• 한국응용곤충학회지
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• 제47권2호
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• pp.175-184
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• 2008

국내의 난방제 해충에 선택적으로 생물활성을 나타내는 균주를 선발하기 위하여 작물재배 지역의 토양으로부터 채취한 115개의 토양샘플 중 46개의 Bacillus thuringiensis 균주를 분리하였다. 이러한 B. thuringiensis균주를 사용하여 난방제 농업해충에 생물활성을 검정한 결과 배추좀나방(Plutella xylostella)에 CAB119을 포함한 35균주, 파밤나방(Spodoptera litura)에는 CAB128, CAB141균주가, 담배거세미나방(Spodoptera exigua)은 CAB133과 CAB159균주가 효과를 나타냈으며 CAB162균주는 3종류의 모든 해충에 높은 활성을 보였다. 분리된 B. thuringiensis CAB133 균주는 H serotype에 의한 혈청학적 동정과 SDS-PAGE를 통한 독소 단백질 패턴에서 B. thuringiensis subsp. kurstaki (3abc)로 동정되었다. 담배거세미나방 2령 유충에 대한 활성검정의 결과 B. thuringiensis subsp. kurstaki (3abc) CAB133, CAB162의 두 균주에 대한 $LD_{50}$ 값은 각각 0.089, $3.144{\mu}g/ml$로 높은 활성을 나타났다. 담배거세미나방의 령기에 따른 생물실험에서 CAB133 균주 $1.5{\times}10^6(cfu/ml)$에서 1령의 경우 3일, 2령은 5일에 100%의 사충율을 보였다. 담배거세미나방의 경우 B. thuringiensis를 섭식 후 먹기를 중단하여 성장이 멈추면서 $5{\times}7$일 후에 사망하였다. 그러므로 B. thuringiensis의 결정성독소단백질$(1.267{\mu}g/ml)$를 섭식하고 성장하지 못하는 담배거세미나방 유충의 무게는 대조군보다 5일후 약 30배정도 차이로 나타나서 사망하였다.

• 한국미생물·생명공학회지
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• 제19권1호
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• pp.25-30
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• 1991

국내농작물의 근부토양으로 분리한 Pseudomonas의 염색체 DNA에 Tn5를 사용하여 Bacillus thuringiensis subsp. kurstaki HD73의 독소유전자(cp)를 도입하였다. Tn5의 중심부위에 있는 BamHI위치 (Tn5-cp)와 BglII 위치 (IS5OL-cp)에 각각 독소유 전자를 도입하였으며 두 종류의 Pseudomonas 균주에는 Tn5-cp로써 그리고 다른 세 종류의 Pseudomonase 균주에는 IS5OL-cp로써 transposition하였다. 면역학적 방법과 흰불나방 애벌레에 대한 살충성 검정으로서 독소유전자의 도입과 발현을 확인하였다.

• Journal of Microbiology and Biotechnology
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• 제4권4호
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• pp.322-326
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• 1994

Bacillus thuringiensis strain BT-14 was isolated from alfalfa dust in Korea. The strain BT-14 produced one bipyramidal crystal and one spore in the cell. The biochemical characteristics of the strain BT-14 were similar to those of Bacillus thuringiensis subsp. kurstaki HD-l. Examination of its antibiotic resistance revealed that while the strain BT-14 was less resistant than BTK HD-l to ampicillin, gentamycin, neomycin and tobramycin, it was more resistant to amikacin than BTK HD-l. The $\delta$-endotoxin crystal of strain BT-14 consisted of a single protein with a high molecular weight of ca 135 KD on a 10% SDS-PACE. The strain BT-14 contained at least nine different plasmids with sizes of 2.9, 5.3, 5.8, 6.2, 9.4, 15.1, 18.1, 23.1 and 79 Kb. In insect bioassay, the isolated strain BT-14 showed lethality of 67% against Plutella xylostella larvae at dilution of 5$\times$$l0^{-4}$ (5$\times$l0 to 3$\times$$l0^2$ spores/ml), which is, almost equivalent to that of BTK HD-l.

• 한국미생물·생명공학회지
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• 제25권6호
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• pp.566-570
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• 1997

During sporulation, Bacillus thuringiensis strains produce crystals consist of toxin proteins highly specific against insect pests. Their host specificities are desirable from a standpoint of environmental safety, but also limit market potential. Thus, development of improved Bacillus thuringiensis strains having broad host spectrum will contribute to increase its use. For the construction of Bacillus thuringiensis strain having broad host spectrum, we cloned cry1C gene encoding a toxin protein highly toxic against Spodoptera exigua from a B. thuringiensis isolate and constructed two recombinant plasmids, pUBClC and plC60. The plasmid PUBC1C has a replication origin of the natural plasmid pBC16 from B. cereus which is closely related species to B. thuringiensis, and the pBC16 was known to be replicated by rolling-circle mechanism. The plasmid pIC60 has a replication origin of a resident 60 MDa plasmid from B. thuringiensis subsp. kurstaki HD263, and it is believed that the pIC60 is replicated in a theta mode. The two plasmids were introduced into B. thuringiensis subsp. kurstaki cryB strain, and the transformed strains produced well-shaped bipyramidal crystals. We confirmed the expression of the cry1C gene by SDS-PAGE, and Western blotting. By investigating the segregational stability, it was found that the plasmid pIC60 is more stable than the pUBC1C.

