highthroughput screening systems to support insecticide-resistant population management. Here, we identified single amino acid substitution mutations related to carbamate resistance in Laodelphax striatellus Fallén type-1 acetylcholinesterase (Lsace1) using carbofuran-selected strains. The phenotypic resistance profiles of the final selection strain (SEL9) compared to the susceptible strain revealed a 14-fold higher resistance ratio based on topical application, 1.2-fold higher general esterase activity, and 4.3- fold higher acetylcholinesterase insensitivity based on the 50% inhibitory concentration (I50), suggesting that insensitivity of the target site could occur as a resistance factor. Comparison of the nucleotide sequences of Lsace1 of five strains (SUS, SEL0, SEL3, SEL6, and SEL9) revealed two amino acid substitutions (F330Y and F331H). To understand the roles of these mutations, we determined the allele frequency of both point mutations in the selected strains using quantitative sequencing methods. In addition, several quantitative genotypic traits (e.g., gene copy numbers and transcript levels of Lsace1, Lsace2, and LS.CarE1) were assessed. A correlation analysis of genotypic and phenotypic traits revealed strong correlations between resistance level and I50 with F331H allele frequency. Interestingly, the F331H mutation was negatively correlated with transcript levels of Lsace1, suggesting that selection pressure might result in a reduction of the target gene. Overall, the F331H mutation and reduced mRNA are important factors in the development of carbamate resistance. Furthermore, the point mutation can be used to monitor rapid carbofuran resistance in conjunction with molecular diagnostic methods such as quantitative sequencing.

To identify the venom components and their expression patterns of some Aculeata bees/wasps, venom gland-specific transcriptome analysis was conducted. FPKM values were normalized with the average of the transcription level of reference gene (a-tubulin). Common components in both solitary and social wasp venoms include hyaluronidase, phospholipase A2, metalloendopeptidase, etc. Although it has been expected that more diverse bioactive components with the functions of prey inactivation and physiology manipulation are present in solitary wasps, the information on venom compositions of solitary wasps obtained in this study was not sufficient to generalizae this notion. Nevertheless, some neurotoxic peptides (e.g., pompilidotoxin and dendrotoxin-like peptide) and proteins (e.g., insuline-like peptide binding protein) appear to be specific to solitary wasp venom. In contrast, several proteins, such as venom allergen 5 protein, venom acid phosphatase, and various phospholipases, appear to be relatively more abundant in social wasp venom. In the venom gland trancsriptome of bumblebees, major allergens or pain producing factors were barely identified, implying that bumblebee venoms are relatively less toxic than those of social or solitary wasps.

The honey bee soluble acetylcholinesterase 1 (AmAChE1) is overexpressed under the overwintering and brood rearing-suppressed conditions. To investigate the role of AmAChE1 in regulating acetylcholine (ACh) titer, ACh concentrations both in the head (neuronal) and abdomen (non-neuronal) were analyzed. ACh titer was significantly lower in both tissues of worker bees under the overwintering and brood rearing-suppressed conditions compared to control bees. The expression levels of another two factors that regulate ACh titer, choline acetyltransferase (AmAChT) and acetylcholinesterase 2 (AmAChE2), were not altered as judged by qPCR and native PAGE, suggesting that the lower ACh titer was mainly regulated by AmAChE1. For precise verification of AmAChE1 as an ACh titer regulator, honey bees were put under brood rearing-suppressed condition to induce AmAChE1 and injected AmAChE1 dsRNA to knock down the gene. The ACh titer of AmAChE1-knocked down honey bees was 1.9 and 2.6 folds higher than that of control bees in head and abdomen, respectively. Taken together, in spite of its extremely low catalytic activity, the overexpression of AmAChE1 is likely to be related with the low level of ACh homeostasis, perhaps via ACh sequestration, under brood rearingsuppressed condition, and likely induce metabolic changes through ACh receptors-related pathways.

