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Open Access Highly Accessed Methodology article

A novel PCR-based method for high throughput prokaryotic expression of antimicrobial peptide genes

Tao Ke12*, Su Liang3, Jin Huang3, Han Mao2, Jibao Chen1, Caihua Dong2, Junyan Huang2, Shengyi Liu2, Jianxiong Kang4, Dongqi Liu4 and Xiangdong Ma3*

Author Affiliations

1 Department of Life Science and Technology, Nanyang Normal University, Wolong Road, Nanyang 473061, China

2 Key Laboratory of Biology and Genetic Improvement of Oil Crops, Ministry of Agriculture, Oil Crops Research Institute, Chinese Academy of Agricultural Sciences, No.2 Xudong Second Road, Wuhan 430062, China

3 Hubei Key Laboratory of Industrial Biotechnology, College of Life Science, Hubei University, Wuhan 430062, China

4 School of Environmental Science and Engineering, Huazhong University of Science and Technology, Wuhan 430074, China

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BMC Biotechnology 2012, 12:10  doi:10.1186/1472-6750-12-10


The electronic version of this article is the complete one and can be found online at: http://www.biomedcentral.com/1472-6750/12/10


Received:31 August 2011
Accepted:23 March 2012
Published:23 March 2012

© 2012 Ke et al; licensee BioMed Central Ltd.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background

To facilitate the screening of large quantities of new antimicrobial peptides (AMPs), we describe a cost-effective method for high throughput prokaryotic expression of AMPs. EDDIE, an autoproteolytic mutant of the N-terminal autoprotease, Npro, from classical swine fever virus, was selected as a fusion protein partner. The expression system was used for high-level expression of six antimicrobial peptides with different sizes: Bombinin-like peptide 7, Temporin G, hexapeptide, Combi-1, human Histatin 9, and human Histatin 6. These expressed AMPs were purified and evaluated for antimicrobial activity.

Results

Two or four primers were used to synthesize each AMP gene in a single step PCR. Each synthetic gene was then cloned into the pET30a/His-EDDIE-GFP vector via an in vivo recombination strategy. Each AMP was then expressed as an Npro fusion protein in Escherichia coli. The expressed fusion proteins existed as inclusion bodies in the cytoplasm and the expression levels of the six AMPs reached up to 40% of the total cell protein content. On in vitro refolding, the fusion AMPs was released from the C-terminal end of the autoprotease by self-cleavage, leaving AMPs with an authentic N terminus. The released fusion partner was easily purified by Ni-NTA chromatography. All recombinant AMPs displayed expected antimicrobial activity against E. coli, Micrococcus luteus and S. cerevisia.

Conclusions

The method described in this report allows the fast synthesis of genes that are optimized for over-expression in E. coli and for the production of sufficiently large amounts of peptides for functional and structural characterization. The Npro partner system, without the need for chemical or enzymatic removal of the fusion tag, is a low-cost, efficient way of producing AMPs for characterization. The cloning method, combined with bioinformatic analyses from genome and EST sequence data, will also be useful for screening new AMPs. Plasmid pET30a/His-EDDIE-GFP also provides green/white colony selection for high-throughput recombinant AMP cloning.

Keywords:
antimicrobial peptide; high throughput; Npro; prokaryotic expression

Background

Antimicrobial peptides are widely distributed in nature and play a critical role in the innate immunity of host defense systems. They act with broad spectrum and, hence, are promising candidates for therapeutic and industrial application [1-5]. For research studies and clinical trials, large quantities of these peptides are needed [6]. The number of described AMPs has increased over recent decades [7]; however, the recent generation of huge amounts of genomic, proteomic and EST (Expressed Sequence Tag) data enables novel strategies for the discovery of new candidate AMPs [8-10]. In silico methods based on bioinformatic analyses, combined with experimental screening techniques have been developed to screen and identify new AMP genes from huge "-omics" data sets [11,12]. Belarmino et al. screened 237,954 ESTs of sugarcane using a computational approach and successfully identified 17 new defensin isoforms [13]. Following in silico prediction, however, there is a requirement for a high throughput genome-scale DNA cloning and expression system to enable the antimicrobial activities of putative AMPs to be characterized [9,14,15].

