Importance of Expression System in the Production of Unnatural Recombinant Proteins in Escherichia coli

Niraikulam Ayyadurai,Rameshkumar Neelamegam,Soundrarajan Nagasundarapandian,Selvakumar Edwardraja,Hyung Soon Park,Soo Jae Lee,Tae Hyeon Yoo,Hyungdon Yoon,이선구 한국생물공학회 2009 Biotechnology and Bioprocess Engineering Vol.14 No.3

In this study, we investigated the efficiencies by which the pET and pQE expression systems produce unnatural recombinant proteins by residue-specific incorporation of unnatural amino acids, a method through which it was found that type of gene expression system tremendously influences the production yield of unnatural proteins in Escherichia coli. Green fluorescent protein (GFP) and a single-chain Fv antibody against c-Met were utilized as model recombinant proteins while Lhomopropargylglycine (Hpg), a methionine analogue that incorporates into the methionine residues of a recombinant protein, was used as model unnatural amino acid. The pET system produced an almost negligible amount of Hpg-incorporated unnatural protein compared to the amount of methionine-incorporated natural protein. However, comparable amounts of unnatural and natural protein were produced by the pQE expression system. The amount of unnatural GFP protein produced through pET expression was not increased despite the over-expression of methionyl tRNA synthetase, which can enhance the activation rate of methionyl-tRNA with a methionine analogue. Incorporation of Hpg decreased the productivity of active GFP by approximately 2.5 fold, possibly caused by the inefficient folding of Hpg-incorporated GFP. Conversely, the productivity of functional anti-c-Met sc-Fv was not influenced by incorporation of Hpg. We confirmed through LC-MS and LCMS/ MS that Hpg was incorporated into the methionine residues of the recombinant proteins produced by the pQE expression system In this study, we investigated the efficiencies by which the pET and pQE expression systems produce unnatural recombinant proteins by residue-specific incorporation of unnatural amino acids, a method through which it was found that type of gene expression system tremendously influences the production yield of unnatural proteins in Escherichia coli. Green fluorescent protein (GFP) and a single-chain Fv antibody against c-Met were utilized as model recombinant proteins while Lhomopropargylglycine (Hpg), a methionine analogue that incorporates into the methionine residues of a recombinant protein, was used as model unnatural amino acid. The pET system produced an almost negligible amount of Hpg-incorporated unnatural protein compared to the amount of methionine-incorporated natural protein. However, comparable amounts of unnatural and natural protein were produced by the pQE expression system. The amount of unnatural GFP protein produced through pET expression was not increased despite the over-expression of methionyl tRNA synthetase, which can enhance the activation rate of methionyl-tRNA with a methionine analogue. Incorporation of Hpg decreased the productivity of active GFP by approximately 2.5 fold, possibly caused by the inefficient folding of Hpg-incorporated GFP. Conversely, the productivity of functional anti-c-Met sc-Fv was not influenced by incorporation of Hpg. We confirmed through LC-MS and LCMS/ MS that Hpg was incorporated into the methionine residues of the recombinant proteins produced by the pQE expression system

Cloning and protein expression of Aggregatibacter actinomycetemcomitans cytolethal distending toxin C

이은선,박소영,이은숙,김형섭 대한치주과학회 2008 Journal of Periodontal & Implant Science Vol.38 No.2

