• Journal of Microbiology and Biotechnology
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• 제14권1호
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• pp.162-166
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• 2004

Phage P22 tailspike is a thermostable homotrimeric protein, and temperature-sensitive folding (tsf) and global suppressor mutations affect its folding yields at elevated temperatures. We earlier suggested that the folding of the tailspike protein in Escherichia coli requires an unidentified molecular chaperone. Accordingly, in the present study, the interactions of purified DnaK, DnaJ, and GrpE heat-shock proteins with the tailspike protein were investigated during the translation and folding of the protein. The cotranslational addition of DnaJ to the tailspike protein resulted in the arrest of folding, when Dnak and GrpE were missing. However, the presence of DnaK, DnaJ, and GrpE had no effect on the folding yield of the tails pike protein, thus, providing evidence for the binding of the nascent tailspike protein with DnaJ protein, a member of DnaK chaperoning cycle.

• Bulletin of the Korean Chemical Society
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• 제17권9호
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• pp.808-813
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• 1996

To explore protein folding mechanism, we simulated a folding pathway in a simplified 3×3×3 cubic lattice. In the lattice folding Monte Carlo simulations, each of the 28 possible native packing pairs that exist in the native conformation was used as a conformational restraint. The native packing restraints in the lattice model could be considered as a disulfide linkage restraint in a real protein. The results suggest that proteins denatured with a small disulfide loop can, but not always, fold faster than proteins without any disulfide linkage and than proteins with a larger disulfide loop. The results also suggest that there is a rough correlation between loop size of the native packing restraint and folding time. That is, the order of native residue-residue packing interaction in protein folding is likely dependent on the residue-residue distance in primary sequence. The strength of monomer-monomer pairwise interaction is not important in the determination of the packing order in lattice folding. From the folding simulations of five strong folding lattice sequences, it was also found that the context encoded in the primary sequence, which we do not yet clearly understand, plays more crucial role in the determination of detailed folding kinetics. Our restrained lattice model approach would provide a useful strategy to the future protein folding experiments by suggesting a protein engineering for the fast or slow folding research.

• Bulletin of the Korean Chemical Society
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• 제35권9호
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• pp.2781-2786
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• 2014

Human ${\alpha}_1$-antitrypsin (${\alpha}_1$-AT) is a natural inhibitor of neutrophil elastases and has several dozens of genetic variants. Most of the deficient genetic variants of human ${\alpha}_1$-AT are unstable and cause pulmonary emphysema. However, the most clinically significant variant, Z-type ${\alpha}_1$-AT, exhibits retarded protein folding that leads to accumulation of folding intermediates. These aggregate within the endoplasmic reticulum (ER) of hepatocytes, subsequently causing liver cirrhosis as well as emphysema. Here, we studied the role of an ER folding assistant protein Cpr5p on Z-type ${\alpha}_1$-AT folding. Cpr5p was induced > 2-fold in Z-type ${\alpha}_1$-AT-expressing yeast cells compared with the wild type. Knockout of CPR5 exacerbated cytotoxicity of Z-type ${\alpha}_1$-AT, and re-introduction of CPR5 rescued the knockout cells from aggravated cytotoxicity caused by the ${\alpha}_1$-AT variant. Furthermore, Cpr5p co-immunoprecipitated with Z-type ${\alpha}_1$-AT and facilitated its protein folding. Our results suggest that protein-folding diseases may be suppressed by folding assistant proteins at the site of causal protein biosynthesis.

• BMB Reports
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• 제38권3호
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• pp.275-280
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• 2005

For most of proteins to be active, they need well-defined three-dimensional structures alone or in complex. Folding is a process through which newly synthesized proteins get to the native state. Protein folding inside cells is assisted by various chaperones and folding factors, and misfolded proteins are eliminated by the ubiquitin-proteasome degradation system to ensure high fidelity of protein expression. Under certain circumstances, misfolded proteins escape the degradation process, yielding to deposit of protein aggregates such as loop-sheet polymer and amyloid fibril. Diseases characterized by insoluble deposits of proteins have been recognized for long time and are grouped as conformational diseases. Study of protein folding mechanism is required for better understanding of the molecular pathway of such conformational diseases.