Expression of fusion proteins that form inclusion bodies has several advantages that can overcome major barriers of AMP expression in E. coli: high rates of expression, easy collection by centrifugation, protection from proteolysis and the avoidance of intrinsic AMP antimicrobial activity against host cells [16,17]. However, recombinant AMPs expressed in E. coli often include 1-2 non-native amino acid residuals at the N terminus of the target protein due to a specific linker sequence recognized by endoproteases or chemical agents, typically located between the native protein sequence and the tag [18]. These non-authentic N termini of AMPs often alter their characteristics. It is, therefore, very important to develop a new strategy for authentic recombinant AMP expression. The N-terminal autoprotease, Npro, of classical swine fever virus (CSFV) cleaves itself between the C-terminal Cys168 and position 169 [19], which represent the authentic N-terminal amino acid of the target protein. It is also a relatively hydrophobic protein that tends to form insoluble aggregates on refolding, preventing autoproteolysis [20]. In this approach, the target protein is fused to the C-terminus of Npro and is expressed in inclusion bodies. After inclusion bodies are isolated, an in vitro refolding step is necessary to induce autoproteolysis, and render the AMPs biologically active [21]. Importantly, cleavage does not need to be initiated by the use of reducing agents or by temperature and pH shifts. EDDIE, a mutant of Npro, shows improved solubility and faster refolding and cleavage than wild-type Npro [16]. In our previous work, the fusion protein EDDIE-CAD was successfully expressed in E. coli after codon optimization and the purified recombinant mature Cecropin AD (CAD) was fully bioactive [22].

The in vitro cloning of DNA molecules traditionally uses PCR or site-specific restriction endonucleases to generate linear DNA inserts with defined termini and requires DNA ligase to covalently join these inserts to vectors with the corresponding ends [23]. However, restriction endonuclease sites often introduce a few amino acids to the N-terminus of mature peptides, and it is very difficult to analyze recombinant clones when the insert DNA fragment is very short. For high throughput subcloning of short peptide genes, we constructed the vector, pET30a/His-EDDIE-GFP (Figure 1A), and used a seamless enzyme-free cloning method for high level expression of AMPs in E. coli, This method allows one-step assembly of DNA fragments in vivo via homologous recombination in E. coli [24]. For high level expression, codon usages of synthesized AMP genes were optimized according to the host strains. For efficient analysis of short insert DNA fragments, the recombinants were easily screened by GFP green/white colony selection. In this article, our approach was validated using 6 target AMPs of variable length.

thumbnailFigure 1. Schematic representation of the Construction of (A) pET30a/His-EDDIE-GFP and (B) pET30a/His-EDDIE-AMPs vectors. (A) pET30a/His-EDDIE-CAD was used to constructed pET30a/His-EDDIE-GFP. This plasmid was derived from pET30a and uses a T7-inducible promoter with lac operator, contains the low-copy pBR322 origin of replication, and encodes the kanamycin resistance gene (kanR) and the lac repressor gene (lacI). The GFP gene was inserted at the Sal I site and replaced CAD gene of pET30a/His-EDDIE-CAD, which at downstream positions of the EDDIE gene, give rise to the vector pET30a/His-EDDIE-GFP for expression of AMPs in E. coli. (B) The AMPs genes were inserted downstream of the carrier protein using overlap primer (arrows) at 168 site. The separate of AMPs and carrier partner between self-cleavage sites while in vitro refolding is shown in the square box, while the self-cleavage site is indicated by an arrow.

Results

Construction of his-EDDIE-GFP fusion expression plasmid

The construction of the pET30a/His-EDDIE-GFP vector was based on pET30a/His- EDDIE-CAD. After PCR amplification, the GFP fragment was successfully subcloned into pET30a/His-EDDIE-CAD. Colonies showing green fluorescence were picked and PCR amplification of the GFP gene followed by gel electrophoresis showed that the GFP fragment had been successfully inserted into the expression vector (Figure 2A, B). DNA sequencing validated that the GFP gene was inserted downstream of the EDDIE gene.

thumbnailFigure 2. Agarose gel electrophoresis of the PCR products of the GFP gene and of plasmid pET30a/His-EDDIE-GFP. (A) Lane M: molecular weight marker; Lane 1: plasmid of pET30a/His-EDDIE-CAD; Lane 2: plasmid of pET30a; Lane 3-5: plasmid of pET30a/His-EDDIE-GFP; (B) Lane M: molecular weight marker; Lane 1: PCR products of linearized plasmid pET30a/His-EDDIE-GFP; Lane 2: PCR products of GFP genes used pET30a/His-EDDIE-GFP as template.