• Journal of Microbiology and Biotechnology
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• 제8권6호
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• pp.685-691
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• 1998

Baculovirus Hyphantrin. cunea nuclear polyhedrosis virus (HcNPV) insecticide containing the insecticidal protein (ICP) gene from Bacillus thuringiensis subsp. kurstaki HD1 was constructed using a lacZ-HcNPV system. The ICP ($\delta$-endotoxin) gene was placed under the control of the polyhedrin gene promoter of the HcNPV. A polyhedrin-negative virus was derived and named ICP-HcNPV insecticide. Then, the insertion of the ICP gene in the ICP-HcNPV genome was confirmed by Southern hybridization analysis. Polyacrylamide gel electrophoresis (PAGE) analysis of the Spodoptera frugiperda cell extracts infected with the ICP-HcNPV showed that the ICP was expressed in the insect cells as 130 kDa at 5 days post-infection. The ICP produced in the cells was present in aggregates. When extracts from the cells infected with the ICP-HcNPV were fed to 20 Bombyx mori larvae, the following mortality rate was seen; 8 larvae at 1 h, 10 larvae at 3 h, and 20 larvae at 12 h. These data indicate that the B. thuringiensis ICP gene was expressed by the baculovirus insecticide in insect cells and there was a high insecticidal activity. The biological activities of the recombinant virus ICP-HcNPV were assessed in conventional bioassay tests by feeding virus particles and ICP to the insect larvae. The initial baculovirus insecticide ICP-HcNPV was developed in our laboratory and the significance of the genetically engineered virus insecticides is discussed.

• International Journal of Industrial Entomology and Biomaterials
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• 제1권2호
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• pp.123-129
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• 2000

Expression of the crylAcl gene of an acrystalliferous Bacillus thuringiensis strain under the control of the native or $\alpha$-amylase gene promoter was investigated. The crylAcl gene was cloned in a B. thuringiensis - E. coli shutle vector, pHT3101, undder the control of either the native promoter (pProAc) or the $\alpha$-amylase promoter from Bacillus subtilis (pAmyAc). These two recombinant plasmids were successfully expressed in B. thuringiensis subsp. kurstaki Cry B. The first transformant (ProAc/CB), harboring pProAc, expressed an about 130 kDa protein begining 24 hr after inoculations just as in the case of the wild type of B. thuringiensis subsp. kurstaki HD-73. The second pAmyAc-transformant (AmyAc/CB) began to express the gene just 6 hr after inoculation, but Western analysis showed that the activity of the $\alpha$-amylase promoter was relatively weaker than that of the native promoter. As expected, their toxicity against Plutella xylostella larvae was dependent on the amount of Cry1Acl protein expressed.

• 한국미생물·생명공학회지
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• 제17권4호
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• pp.295-300
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• 1989

B. thuringiensis가 생산하는 살충성 독소 단백질의 생태학적 응용방법을 개발하기 위한 목적으로 우선 독소 단백질 유전자를 옮겨 발현시키기에 적합한 숙주 미생물의 분리작업을 수행하였다. 국내 주요농산물인 고추, 감자, 무우 등 7가지 농작물의 뿌리부근에 군락을 형성하는 35종의 형광성Pseudomonas들을 분리하였고 독소 단백질 유전자를 함유하는 재조합 plasmid에 대한 숙주로서의 이응가능성을 검토해 보기 위하여 분리균주 35주에 대한 형질전환을 실시한 결과 4주에 독소 단백질 유전자의 도입이 가능하였고 생물검정과 면역학적인 방법 등에 의한 결과 BT 독소 유전자의 발현을 확인하였다.

• Journal of Microbiology and Biotechnology
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• 제1권4호
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• pp.240-245
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• 1991

We have constructed a promoter-probe vector pKU20 using pKT230, a derivative of broad-host-range plsmid RSF1010, as a base. The pKU20 contains structural gene for aminoglycoside phos-photransferase (aph), without promoter, and a multiple cloning site upstream the aph. Using this vector, a 412base pairs (bp) PstI fragment showing strong promoter activity both in Escherichia coli LE392 and Pseudomonas putida KCTC1644 has been cloned from Pseudomonas fluorescens chromosomal DNA on the basis of streptomycin resistance. The nucleotide sequence of the 412 bp fragment has been determined and the putative - 35 and -10 region was observed. Insecticidal protein gene of Bacillus thuringiensis subsp. kurstaki HD-73 inserted on downstream of the promoterlike DNA fragment was efficiently expressed in E. coli and P. putida. The toxin protein was efficiently synthesized in an insoluble form in both strains.