Lately, CRISPR-Cas9 has become one of the most essential tools to understand gene’s function. In the honeybee, however, the application of CRISPR technology has been hindered by various factors leading to very few reports of success in genome editing. Among these, collection of honeybee embryos for microinjection has been a time-consuming procedure, mainly limiting the applicability of the genome editing technique to honeybees. To improve the drawbacks of the conventional plastic plug-based system, we have developed a film-assisted honeybee embryo collection system (FECS) using transparent film as a detachable bottom layer. In this new system, eggs are laid on the detachable film surface and collected in a batch, and thus no additional alignment is required for microinjectoin. As the film can be easily replaced with in a few seconds, embryo collection can be repeated continuously after a single caging of a queen. Also, unlike conventional plug-based systems, the new system utilizes 100% of the eggs laid by the queen, thereby increases the yield three times in theory. The main unit of the system can be printed with ordinary SLA/DLP type 3D printer and the stl file for 3D printing will be distributed online.

RNA interference (RNAi)-based strategy has been developed to control various phytophagous chewing pests. However, only a few cases of RNAi-based control success have been reported for sucking pests, suggesting that sucking pests likely ingest less amount of transgenic subcellular hairpin RNA (or dsRNA). In this study, as the basic information for the establishment of ingestion RNAi against sucking pests, feeding amount and time course of plant subcellular fractions of the four sucking pest species (Frankliniella occidentalis, Frankliniella intonsa, Tetranychus urticae and Nilaparvata lugans) were determined by quantitative PCR (qPCR). Adults of the four species were starved for 24 h and then fed with kidney bean leaf (F. occidentalis, F. intonsa, T. urticae) or rice leaf (N. lugens) for 48 h. The leaf-fed adults were collected every 6-h interval and their genomic DNA was extracted. The ingested fractions of chloroplast and nuclear were quantified using rubisco and 50s rRNA as marker genes, respectively. The ingested amount of rubisco and 50s rRNA genes in F. occidentalis, F. intonsa and T. urticae showed rapid increasing pattern after feeding and then slightly reduced over time. In contrast, N. lugens neither ingest nuclear nor showed any distinct feeding pattern of chloroplast. These results demonstrate that F. occidentalis, F. intonsa and T. urticae ingest both chloroplasts and nucleus along with cytosol as cell-feeders but N. lugens, a phloem sap feeder, does not ingest nucleus during sucking. Our findings further suggest that ingestion RNAi-based control strategy would work better for cell-feeding sucking pests compared to phloem sap-feeding sucking pests.

Residual contact vial (RCV) method was used to monitor insecticide resistance in field populations of the melon thrips, Thrips palmi. Median lethal doses (LD50) at 8 h post-treatment of six insecticides (chlorfenapyr, cyantraniliprole, cypermethrin, dinotefuran, emamectin benzoate and spinosad), which are commonly used for T. palmi control, were determined at 8 h post-treatment using a susceptible RDA strain. The diagnostic doses for on-site resistance monitoring of the six insecticides, which were determined as two-fold higher doses of LD90 for the RDA strain, were in the range of 0.299 to 164,25 μg-1cm2. To test the applicability of RCV for T. palmi, insecticide resistance levels in three field populations (Gyeonggi; GG_AS, Chungbuk; CB_CJ, Jeonbuk; JB_KJ) were evaluated. Field populations showed reduced mortality (0-50% mortality) to spinosad, cypermethrin, cyantraniliprole and emamectin benzoate, that they have different degree of resistances to these insecticides. In particular, all test field populations exhibited 0% mortality to spinosad, suggesting wide spread of spinosad resistance in the field. Moreover, no detectable mortality to emamectin benzoate was observed in JB_KJ strain, suggesting uneven distribution of emamectin benzoate resistant population of T. palmi. To provide more precise information on resistance profiles and distribution in T. palmi populations, it would be necessary to conduct a large scale resistance mapping for broad geographical regions.

Laodelphax striatellus is an important pest of rice due to not only sucking rice seedlings, but also transmitting serious plant viruses. Among various kinds of insecticide groups (carbamates, organophosphorus, neonicotinoids, etc.), carbofuran, a systemic carbamate insecticide, has been most extensively used to control rice pests including L. striatellus, resulting in widespread carbamate resistance in Korea and other Northeast Asia countries. To identify the genes associated with carbofuran resistance, we obtained a 14-fold higher resistant strain (SEL9) from the mixed-field population (SEL0) by consecutive selection. A transcriptome-based analysis was conducted and differentially expressed genes (DEG) were compared between the SEL9 and SEL0 strains. A total of 96,185,150 reads were analyzed, of which 62,860,430 reads were mapped. From these reads, 15,356 transcripts were annotated. A total of 327 up-regulated and 275 down-regulated genes were identified in the resistant SEL9 strain compared to SEL0 strain by DEG analysis. Gene ontology (GO) analysis was performed using DEGs showing statistical significance (P < 0.05). The GO analysis identified 1,320 genes in biological process group, 1,100 genes in cellular component group and 428 genes in molecular_function group.