Construction of the his-EDDIE-AMP fusion expression plasmid

To clone AMP genes in a high-throughput manner, we performed a green/white colony screen using the GFP in pET30a/His-EDDIE-GFP. After a target gene is cloned into the vector by a one-step PCR technique, the GFP gene is destroyed; therefore, green fluorescence indicates non-linearized parental vector. Four AMP genes, Temporin G, hexapeptide, Combi-1 and Histatin 9 were amplified and cloned downstream of EDDIE using a one-step PCR process, and then transformed into E. coli cells (Figure 3A). BLP-7 and Histatin 6 genes were assembled using four primers in one PCR reaction, respectively (Figure 3B). pET30a/His-EDDIE-GFP was replicated at the same time. The two PCR products were then transformed into E. coli cells together. The transformants were screened under ultraviolet light, and the white colonies were further screened by PCR verification and sequencing. The recombinant pET30a/His-EDDIE-AMP plasmid is smaller than the parental pET30a/His-EDDIE-GFP plasmid, which makes it very easy to distinguish the two plasmids by agarose gel electrophoresis (Figure 3C).

thumbnailFigure 3. Gel analysis of six recombinant pET30a/His-EDDIE-AMP expression vectors. (A) Lane M: molecular weight markers; Lane 1-4: PCR product of four recombinant expression vector pET-His-EDDIE-AMPs; Lane 5: PCR product of vector pET-His-EDDIE-GFP; (B) Lane M: molecular mass makers; Lane 1-2: PCR product of Histatin6 and BLP-7 genes; (C) Lane M: molecular mass makers; Lane 1: plasmid of pET30a/His-EDDIE-GFP; Lane 2-7: plasmids of six pET30a/His-EDDIE-AMPs;.

Expression and purification of fusion proteins

E. coli BL21 (DE3) cells harboring pET30a/His-EDDIE-AMP were induced by IPTG, and the expression of His-EDDIE-AMP proteins was analyzed by SDS-PAGE (Figure 4). Fusion proteins of 20 kDa represented the majority of the insoluble components in cell lysates. The recombinant His-EDDIE-AMPs were estimated to constitute about 40% of the total protein present in cells. The yield of inclusion bodies was quite high due to the properties of the fusion partner (high content of hydrophobic residues).

thumbnailFigure 4. SDS-PAGE analysis of recombinant His-EDDIE-AMPs expressed in E. coli BL21 (DE3). Lane M: the molecular weight markers; Lane 1: crude cells extracts of uninduced E. coli BL21 containing pET-His-EDDIE-AMP; Lane 2: crude cells extracts after 5 h past the induction with IPTG of E. coli BL21 containing pET-His-EDDIE-AMP; The molecular weights of the new protein components agree well with those predicted for the fusion proteins.

Refolding and activity analysis

Purified His-EDDIE-AMP inclusion bodies were diluted in optimized refolding buffer and incubated to enable self-cleavage to occur. To examine the antimicrobial activity of six recombinant AMPs, the purified supernatants were assayed using a radial diffusion assay. As shown in Figure 5, there were large halos around the six AMPs, indicating that all six AMPs had specific bactericidal activities against E. coli ATCC2592, M. luteus or S. cerevisiae. No inhibition zones were seen around the negative control spots. The recombinant AMPs were clearly bioactive and very effective in killing these sensitive strains.

thumbnailFigure 5. Detection of the antibacterial activities of candidate antimicrobial peptides against E. coli and M. luteus. B: refolding buffer; IB: Inclusion bodies of His-EDDIE-AMPs; a: antimicrobial activities assay against S. cerevisiae; b: antimicrobial activities assay against E. coli; c: antimicrobial activities assay against M. luteus; (A) 026, Hexapeptide; (B) 054, BLP-7; (C) 099, Temporin G; (D) 801, human Histatin 6; (E) 726, Combi-1; (F) 803, human Histatin 9.

Discussion

We have described a new method for cloning and expressing AMP genes. The desired AMPs are amplified using ORF-specific primers with flanking sequences identical to the two ends of a linearized vector. The PCR product and the linearized vector are then cotransformed into E. coli cells, where the ORF is incorporated into the vector in vivo. Short AMPs can even directly incorporate into the linearized vector through self-ligation. Unlike conventional methods that use restriction enzymes or site-specific recombinases, PCR products could be seamlessly assembled without the need for specific sequences for ligation or site-specific recombination [25]. This system is more efficient than cloning methods requiring ligase [26,27] and will be useful for standard DNA cloning and for constructing genome-scale clone resources that facilitate functional analysis [23].