Purpose: Aggregatibacter actinomycetemcomitans was associated with localized aggressive periodontitis, endocarditis, meningitis, and osteomyelitis. The cytolethal distending toxin (CDT) of A. actinomycetemcomitans was considered as a key factor of these diseases is composed of five open reading frames (ORFs). Among of them, An enzymatic subunit of the CDT, CdtB has been known to be internalized into the host cell in order to induce its genotoxic effect. However, CdtB can not be localized in host cytoplasm without the help of a heterodimeric complex consisting of CdtA and CdtC. So, some studies suggested that CdtC functions as a ligand to interact with GM3 ganglioside of host cell surface. The precise role of the CdtC protein in the mechanism of action of the holotoxin is unknown at the present time. The aim of this study was to generate recombinant CdtC proteins expression from A. actinomycetemcomitans, through gene cloning and protein used to investigate the function of Cdt C protein in the bacterial pathogenesis Materials and Methods: The genomic DNA of A. actinomycetemcomitans Y4 (ATCC29522) was isolated using the genomic DNA extraction kit and used as template to yield cdtC genes by PCR. The amplifed cdtC genes were cloned into T-vector and cloned cdt C gene was then subcloned to pET28a expression vector. The pET28a-cdtC plasmid expressed in BL21 (DE3) Escherichia coli system. Diverse conditons were tested to opitimize the expression and purification of functional CdtC protein in E. coli. Results: In this study we reconstructed CdtC subunit of A. actinomycetemcomitans Y4 and comfirmed the recombinant CdtC expression by SDS-PAGE and Western Blotting. The expression level of the recombinant CdtC was about 2% of total bacterial proteins. Conclusion: The lab condition of procedure for the purification of functionally active recombinant CdtC protein is established. The active recombinant CdtC protein will serve to examine the role of CdtC proteins in the host recognition and enzyme activity of CDT and investigate the pathological process of A. actinomycetemcomitans in periodontal disease. (J Korean Acad Periodontol 2008;38:317-324) Purpose: Aggregatibacter actinomycetemcomitans was associated with localized aggressive periodontitis, endocarditis, meningitis, and osteomyelitis. The cytolethal distending toxin (CDT) of A. actinomycetemcomitans was considered as a key factor of these diseases is composed of five open reading frames (ORFs). Among of them, An enzymatic subunit of the CDT, CdtB has been known to be internalized into the host cell in order to induce its genotoxic effect. However, CdtB can not be localized in host cytoplasm without the help of a heterodimeric complex consisting of CdtA and CdtC. So, some studies suggested that CdtC functions as a ligand to interact with GM3 ganglioside of host cell surface. The precise role of the CdtC protein in the mechanism of action of the holotoxin is unknown at the present time. The aim of this study was to generate recombinant CdtC proteins expression from A. actinomycetemcomitans, through gene cloning and protein used to investigate the function of Cdt C protein in the bacterial pathogenesis Materials and Methods: The genomic DNA of A. actinomycetemcomitans Y4 (ATCC29522) was isolated using the genomic DNA extraction kit and used as template to yield cdtC genes by PCR. The amplifed cdtC genes were cloned into T-vector and cloned cdt C gene was then subcloned to pET28a expression vector. The pET28a-cdtC plasmid expressed in BL21 (DE3) Escherichia coli system. Diverse conditons were tested to opitimize the expression and purification of functional CdtC protein in E. coli. Results: In this study we reconstructed CdtC subunit of A. actinomycetemcomitans Y4 and comfirmed the recombinant CdtC expression by SDS-PAGE and Western Blotting. The expression level of the recombinant CdtC was about 2% of total bacterial proteins. Conclusion: The lab condition of procedure for the purification of functionally active recombinant CdtC protein is established. The active recombinant CdtC protein will serve to examine the role of CdtC proteins in the host recognition and enzyme activity of CDT and investigate the pathological process of A. actinomycetemcomitans in periodontal disease. (J Korean Acad Periodontol 2008;38:317-324)

Recombinant DNA and Protein Vaccines for Foot-and-mouth Disease Induce Humoral and Cellular Immune Responses in Mice

배지영,문선화,최정아,박종석,한범수,김기영,김병한,송재영,권대혁,이석찬,김종범,양주성 대한면역학회 2009 Immune Network Vol.9 No.6

Foot-and-mouth disease virus (FMDV) is a small single- stranded RNA virus which belongs to the family Picornaviridae, genus Apthovirus. It is a principal cause of FMD which is highly contagious in livestock. In a wild type virus infection, infected animals usually elicit antibodies against structural and non-structural protein of FMDV. A structural protein, VP1, is involved in neutralization of virus particle, and has both B and T cell epitopes. A RNA-dependent RNA polymerase, 3D, is highly conserved among other serotypes and strongly immunogenic, therefore, we selected VP1 and 3D as vaccine targets. VP1 and 3D genes were codon-optimized to enhance protein expression level and cloned into mammalian expression vector. To produce recombinant protein, VP1 and 3D genes were also cloned into pET vector. The VP1 and 3D DNA or proteins were co-immunized into 5 weeks old BALB/C mice. Antigen-specific serum antibody (Ab) responses were detected by Ab ELISA. Cellular immune response against VP1 and 3D was confirmed by ELISpot assay. The results showed that all DNA- and protein-immunized groups induced cellular immune responses, suggesting that both DNA and recombinant protein vaccine administration efficiently induced Ag-specific humoral and cellular immune responses. Foot-and-mouth disease virus (FMDV) is a small single- stranded RNA virus which belongs to the family Picornaviridae, genus Apthovirus. It is a principal cause of FMD which is highly contagious in livestock. In a wild type virus infection, infected animals usually elicit antibodies against structural and non-structural protein of FMDV. A structural protein, VP1, is involved in neutralization of virus particle, and has both B and T cell epitopes. A RNA-dependent RNA polymerase, 3D, is highly conserved among other serotypes and strongly immunogenic, therefore, we selected VP1 and 3D as vaccine targets. VP1 and 3D genes were codon-optimized to enhance protein expression level and cloned into mammalian expression vector. To produce recombinant protein, VP1 and 3D genes were also cloned into pET vector. The VP1 and 3D DNA or proteins were co-immunized into 5 weeks old BALB/C mice. Antigen-specific serum antibody (Ab) responses were detected by Ab ELISA. Cellular immune response against VP1 and 3D was confirmed by ELISpot assay. The results showed that all DNA- and protein-immunized groups induced cellular immune responses, suggesting that both DNA and recombinant protein vaccine administration efficiently induced Ag-specific humoral and cellular immune responses.

