Virus infections of the honeybee(Apis mellifera) have been increasingly investigated during the last decade. In general, honeybee viruses are widespread and most of them persist as inapparent infections. We screened honeybee colonies for the presence of several bee viruses, including deformed wing virus(DWV), black queen virus(BQCV), Kashmir bee virus(KBV), Israeli acute paralysis virus (IAPV), sacbrood virus(SBV), acute bee paralysis virus(ABPV), using uniplex RT-PCR. Frequently simultaneous infections with different viruses are diagnosed in seemingly healthy bee colonies. Therefore we developed a multiplex RT-PCR assay for the simultaneous detection of multiple bee viruses.

Sacbrood virus (SBV) is one of the most serious honeybee viruses. The virus causes failure to pupate and death in both larvae and adult bees. Recently, Korean Sacbrood virus (KSBV) caused a great loss in Korean honeybee (Apis cerana) colonies. Although KSBV shows high homology with SBV strains, it has unique motifs and causes different symptoms. Therefore, a simple, sensitive and specific method for detecting KSBV is needed urgently. In this study a reverse transcription loop-mediated isothermal amplification (RT-LAMP) and a novel micro PCR-based detection method, termed ultra-rapid real-time PCR (URRT-PCR) were applied for rapid detection for korean sacbrood virus (KSBV) from honeybees (Apis cerana) infected with SBV in Korea. The LAMP could be detect the virus in RT-LAMP reactions containing 102copies of pBX-KSBV within 30 min, which was 10 times more sensitive than a RT-PCR assay. The URRT-PCR showed high sensitivities which were able to detect 10 copies in the standard assays. In the application of URRT-PCR detection to an KSBV-infected honeybee, the shortest detection time was 10 min 12 sec, including reverse transcription. In addition, these methods could be distinguished between KSBV and other closely-related SBV strains, These rapid methods were rapid molecular-based diagnostic tools and useful tool for the rapid and sensitive diagnosis of KSBV infection of honeybees.

Sacbrood virus (SBV), a causative agent of larval death in honeybees, is one of the most devastating diseases in bee industry throughout the world. Lately the Korean Sacbrood virus (KSBV) induced great losses in Korean honeybee (Apis cerana) colonies. However, there is no culture system available for honeybee viruses, including SBV, therefore, the research on honeybee viruses is practically limited until present. In this study, we investigated the growth and replication of KSBV in cell cultures. The growth of KSBV was demonstrated by RT-PCR, quantitative real-time PCR, TEM and nucleotide sequence analysis. The results demonstrated that SBVshowed the replication signals in mammalian cell lines, including Vero cells without any signs of cytopathic effect (CPE). The results of RT-PCR, quantitative real-time PCR and in vivo infection with KSBV were also indicated the replication. Phylogenetic tree analysis shows our sequence included in distinct group with other SBV strains from China and Korea. It clearly showed the differenciation between field strain and attenuated strain through cell culture. The results of present study demonstrated for the first time that SBV like other animal viruses could be adapted and attenuated in cells through the sequential passages. The sequential adaptation through cell culture could result in discrepancy of pathogenicity of virus and morphological characterization. For this reason, the present results indicated that the cell adapted SBV could be a valuable tool to study the general properties of this emerging virus, including pathogenicity in the future.

Eugenol은 많은 식물에서 eugenol synthase에 의해 생합성되는 phenylpropene 계통의 휘발성 화 합물이다. 그러나, 토마토 과실에서의 특징은 밝혀져 있지 않다. 이에 따라 토마토 ‘Micro-Tom'으로 부터 RACE 기법을 이용하여 완전장 cDNA를 클로닝 하여, SlEGS라 명명하였다. SlEGS의 open reading frame은 921bp로, 307개의 아미노산 서열을 갖는 단백질로 번역되었다. BLAST 결과에 따라 SlEGS는 PhEGS1 및 CbEGS2와 각 67.1, 69.4%의 높은 상동성을 갖는 것으로 나타났다. CLC genomics workbench 프로그램을 이용하여 SlEGS의 아미노산 구성을 분석하였고, Swiss-PDB viewer 프로그램에서 homology modeling 기법으로 SlEGS의 3차원 단백질 구조를 구축한 후 ProSA-web 툴로 3차원 구조의 안정성을 확인 하였다. 또한 ExPASy의 ProtParam 툴을 이용하여 SlEGS의 생리화학적 특성을 분석 하였다. SlEGS의 추정 분자량은 33.93kDA이고 등전점(pI)은 5.85 로 산성인 것으로 나타났다. 이와 더불어 SlEGS의 흡광 계수(EC), 불안정성 지수(II), alipathic 지수 (AI), GRAVY값 등의 생리화학적 특성에 대한 분석을 실시 하였다.