Frankliniella occidentalis is a notorious polyphagous crop pest causing tremendous economic loss. It damages flowers and leaves of host plants and also carries severe plant viruses. During last few decades, it has spread to all continents via transport of plant materials. Following extensive use of insecticides to control F. occidentalis, it has developed high level of resistance due to its short life cycle and high reproductive potential. In this study, RNA interference (RNAi)-based bioassay system was developed to find an alternative control measure for insecticide-resistant population of F. occidentalis. A variety of genes involved in various physiological mechanisms were selected for the test of dsRNA potency (tubulin, v-ATPase, amylase, aquaporin etc.). Each bioassay unit made by 3D printing has a leaf disc placed on 150 ㎕ of 50 ng/ul dsRNA solution and 20 thrips. The mortality was checked, and the dsRNA and leaf disc were replaced every 24 h for 72 h. Of the 20 genes tesetd, tubulin, v-ATPase, and aquaporin showed 31, 38, 38 and 45% of corrected mortality at 72 h post-treatment, respectively. This result suggests the potential of these genes as candidate lethal genes for RNAi-based F. occidentalis control system.

4,4’-dichlorodiphenyltrichloroethane (DDT) has been re-recommended by the World Health Organization for malaria mosquito control in Africa. Previous DDT use has resulted in predisposition of resistance, and with continued use resistance will increase further in terms of level and extent. Drosophila melanogaster is a model dipteran that has many available genetic tools, has been widely used for elucidating insecticide resistance mechanisms, and is related to malaria mosquitoes allowing for extrapolation. The 91-R strain of D. melanogaster is highly resistant to DDT (>1500-fold); however, there is no mechanistic scheme that accounts for this level of resistance. Recently, reduced penetration, increased detoxification, and direct excretion have been identified as resistance mechanisms in the 91-R strain. Their interactions, however, remain unclear. Use of Gal4/UAS-RNAi transgenic lines of D. melanogaster allowed for the targeted knockdown of genes putatively involved in DDT resistance and has identified the role of several cuticular proteins (Cyp4g1 and Lcp1), cytochrome P450 monooxygenases (Cyp6g1 and Cyp12d1), and ATP binding cassette transporters (mdr50, mdr65, and mrp1) in increased sensitivity to DDT. These findings have been further validated in 91-R flies using a nanoparticle-enhanced RNAi strategy, directly implication these genes in DDT resistance in 91-R flies.

Small hive beetle (Aethina tumida) (SHB) is an invasive species to most northern hemisphere countries, including Korea. In an attempt to obtain basic information for efficient management of SHB, genes encoding conventional insecticide targets [voltage-sensitive sodium channel α-subunit (VSSC) and acetylcholinesterase (AChE)] were annotated and characterized following the analysis of whole transcriptomes of adults and larvae. A single VSSC gene was identified but no apparent mutations associated with pyrethroid resistance were detected. Genes encoding two AChEs (AtAChE1 and AtAChE2) were identified from the SHB transcriptome. AtAChE1 was determined to be the main catalytic enzyme, thereby being a toxicologically more relevant target. No apparent mutations associated with resistance to organophosphorus and carbamate insecticides was identified in the AtAChE1 gene, whereas the S238G mutation, originally identified from the Colorado potato beetle, was detected in the AtAChE2 gene.

The common bed bug, Cimex lectularius, possesses a cholinesterase expressed exclusively in the salivary gland (ClSChE). In this paper, we investigated the molecular structure, tissue distribution patterns, and biochemical properties of ClSChE and showed that ClSChE exists as a soluble monomeric form or a soluble dimeric form connected by a disulfide bridge. Immunohistochemical analysis confirmed that ClSChE was expressed in the epithelial cells of both the salivary gland and the duct. In addition, the secretion of monomeric ClSChE through the proboscis during feeding was detected by western blotting using a ClSChE-specific antibody. To predict the role of ClSChE injected into the tissue of an animal host, we analyzed the extent of sequestration and hydrolysis of acetylcholine (ACh)/choline (Ch) by ClSChE by ultra-performance liquid chromatography-tandem mass spectrometry. Kinetic analysis revealed that ClSChE possesses extremely low Km (high affinity to ACh) and Vmax values. These findings suggest that ClSChE functions as a sequestering enzyme specific to ACh (not to Ch) by having a very strong affinity to ACh but an extremely long turnover time.

