• IMMUNE NETWORK
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• 제1권3호
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• pp.187-195
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• 2001

The expression of recombinant proteins fused to 26 kDa glutathione S-transferase (GST) extracted from Schistosoma japonicum represents an attractive system for purifiying proteins of interest in a single step using GST-affinity chromatography. In addition, the GST-tag is used conveniently for detecting fused proteins since its high solubility as well as its relatively small size rarely interferes with the biological activity of the fused protein. In this regard, the GST system is frequently applied for tracing fusion proteins in both prokaryotic and eukaryotic cells to elucidate the physiological interactions and functional compartments of proteins. To provide a further tool in analyzing GST-fusion proteins, a new monoclonal antibody, with a high specificity to the S. japonicum GST was produced. Methods: BALB/c mice were immunized both with recombinant S. japonicum GST proteins, and by the fusion of splenocytes from these mice with myeloma cells. From this, a new anti -GST monoclonal antibody, termed SARAH, was generated. The specificity and reactivity of this antibody was confirmed by ELISA and by Western blot analysis. Results: SARAH showed a high reactivity to recombinant GST and GST fusion protein but not with native mammalian GST proteins as derived from other species including humans, cows, rabbits and rats. The applicability of SARAH was further demonstrated by confocal laser scanning microscopy, where GST proteins that were expressed transiently in mouse fibroblast cells, were specifically detected without interference of endogenous GST. Conclusion: SARAH is new monoclonal antibody with a high specificity to recombinant GST proteins but not to endogenous GST in mammalian cells.

• BMB Reports
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• 제31권1호
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• pp.77-82
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• 1998

To purify the geranylgeranyl protein transferase type I (GGPT-I) efficiently, a gene expression system using the pGEX-4T-1 vector was constructed. The cal1 gene, encoding the ${\beta}$ subunit of GGPT-I, was subcloned into the pGEX-4T-1 vector and co-transformed into E. coli cells harboring the ram2 gene, the ${\alpha}$ subunit gene of GGPT-I. GGPT-I was highly expressed as a fusion protein with glutathione S-transferase (GST) in E. coli, purified to homogeneity by glutathione-agarose affinity chromatography, and the GST moiety was excised by thrombin treatment. The purified yeast GGPT-I showed a dose-dependent increase in the transferase activity, and its apparent $K_m$ value for an undecapeptide fused with GST (GST-PEP) was $0.66\;{\mu}M$ and the apparent value for geranylgeranyl pyrophosphate (GGPP) was $0.071\;{\mu}M$.

• Biomolecules & Therapeutics
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• 제4권1호
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• pp.103-109
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• 1996

To investigate the effect of the third intracellular loop (i3 loop) peptide of human $\beta$$_2$-adrenergic receptor on receptor agonist binding, we expressed third intracellular loop region of human $\beta$$_2$-adrenergic receptor as glutathione S-transferase fusion protein in E. coli. DNA fragment of the receptor gene which encodes amino acid 221-274 of human $\beta$$_2$-adrenergic receptor was amplified by polymerase chain reaction and subcloned into the bacterial fusion protein expression vector pGEX-CS and expressed as a form of glutathione-S-transferase (GST) fusion protein in E. coli DH5$\alpha$. The receptor fusion protein was identified by SDS-PAGE and Western blot using monoclonal anti-GST antibody. The fusion protein expressed in this study was purified to an apparent homogeneity by glutathione Sepharose CL-4B affinity chromatography. The purified i3 loop fusion proteins at a concentration of 10 $\mu\textrm{g}$/ι caused right shift of the isoproterenol competition curve of [$^3$H]Dihydroalprenolol binding to hamster lung $\beta$$_2$-adrenergic receptor indicating lowered affinity of isoproterenol to $\beta$$_2$-adrenergic receptor possibly due to the uncoupling of receptor and G protein in the presence of the fusion protein. The uncoupling of receptor and G protein suggests that i3 loop region plays a critical role on $\beta$$_2$-adrenergic receptor G protein coupling.

• Animal cells and systems
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• 제12권3호
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• pp.149-155
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• 2008

We have isolated and characterized Agrius convolvuli cDNA encoding a c-type lysozyme. The cDNA sequence encodes a processed protein of 139 amino acid residues with 19 amino acid residues amino-terminal signal sequence and 120 amino acid residues mature sequence. The amino acid residues responsible for the catalytic activity and the binding of the substrate are conserved. Agrius lysozyme has a high identity to Manduca sexta. Recombinant A. convolvuli lysozyme was expressed in Escherichia coli BL21(DE3) pLysS cells for pGEX 4T-1 expression vector. Their optimal conditions for the fusion protein expression and purification were screened. Lysozyme gene amplified with primers ACLyz BamHI and ACLyz XhoI was ligated into the pGEX 4T-1 vector, which contained the glutathione S-transferase(GST) gene for fusion partner. The fusion protein was induced by IPTG and identified by SDS-PAGE analysis. Molecular weight of the fusion protein was estimated to be about 45 kDa. Recombinant lysozyme, fused to GST, was purified by glutathion-Sepharose 4B affinity chromatography. Western blot analysis of this protein revealed an immunoreactivity with the anti-Agrius lysozyme.