• Bulletin of the Korean Chemical Society
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• 제31권10호
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• pp.2877-2883
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• 2010

The folding kinetics of $WT^*$ ubiquitin variant with valine to alanine mutation at sequence position 26 (HubWA) was studied by stopped-flow fluorescence spectroscopy. While unfolding kinetics showed a single exponential phase, refolding reaction showed three exponential phases. The semi-logarithmic plot of urea concentration vs. rate constant for the first phase showed v-shape pattern while the second phase showed v-shape with roll-over effect at low urea concentration. The rate constant and the amplitude of the third phase were constant throughout the urea concentrations, suggesting that this phase represents parallel process due to the configurational isomerization. Interestingly, the first and second phases appeared to be coupled since the amplitude of the second phase increased at the expense of the amplitude of the first phase in increasing urea concentrations. This observation together with the roll-over effect in the second folding phase indicates the presence of intermediate state during the folding reaction of HubWA. Quantitative analysis of Hub-WA folding kinetics indicated that this intermediate state is on the folding pathway. Folding kinetics measurement of a mutant HubWA with hydrophobic core residue mutation, Val to Ala at residue position 17, suggested that the intermediate state has significant amount of native interactions, supporting the interpretation that the intermediate is on the folding pathway. It is considered that HubWA is a useful model protein to study the contribution of residues to protein folding process using folding kinetics measurements in conjunction with protein engineering.

• Bulletin of the Korean Chemical Society
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• 제32권spc8호
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• pp.3051-3056
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• 2011

We calculate the free energy surfaces for two small proteins and a protein-RNA complex system by using a lattice model approach. In particular, we employ the Munoz-Eaton model, which is a native-structure based statistical mechanical model for studying protein folding problem. The model can provide very useful insights into the folding mechanisms by allowing one to calculate the free energy surfaces efficiently. We first calculate the free energy surfaces of ubiquitin and BBL, using both approximate and recently developed exact solutions of the model. Ubiquitin exhibits a typical two-state folding behavior, while BBL downhill folding in our study. We then extend the method to study of a protein-RNA complex. In particular, we focus on PAZ-siRNA complex. In order to elucidate the interplay between folding and binding kinetics for this system we perform comparative studies of PAZ only, PAZ-siRNA complex and two mutated complexes. We find that folding and binding are strongly coupled with each other and the bound PAZ is more stable than the unbound PAZ. Our results also suggest that the binding sites of the siRNA may serve act as a nucleus in the folding process.

• Biotechnology and Bioprocess Engineering:BBE
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• 제6권4호
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• pp.237-243
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• 2001

Substantial progress has been made towards understanding the folding mechanisms of proteins in virto and in vivo even though the general rules governing such folding events remain unknown. This paper reviews current folding models along with experimental approaches used to elucidate the folding pathways. Protein misfolding is discussed in relation to disease states, such as amyloidosis, and the recent findings on the mechanism of converting normally soluble proteins into amyloid fibrils through the formation of intermediates provide an insight into understanding the pathogenesis of amyloid formation and possible cules for the development of therapeutic treatments. Finally, some commonly adopted refolding strategies developed over the part decade are summarized.

• 대한화학회지
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• 제63권6호
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• pp.427-434
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• 2019

단백질 폴딩 연구에 유용하도록 유비퀴틴 단백질의 페닐알라닌 45를 트립토판으로, 발린 26을 알라닌으로 변이시킨 HubWA 단백질을 모델로 삼아 소수성 상호작용이 단백질 폴딩 반응에 끼치는 영향을 탐구하였다. HubWA의 소수성 아미노산 중 14 개를 알라닌으로 치환한 변이 단백질을 제조하였고 이들 중 폴딩 연구에 적절한 4 개의 변이 단백질(V5A, I13A, V17A, I36A)을 얻어서 폴딩 반응의 진행 과정을 stopped-flow 장치로 측정하였다. 변이 단백질 V17A의 폴딩 반응은 HubWA와 마찬가지로 three-state 메커니즘을 따르며, V5A, I13A, I36A의 반응은 two-state 폴딩 메커니즘을 따르는 것으로 관찰되었다. 이는 HubWA 단백질의 폴딩 반응은 지엽적으로 구조적인 안정성을 지닌 부분이 존재하는 중간 단계가 먼저 형성된 다음 이들이 서로 퍼즐을 맞추는 것과 같은 방식으로 폴딩이 일어나는 collision-diffusion 메커니즘을 따르다가 소수성이 약한 아미노산으로 치환하였을 때 구조적인 안정성을 지닌 중간 단계가 관찰되지 않지만 폴딩 핵의 형성과 핵 주위로 native 구조가 형성되는 반응이 짝지어서 일어나는 nucleation-condensation 메커니즘으로 전환되는 것으로 해석되었다. 이러한 관찰은 단백질의 폴딩 경로는 지엽적인 구조의 안정성에 따라 서로 다른 메커니즘을 띨 수 있음을 시사한다.