The honey bee soluble acetylcholinesterase 1 (AmAChE1) is overexpressed under the overwintering and brood rearing-suppressed conditions. To investigate the role of AmAChE1 in regulating acetylcholine (ACh) titer, ACh concentrations in both the head (central nervous system) and abdomen (peripheral nervous system) were analyzed. ACh titer was significantly lower in both tissues of worker bees under the overwintering and brood rearing-suppressed conditions compared to control bees. Interestingly, the expression levels of choline acetyltransferase (AmChAT) and molecular marker genes of immune systems were significantly reduced in honey bee head under the same conditions. Taken together, ACh titer appears to be reduced via a cooperative interaction of the AmAChE1 overexpression and AmChAT underexpression and to be linked to reduced inmmune responses under the overwintering and brood rearing-suppressed conditions. The roles of AmAChE1 (with little catalytic activity) and AmChAT in the ACh homeostasis and signaling was discussed in the contexts of immune response and longevity regulation in honey bees.

Honey bee has been widely used as a model insect for biological sciences because of its sociality and specialized labor division. For the investigation of the seasonal and labor-dependent expression patterns of genes putatively involved in its sociality, quantitative real-time PCR (qRT-PCR) can be applied to quantify gene expression level and selection of reliable reference gene(s) for normalization is an accurate step. In this study, using three softwares (geNorm, NormFinder and BestKeeper), we evaluated seasonal expression stabilities of four reference genes that have been widely used for qRT-PCR in forager and nurse heads. Among four candidates, two genes, rpS18 and gapdh, were suggested to be the optimal reference genes for qRT-PCR.

소나무재선충(pine wood nematode, PWN) 감염 소나무를 현장에서 신속하게 진단을 할 수 있는 방법은 현재 없다. 본 연구에서는 PWN특이적인 항원으로 알려진 PWN-GaLectin을 baculovirus발현체계로 발현시켜서 총 1,464개의 fusion hybridoma 세포 주 라이브러리 를 제작 하는 항원으로 이용하였다. 총 1,464개의 fusion hybridoma 세포 주 중, PWN-GaLectin에 대한 높은 반응을 보이는 62개의 fusion hybridoma 세포 주를 선별했다. 이들 중, 표준 PWN 감염소나무 PBS추출물과 PWN 단백질 추출물에 강한 반응을 보이는 세포 주 12개를 선 별하여 단클론 항체(monoclonal antibody, Mab) 분비세포 주 확립을 위한 limited dilution을 실시하였다. Mab분비세포 주 확립을 위해서 표 준 PWN 감염소나무 추출물에 대한 반응이 표준 정상 소나무 추출물 보다 높은 세포 주들을 선별했다. 그리고 추가로 PWN 단백질 추출물에 대 해서 3종의 비 병원성 선충 단백질 추출물 보다 높은 반응을 보이는 세포 주들도 선별, 확립했다. 본 연구에서 확립된 Mab들을 우리는 현장과 실 험실에서 사용할 수 있는 신속진단키트의 개발에 이용할 수 있을 것이다.

It is necessary to understand of temporal and spatial dynamics by establishing a periodical monitoring system for theproper management in small brown planthopper (SBPH). A dataset is including the number of SBPHs by location, collectionmethod [aerial collection net (AeCN) or light trap (LT)] and period (May~Aug.) for five years (2011~2015), and missingvalues were imputed using multiple imputation methods. Of the 15,848 individuals collected, approximately 47% and 52.9%were collected using the AeCN and LT methods, respectively. A high incidence of migratory SBPHs was observed duringJulian days 144-166 using the AeCN method. Generally, the migratory SBPHs from China composed 39.4% of the totalpopulations of SBPHs. These results would provide valuable information to predict the incidence period of migratory SBPHsand establish a proactive management system against SBPH.