Effective non-denaturing purification method for improving the solubility of recombinant actin-binding proteins produced by bacterial expression

Chung, Jeong Min,Lee, Sangmin,Jung, Hyun Suk Elsevier 2017 Protein expression and purification Vol.133 No.-

<P><B>Abstract</B></P> <P>Bacterial expression is commonly used to produce recombinant and truncated mutant eukaryotic proteins. However, heterologous protein expression may render synthesized proteins insoluble. The conventional method used to express a poorly soluble protein, which involves denaturation and refolding, is time-consuming and inefficient. There are several non-denaturing approaches that can increase the solubility of recombinant proteins that include using different bacterial cell strains, altering the time of induction, lowering the incubation temperature, and employing different detergents for purification. In this study, we compared several non-denaturing protocols to express and purify two insoluble 34 kDa actin-bundling protein mutants. The solubility of the mutant proteins was not affected by any of the approaches except for treatment with the detergent sarkosyl. These results indicate that sarkosyl can effectively improve the solubility of insoluble proteins during bacterial expression.</P> <P><B>Highlights</B></P> <P> <UL> <LI> The expression and purification condition for truncated actin binding proteins was optimized from <I>Escherichia coli</I> strain. </LI> <LI> The treatment of sarkosyl-detergent increases the solubility of bacterial recombinant proteins. </LI> <LI> Minimizing concentration of sarkosyl was suggested for enhancing the production of soluble proteins. </LI> </UL> </P>

재조합 TIS21 단백질에 대한 Affinity-Purified 항혈청의 생산

이재호,이수한,임인경 아주대학교 의과학연구소 1996 아주의학 Vol.1 No.1

For the study of TIS21 protein, a primary response gene product, we produced affinity-purified antisera against recombinant TIS21 protein. At first, hexahistidine-tagged recombinant TIS21 protein was produced by using bacterial expression system and was purified to near homogeneity using Ni^(2+)-affinity column in the presence of urea. PBS-soluble and -insoluble TIS21 protein fractions were immunized into rabbits after dialysis. High-titer antiserum was obtained from one of the rabbits immunized with PBS-soluble fraction. Meanwhile, partially purified recombinant TIS21 protein was further purified by preparative SDS-PAGE and it was conjugated with the sepharose resin. The high-titer serum was applied to this affinity column and affinity-purified antiserum was obtained. This affinity-purified antiserum recognized TIS21 proteins expressed in bacteria as well as in mammalian cell when it was used in western blot. In addition, this affinity-purified antiserum recognized a constitutively expressed 40 kDa protein from NIH3T3, B9, C3HIOTI/2 and 293 cell lines. Detection of this protein with the affinity-purified antiserum can be inhibited by recombinant TIS21 proteins prepared by our laboratory and other laboratory. Therefore this 40kDa protein can be an immunologically cross-reactive protein with TIS21 protein.

A lower isoelectric point increases signal sequence–mediated secretion of recombinant proteins through a bacterial ABC transporter

Byun, Hyunjong,Park, Jiyeon,Kim, Sun Chang,Ahn, Jung Hoon American Society for Biochemistry and Molecular Bi 2017 The Journal of biological chemistry Vol.292 No.48