• 한국미생물·생명공학회지
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• 제26권6호
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• pp.497-506
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• 1998

Bacillus thurintensis subsp. kurstaki HD1 살충성 단백질 ICP 유전자가 있는 NdeI 단편 3.856 kb를 클로닝하여 제조한 pHLN2-80(-) 클론이 pHLN1-80(-)에 비해서 대장균에서 ICP발현량이 과다발현되는 현상을 규명하고자 하였다. 본 연구에서는 상기의 pHLN2-80(+) 클론의 발현량을 조절하는 원인을 규명하기 위하여 ICP의 아미노산 서열은 변화되지 않는 범위 내에서 pHLN1-80(+) 클론에 있는 Plac프로모터와 ICP유전자 프로모터의 일부인 -80 bp프로모터의 염기서열, 전사 개시점과 종결부위의 변이가 ICP유전자발현에 미치는 영향을 조사하였다. pHLN1-80(+)에 5'-말단에 존재하는 -80 bp 프로모터만을 보유한 pHLNK-80 클론은 ICP 생산은 매우 저조하였다. Plac프로모터와 -80 bp 프로모터의 구조 골격을 일부 변이 시킨 pHLNF1-80클론의 ICP생산량은 pHLN2-80(-)가 생산한 양보다는 낮아서 과다발현이 안되었다. Plac프로모터 상류를 약 350bp을 제거하여 만든 클론 pHLND2-80의 ICP 생산량은 모클론인 pHLN2-80(-) 보다 매우 높게 과다발현 되었다. ICP 유전자의 과다발현 현상에 대한 전사 개시점과 전사종결 부위의 역할을 알아보기 위해서 -72bp ICP유전자프로모터를 갖는 클론 pHLD1-72는 재조합 클론 pHLN2-80(-)가 생산한 양보다 적은 양의 ICP을 생성하였고, 클론 pHLD2-72는 재조합 클론 pHLN2-80(-)보다 적은 ICP을 발현하여 과다 발현되었으며, 클론 pHLN2-72는 모클론인 pHLN2-80(-)보다 약간 높은 ICP 생산량을 보여 과다발현되었다. 클론 pHLN2-72를증식하여 파쇄액을 만든 후에 Bombyx mori유충에 대한 살충력 검사에서 클론 pHLN2-72이 생산한 ICP는 pHLN1-80(+)이 생산한 ICP보다 약 90배의 살충력을 보였다. SDS-PAGE와 Western blot 분석에서도 클론 pHLN2-72는 재조합 클론 pHLN2-80(-)보다 약간 높게 ICP가 생성이 되었었다. 이상의 결과는 과다발현에 Plac프로모터와 종결부위가 반드시 필요하며, -72 bp ICP 프로모터가 -80 bp 프로모터보다 과다발현률이 높았으며, ICP 유전자는 반드시 Plac프로모터의 전사 방향에 역방향으로 삽입이 되어야 하는 것으로 나타났다.

• Journal of Microbiology and Biotechnology
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• 제17권4호
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• pp.547-559
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• 2007

Bacillus thuringiensis (Bt) was first described by Berliner [10] when he isolated a Bacillus species from the Mediterranean flour moth, Anagasta kuehniella, and named it after the province Thuringia in Germany where the infected moth was found. Although this was the first description under the name B. thuringiensis, it was not the first isolation. In 1901, a Japanese biologist, Ishiwata Shigetane, discovered a previously undescribed bacterium as the causative agent of a disease afflicting silkworms. Bt was originally considered a risk for silkworm rearing but it has become the heart of microbial insect control. The earliest commercial production began in France in 1938, under the name Sporeine [72]. A resurgence of interest in Bt has been attributed to Edward Steinhaus [105], who obtained a culture in 1942 and attracted attention to the potential of Bt through his subsequent studies. In 1956, T. Angus [3] demonstrated that the crystalline protein inclusions formed in the course of sporulation were responsible for the insecticidal action of Bt. By the early 1980's, Gonzalez et al. [48] revealed that the genes coding for crystal proteins were localized on transmissible plasmids, using a plasmid curing technique, and Schnepf and Whiteley [103] first cloned and characterized the genes coding for crystal proteins that had toxicity to larvae of the tobacco hornworm, from plasmid DNA of Bt subsp. kurstaki HD-1. This first cloning was followed quickly by the cloning of many other cry genes and eventually led to the development of Bt transgenic plants. In the 1980s, several scientists successively demonstrated that plants can be genetically engineered, and finally, Bt cotton reached the market in 1996 [104].