We compared the genetic structures of overwintered indigenous Korean and Chinese populations. The eight Koreanpopulations consisted of 33 haplotypes, and 16 haplotypes were newly identified. The genetic diversity of the Koreanpopulation revealed high haplotype diversity and low nucleotide diversity of 0.86 and 0.0024 on average, respectively,due to the high dispersal ability, which is similar to that of the Chinese population (Sun et al., 2015). Comparison with30 Chinese populations using a population tree showed that the Korean populations grouped with 12 Chinese populationsand that 67% were located near Jiangsu province. Moreover, the three frequent migration regions by migratory SBPH,including the Buan, Shinan and Taean counties, were grouped together with high supporting values. These results mightsupport the presence of gene flow between the Korean and Chinese populations by migratory SBPHs.

Biological activities of bombolitins from Bombus ardens, B. consobrinus, B. terrestris and B. ussurensis (bombolitinsA, C, T and U, respectively) were examined using hemolytic, anti-microbial, anti-fungal and anti-tumor activity assays.Among the four bombolitins tested, bombolitin T showed the highest hemolytic and anti-tumor activities. All bombolitinsexhibited strong anti-microbial and anti-fungal activities, and bombolitin A specifically possessed the highest anti-microbialactivity against the Gram-negative bacteria Escherichia coli. Circular dichroism spectrometry analysis revealed that allfour bombolitins had over 61.7% and 45.5% of α-helicity in 30 mM sodium dodecyl sulfate and 50% trifluoroethanolbuffers, respectively, which form lipid-membrane-mimicking environments. Bombolitin T showed the lowest IC50 valuesof 8.5 μM and 8.8 μM against SK-OV-3 and NIH-OVCAR-3 cell lines, respectively, after 72 h of treatment, but itsrelative hemolytic activity at a concentration of 200 μM was 2.3-fold higher than that of 0.1% Triton X-100. Thisstudy provides new information on the biological and molecular properties of venom peptides of bumblebees. However,further studies on reducing cytotoxicity of bombolitins are needed for designing selective anti-tumor peptides.

Among two different acetylcholinesterase (AmAChE1 and AmAChE2) of the western honey bee, the soluble AmAChE1might be related with a stress response as judged from its over-expression in honey bee workers when brood rearingwas suppressed. In this study, to ensure the nature of AmAChE1 responding to stress factors, the expression patternsof AmAChE1 were investigated following various treatments, including varroa mite infestation, bacterial challenge, broodrearing suppression, thermal stresses, chemical treatments, ultraviolet B irradiation, starvation, water restriction and crowdingstress. In addition, transcription profiles of four heat shock protein genes known as general stress markers and vitellogeningene, which is induced in several stress conditions, were tested as positive references. In every tested condition, onlybrood rearing suppression and heat shock were related with the expression of AmAChE1.

To identify genes that commonly respond to the treatment of different insecticides and are responsible for the toleranceenhancement, transcriptomic profiles of larvae treated with sublethal doses of the five insecticides were compared withthat of untreated control. A total of 117,181 transcripts with a mean length of 662 bp were generated by de novo assembly,of which 35,329 transcripts were annotated. Among them, 125, 143, 182, 215 and 149 transcripts were determined tobe up-regulated whereas 67, 45, 60, 60 and 38 genes were down-regulated following treatments with these five insecticides.The most notable examples of commonly responding over-transcribed genes were two cytochrome P450 genes and ninecuticular protein genes. In contrast, several genes composing the mitochondrial energy generation system were significantlydown-regulated in all treated larvae. Considering the distinct structure and mode of action of the five insecticides tested,the differentially expressed genes identified in this study appear to be involved in general chemical defense at the initialstage of intoxication. Their possible roles in the tolerance/resistance development were discussed.

Honey bee swarming is a natural phenomenon that occurs by changes of colony (i.e. population size and queen condition) and environment conditions. As cuticular hydrocarbons (CHCs) are known to be involved in the communication between honey bee nest-mates, we investigated and compared the CHC profiles of worker bees from individual colonies of 9-days before swarming (PPSC), a day before swarming (PSC), swarming (SG) and remaining (non-swarming) (RG). A total of 53 CHCs were identified by GC-MS, among which 11 compounds showed significantly differential expression patterns between swarming states. Before swarming (between PPSC and PSC), detection levels of 4 CHCs were significantly different, suggesting that production of some CHCs changed prior to swarming for swarming preparation. Six CHCs were deferentially produced between PSC and RG. The differential profiles of CHCs with respect to different swarming states are currently under investigation.