<P>Efficient protein production for industrial and academic purposes often involves engineering microorganisms to produce and secrete target proteins into the culture. <I>Pseudomonas fluorescens</I> has a TliDEF ATP-binding cassette transporter, a type I secretion system, which recognizes C-terminal LARD3 signal sequence of thermostable lipase TliA. Many proteins are secreted by TliDEF <I>in vivo</I> when recombined with LARD3, but there are still others that cannot be secreted by TliDEF even when LARD3 is attached. However, the factors that determine whether or not a recombinant protein can be secreted through TliDEF are still unknown. Here, we recombined LARD3 with several proteins and examined their secretion through TliDEF. We found that the proteins secreted via LARD3 are highly negatively charged with highly-acidic isoelectric points (pI) lower than 5.5. Attaching oligo-aspartate to lower the pI of negatively-charged recombinant proteins improved their secretion, and attaching oligo-arginine to negatively-charged proteins blocked their secretion by LARD3. In addition, negatively supercharged green fluorescent protein (GFP) showed improved secretion, whereas positively supercharged GFP did not secrete. These results disclosed that proteins' acidic pI and net negative charge are major factors that determine their secretion through TliDEF. Homology modeling for TliDEF revealed that TliD dimer forms evolutionarily-conserved positively-charged clusters in its pore and substrate entrance site, which also partially explains the pI dependence of the TliDEF-dependent secretions. In conclusion, lowering the isoelectric point improved LARD3-mediated protein secretion, both widening the range of protein targets for efficient production via secretion and signifying an important aspect of ABC transporter–mediated secretions.</P>

Recombinant production and biochemical characterization of a hypothetical acidic shell matrix protein in Escherichia coli for the preparation of protein-based CaCO3 biominerals

Yoo Seong Choi,Chaeyeon Son,Wooho Song,Dong Soo Hwang,Yong-Ki Hong,Jin Joo 한국화학공학회 2016 Korean Journal of Chemical Engineering Vol.33 No.8

The biological structure of shells consists of highly organized calcium carbonate (CaCO3) crystals, which have remarkable mechanical and biological properties compared to the pure mineral form of CaCO3. It has been known that the organization of these biominerals is controlled by a relatively tiny amount of organic components such as shell matrix proteins. Here, we successfully produced a recombinant hypothetical acidic shell matrix protein in Escherichia coli, although the protein is composed of highly repetitive and biased amino acid sequences. About 15mg/L purified protein with greater than 95% purity was obtained in the 400 mL lab scale flask culture. The protein was able to efficiently form a complex with calcium ions, and spherulitic calcite crystals were synthesized in the presence of the recombinant protein. We expect that biomineralization using the recombinant protein could not only overcome the limited amount of protein available for biomineralization studies and biomineral preparation in practical aspects, but also provide opportunities to enable biomimetic synthesis of notable bio-composites based on organic-inorganic complexation.

Enhancement of the solubility of recombinant proteins by fusion with a short-disordered peptide

Ren Jun,Hwang Suhee,Shen Junhao,Kim Hyeongwoo,Kim Hyunjoo,Kim Jieun,Ahn Soyoung,Kim Min-gyun,Lee Seung Ho,Na Dokyun 한국미생물학회 2022 The journal of microbiology Vol.60 No.9

In protein biotechnology, large soluble fusion partners are widely utilized for increased yield and solubility of recombinant proteins. However, the production of additional large fusion partners poses an additional burden to the host, leading to a decreased protein yield. In this study, we identified two highly disordered short peptides that were able to increase the solubility of an artificially engineered aggregationprone protein, GFP-GFIL4, from 0.6% to 61% (D3-DP00592) and 46% (D4-DP01038) selected from DisProt database. For further confirmation, the peptides were applied to two insoluble E. coli proteins (YagA and YdiU). The peptides also enhanced solubility from 52% to 90% (YagA) and from 27% to 93% (YdiU). Their ability to solubilize recombinant proteins was comparable with strong solubilizing tags, maltosebinding protein (40 kDa) and TrxA (12 kDa), but much smaller (< 7 kDa) in size. For practical application, the two peptides were fused with a restriction enzyme, I-SceI, and they increased I-SceI solubility from 24% up to 75%. The highly disordered peptides did not affect the activity of I-SceI while I-SceI fused with MBP or TrxA displayed no restriction activity. Despite the small size, the highly disordered peptides were able to solubilize recombinant proteins as efficiently as conventional fusion tags and did not interfere with the function of recombinant proteins. Consequently, the identified two highly disordered peptides would have practical utility in protein biotechnology and industry.