• 미생물학회지
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• 제31권4호
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• pp.279-285
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• 1993

p53 유전자의 변화는 인간의 여러 암에서 가장 흔하게 발견되며 종양세포내에서는 이러한 변형된 p53 단백질의 양의 증가가 초래된다. 세포내에 축적된 p53 단백질의 발견은 인간의 암증세를 판단할 유용한 기중이 되기도 한다. 본 연구에서는 이러한 면역조직화학 검사에 쓰일 수 있는 폴리클로날 항체를 만들기 위햐여 사람의 p53 유전자를 glutathione S-transferase 와의 융합 단백질의 형태로서 대장균내에서 발현시켰다. p53 의 아미노산 1-158번을 코딩하고 있는 NeoI fragment 와 아미노산 159-393 번을 코딩하는 NocI-BamHI fragment 를 BamHI linker 를 이용하여 in frame 으로 pGEX-2T 의 BamHI 자리에 삽입하여 재조합 플라스미드 pGTNS 와 pGTNL 을 각각 만들었다. 또 PCR 에 의한 증폭에 의햐여 아미노산 38-145번을 코딩하는 유전자 부위를 증폭하였으며 BamHI 과 PvuII 로 절단하여 pGEX-2T의 BamHI 과 SmaI 자리에 삽입함으로써 pGTBP 를 제조하였다. 이들 재조합 균주들을 IPTG 로 4시간 induction 한 후 세포 추출물로부터 glutathione Sepharose bead 를 이용하여 융합단백질을 분리하였다. Bead 에 결합된 단백질은 10% SDS-polyacrylamide gel 에서 전기영동하였으며, 각각의 분자량은 54 kDa, 53 kDa 와 40 kDa 였다. 이러한 방법으로 1리터 배양으로부터 약 1mg 의 단백질을 정제하였다.

• 한국생물공학회:학술대회논문집
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• 한국생물공학회 2003년도 생물공학의 동향(XII)
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• pp.500-500
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• 2003

• 한국결정학회:학술대회논문집
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• 한국결정학회 2000년도 추계 학술연구발표회
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• pp.7-7
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• 2000

• BMB Reports
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• 제29권5호
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• pp.462-467
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• 1996

Acetolactate synthase (ALS, EC 4.1.3.18) is the first common enzyme in the biosynthesis of leucine, isoleucine, and valine. It is the target enzyme for several classes of herbicides, including the sulfonylureas, the imidazolinones, the mazolopyrimidines, the pyrimidyl-oxy-benzoates, the pyrimidyl-thio-benzens, and the 4,6-dimethoxypyrimidines. An amino-terminal fragment of the sulfonylurea-resistant ALS gene (SurB) from Nicotiana tabaccum was cloned into the bacterial expression vector pGEX-2T. The resulting recombinant plasmid pGEX-ALS1 was used to transform Escherichia coli strain BL21, and the tobacco ALS was expressed in the bacteria as a protein fused with glutathione S-transferase (GST). Polyclonal antibodies against the fusion product (GST-ALS) were produced, and the sensitivity of GST-ALS with the rabbit anti-GST-ALS IgG was up to 50 ng. This antibody was used for Western blot analysis of the partially purified ALS from barley shoots. The results suggest that the polyclonal antibody produced in this study can be used to detect plant ALS.

• 대한의생명과학회지
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• 제2권2호
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• pp.231-240
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• 1996

인체 혈액 응고 9인자는 간에서 생성되며 461개의 아미노산으로 구성된 당 단백질이다. 따라서 인체 혈액 응고 9인자 cDNA를 찾기 위해 태아의 간(fetal liver) cDNA library를 PCR(Polymerase Chain reaction) 방법으로 screening하였으며, 그 결과 ATG개시 코돈으로부터 TAA종료 코돈까지 포함하는 1.4 kb의 9인자 cDNA를 찾았다. 또한 클론된 9인자 cDNA를 박테리아에서 발현시키기 위해 박테리아 발현 벡터인 pGEX-2T 플라스미드에 클로닝하므로써 pGEX-F9 플라스미드를 제조하였다. pGEX-F9로 형질전환된 E. coli에서 PGEX-F9의 발현을 유도하면 73 kDa 크기의 GST-factor9 융합 단백질이 다량생성되며 , 이 단백질이 혈액 응고 9인자 단백질을 함유하는 융합 단잭질임을 혈액 응고 9인자 항체를 이용한 Western blot으로 입증하였다. E. coli에서 발현된 GST-factor 9 융합 단백질은 전체 단백질의 약 20%를 차지하며 GST agarose bead를 이용한 one step purificarion 방법을 통해 GST-factor9 융합 단백질을 쉽게 분리 할 수 있다.

• 한국응용약물학회:학술대회논문집
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• 한국응용약물학회 1997년도 춘계학술대회
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• pp.93-93
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• 1997

Analysis of protein is often frustrated by the inability to isolate large amounts of purified protein from a native source. To overcome this problem, fusion protein expression systems such as pGEX system have been widely used. Using pGEX system, the desired protein could be easily obtained in a large amount in E. coli, and then the fusion protein could be used for the study of the function of the given protein. To analyze and purify the GST fusion protein, anti-GST antibody could be used as one of the system of choice. However, the production and characterization of monoclonal anti-GST antibody has not been studied extensively yet. To produce monoclonal anti-GST antibody, GST was purified from E. coli transformed with pGEX-cs, one of the pGEX system and was used as an antigen. The monoclonal antibody was produced by fusion of the immunized spleen cells with SP2-0 myeloma cells. The antibody was characterized by ELISA, western blotting, etc. The monoclonal antibody produced in this study (mAb-GSTA) showed strong and specific immunoreactivity against not only GST but also GST-fusion proteins. Also, mAb-GSTA was successfully used for the immunoaffinity purification of the GST ${\beta}$-Rc.-third intracellular-loop fusion protein. The results of the present study suggest that mAb-GSTA may be used for the identification and purification of GST fusion proteins.