• Bulletin of the Korean Chemical Society
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• 제31권12호
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• pp.3521-3524
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• 2010

MTH1880 is a hypothetical protein derived from Methanobacterium thermoautotrophicum, thermophilic methanogen. The solution structure determined by NMR spectroscopy showed that it has a novel $\alpha+\beta$-fold with a highly acidic ligand binding pocket. Since MTH1880 maintains its ultra-stable structural characteristics at both high temperature and pressure, it has been considered as an excellent model for studying protein folding. To initiate the structural and folding study of MTH1880 in proving its unusual stability, we performed the site directed mutagenesis and biochemical analysis of MTH1880 mutants. Data from circular dichroism and NMR spectroscopy suggest that the point mutations perturbed the structural stability of protein even though the secondary structure is retained. This study will provide the useful information in understanding the role of participating residues during folding-unfolding process and our result will be used in designing further folding experiments for hyper-thermopile proteins like MTH1880.

• 대한화학회지
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• 제67권2호
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• pp.81-88
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• 2023

HubWA 단백질을 모델로 삼아 소수성 아미노산이 folding 반응에 끼치는 영향을 탐색하기 위하여 HubWA에 있는 I와 L을 V로 치환한 변이 단백질의 folding kinetics를 측정하였다. 변이 단백질의 folding kinetics는 HubWA 단백질과 마찬가지로 three-state on-pathway mechanism(U ⇌ I ⇌ N, U는 unfolded 상태, I는 중간단계, N은 native 상태를 의미한다)을 따르는 것으로 나타났다. Folding kinetics 분석을 통하여 three-state 반응의 elementary 반응과 전체 반응의 자유에너지인 ΔG^o_UI, ΔG^o_IN, ΔG^o_UN을 얻었고, 변이 단백질의 자유에너지와 HubWA 단백질의 자유에너지의 차(ΔΔG^o_UI = ΔG^o_UI(변이 단백질) - ΔG^o_UI(HubWA), ΔΔG^o_UN = ΔG^o_UN(변이 단백질) - ΔG^o_UN(HubWA))의 비인 ΔΔG^o_UI/ΔΔG^o_UN를 통하여 중간단계가 전체 folding 반응에 끼치는 영향을 각 소수성 잔기 별로 알아볼 수 있었다. HubWA의 입체구조에서 α-helix와 β-sheet가 상호작용하는 소수성 코어에 위치하는 아미노산인 I3, I13, L15, I30, L43, I61, L67을 V로 치환한 변이 단백질의 ΔΔG^o_UI/ΔΔG^o_UN 값이 ~0.5로 나타난 점은 이들 아미노산이 중간단계에서 native 상태보다는 느슨하지만 비교적 견고한 구조를 이루는 것으로 해석되었다. HubWA 입체구조에서 α-helix의 아미노말단에 위치하는 I23, 특정 이차구조가 없는 부위에 위치하는 I36, β-strand 5의 카복실말단에 위치하는 L69를 V로 치환한 변이 단백질의 ΔΔG^o_UI/ΔΔG^o_UN 값이 0.4 이하로 나타난 것은 이들 아미노산 잔기가 중간단계에서는 비교적 느슨한 구조를 이루다 중간단계에서 native 단계로 진행하는 folding 과정의 후반부에 HubWA의 입체구조에 견고하게 편입되는 것으로 해석되었다. HubWA의 입체구조에서 두 번째 β-strand의 카복실말단에 위치한 V17, 짧은 네 번째 β-strand의 카복실말단에 위치한 L50, 짧은 3₁₀-helix의 아미노말단에 위치한 L56이 중간단계에서 서로 상호작용을 하는 점은 이들 아미노산을 V로 치환한 변이 단백질의 ΔΔG^o_UI/ΔΔG^o_UN값이 0.8 이상으로 나타난 점을 통하여 알 수 있었다. L50과 L56은 짧은 β-strand와 3₁₀-helix를 제외하고 특별한 이차구조가 존재하지 않는 부위(46번째 아미노산 잔기부터 62번째 아미노산 잔기 까지)에 위치하는데, 이들 아미노산이 V17과 더불어 folding 반응의 초기에 견고하게 상호작용을 하는 것은 HubWA단백질이 folding 과정의 초기에 응집체를 형성하는 것을 막아주는 역할을하는 것으로 생각되었다.