N4SSB 단백질의 C-말단기의 7개의 아미노산이 N4SSB 단백질의 in vivo 활성에 미치는 영향

최미영,Choi, Mieyoung 한국미생물학회 1998 미생물학회지 Vol.34 No.4

Bacteriophage N4, a lytic phage specific for Esherichia coli K12 strain encodes single-stranded DNA-binding protein, N4SSB (bacteriophage N4-coded single-stranded DNA-binding protein). N4SSB protein is originally identified as a protein required for N4 DNA replication. N4SSB protein is also required for N4 late transcription, which is catalyzed by E. coli ${\sigma}^{70}$ RNA polymerase. N4 late transcription does not occur until N4SSB protein is synthesized. Recently it is reported that N4SSB protein is essential for N4 DNA recombination. Therefore N 4SSB protein is a multifunctional protein required for N4 DNA replication, late transcription, and N4 DNA recombination. In this study, a variety of mutant N4SSB proteins containing internal deletions or substitutions were constructed to define and characterize domains important for N4 DNA replication, late transcription, and N4 DNA recombination. Test for the ill vivo activity of these mutant N4SSBs for N4 DNA replication, late transcription, and N4 DNA recombination was examined. The results suggest that C-terminal 7 amino acid residues are important for the activity of N4SSB. Three lysine residues, which are contained in this region play important roles on N4SSB activity. Esherichia coli(E. coli) K12 균주를 숙주세포로 삼는 박테리오파아지인 N4는 single-stranded DNA에 결합하는 단백질인 N4SSB(bacteriophage N4-coded single-stranded DNA-binding protein) 단백질을 만든다. N4SSB 단백질은 N4 DNA replication 뿐만 아니라 late transcription과 N4 DNA recombination에도 필요한 여러 가지 기능을 가진 단백질이다. N4 late transcription은 숙주세포인 E. coli의 $E{\sigma}^{70}$ RNA polymerase에 의해서 수행이 되나 N4SSB 단백질을 반드시 필요로 하기 때문에 N4SSB 단백질이 생성될 때까지는 N4 late promoter로부터 RNA 합성이 일어나지 않는다. 본 연구에서는 N4SSB의 N4 DNA replication과 late transcription, 그리고 N4 DNA recombination에 필요한 영역(domain)을 알아내기 위해서 여러 가지 돌연변이형 N4SSB 단백질을 만들어 N4 DNA replication과 late transcription, 그리고 N4 DNA recombination의 3가지 작용에 대한 in vivo 활성을 조사 분석하였다. 그 결과 N4SSB 단백질의 C-말단기에 있는 7개의 아미노산이 N4SSB 단백질의 활성에 중요하다는 것을 알 수 있었다. 특히 C-말단기의 7개의 아미노산에는 세 개의 lysine이 포함되어 있는데 이 lysine이 N4SSB 단백질의 활성에 중요한 역할을 한다는 것이 제시되었다.

Cloning and protein expression of Aggregatibacter actinomycetemcomitans cytolethal distending toxin C

Lee, Eun-Sun,Park, So-Young,Lee, Eun-Suk,Kim, Hyung-Seop Korean Academy of Periodontology 2008 Journal of Periodontal & Implant Science Vol.38 No.2

Purpose: Aggregatibacter actinomycetemcomitans was associated with localized aggressive periodontitis, endocarditis, meningitis, and osteomyelitis. The cytolethal distending toxin (CDT) of A. actinomycetemcomitans was considered as a key factor of these diseases is composed of five open reading frames (ORFs). Among of them, An enzymatic subunit of the CDT, CdtB has been known to be internalized into the host cell in order to induce its genotoxic effect. However, CdtB can not be localized in host cytoplasm without the help of a heterodimeric complex consisting of CdtA and CdtC. So, some studies suggested that CdtC functions as a ligand to interact with GM3 ganglioside of host cell surface. The precise role of the CdtC protein in the mechanism of action of the holotoxin is unknown at the present time. The aim of this study was to generate recombinant CdtC proteins expression from A. actinomycetemcomitans, through gene cloning and protein used to investigate the function of Cdt C protein in the bacterial pathogenesis. Materials and Methods: The genomic DNA of A. actinomycetemcomitans Y4 (ATCC29522) was isolated using the genomic DNA extraction kit and used as template to yield cdtC genes by PCR. The amplifed cdtC genes were cloned into T-vector and cloned cdt C gene was then subcloned to pET28a expression vector. The pET28a-cdtC plasmid expressed in BL21 (DE3) Escherichia coli system. Diverse conditons were tested to opitimize the expression and purification of functional CdtC protein in E. coli. Results: In this study we reconstructed CdtC subunit of A. actinomycetemcomitans Y4 and comfirmed the recombinant CdtC expression by SDS-PAGE and Western Blotting. The expression level of the recombinant CdtC was about 2% of total bacterial proteins. Conclusion: The lab condition of procedure for the purification of functionally active recombinant CdtC protein is established. The active recombinant CdtC protein will serve to examine the role of CdtC proteins in the host recognition and enzyme activity of CDT and investigate the pathological process of A. actinomycetemcomitans in periodontal disease.