Most AMP genes are very small (100-200 bases) and it is difficult to identify recombinant plasmids containing these genes. We, therefore, incorporated the GFP reporter gene into the expression vector to enable convenient recombinant colony picking.

AMPs expressed as Npro fusions are deposited as insoluble proteins in inclusion bodies. This greatly increases yield due to resistance to proteolytic degradation. During refolding in vitro, EDDIE self-cleaved at the specific site and the six target peptides were released. Our construct also encodes the (His)6 affinity tag, preceding the coding regions of EDDIE, to enable fast and straightforward purification using Ni2+-chelating affinity chromatography after refolding. The target peptides could be easily purified to homogeneity.

These results validated this high throughput AMP subcloning method. Using this method, we successfully cloned 40 peptides into the expression vector and identified about 20 new AMPs from Brassica napus cDNA libraries that showed antimicrobial activities (data not shown). This approach, combined with bioinformatic analyses of genome and EST sequence data, will be useful in screening for new AMPs.

Conclusions

In conclusion, this is a simple, reliable, automated, robust, flexible and low-cost expression cloning approach in which PCR fragments are fused into an expression vector without unwanted amino acids. This strategy advances the methodologies available for AMP prokaryote expression. The main barriers to AMP expression, such as, codon preference, the intrinsic antimicrobial activity of AMPs to host cells, and inefficient production of AMPs owing to proteolytic degradation, are overcome by this expression system.

Methods

Materials

E. coli XL-GOLD (Stratagene, USA) was used as the host for subcloning and plasmid amplification. E. coli BL21 (DE3) was used as the host for expression of recombinant protein. E. coli ATCC2592 and M. luteus ACCC11001 were used as indicators in the antimicrobial assay of the six antimicrobial peptides. pET30a (Novagen, Madison, WI, USA) was used as a vector construction and recombinant protein expression plasmid. Restriction enzymes NdeI and SalI were purchased from Takara (Dalian, China).

Construction of the pET30a/His-EDDIE-GFP expression vector

The plasmids containing the Npro mutant, EDDIE, were constructed according to Zhang et al. [22]. To enable green/white screening of recombinant clones (green colonies indicate the presence of uncut parental vector), the PCR primers Gf and Gr were designed according to the reported DNA sequence of GFP (GenBank accession no. ABN41558), with an added 18 bases flanking the sequences complementary to the two ends of linearized vector (Table 1). The pET30a/His-EDDIE-CAD vector was amplified using primers Pf and Pr (25 cycles of 95°C for 10 s, 65°C for 30 s, and 72°C for 6 min using Pyrobest DNA polymerase; Takara Bio Inc., Shiga, Japan), and the linear PCR product, with 18 bases at each end homologous to GFP, was digested by DpnI and purified. The plasmid was then generated by the seamless enzyme free cloning method [24], and was named pET30a/His-EDDIE-GFP (Figure 1). 5 μL of purified PCR product (100-300 ng) and 1 μL (50 ng) of the appropriately linearized vector were mixed and transformed into 50 μL of E. coli XL-GOLD chemically competent cells by heat shock and then plated on selection plates (containing 50 μg/mL kanamycin). The recombinant colonies were easily selected by visualizing GFP fluorescence under ultraviolet light.

Table 1. Primers for vector construction

Construction of the AMP expression vector with EDDIE as a fusion partner

Six AMPs were selected from the AMP database [28] (Table 2). The AMP sequences were optimized according to E. coli codon usage. For short AMPs, the sense and antisense primers contained the reported DNA sequence and 18 bases of overlap with each other. Their 3' ends also contained the EDDIE C-terminal sequences and the ends of MCS of the vector, respectively. For longer AMPs, BLP-7 and Histatin 6, genes were assembled using 4 primers in a one-step PCR reaction. Vector was amplified with the PCR primers, backboneF and backboneR, which were designed according to the EDDIE C-terminal sequences and the ends of MCS of the vector, respectively (Table 3). The pET30a/His-EDDIE-GFP vector was amplified with the primers, and the linearized vector was purified and digested with DpnI. The PCR reaction was carried out for 25 cycles, each cycle consisting of 30 s at 94°C, 30 s at 62°C, and 7 min at 72°C. The PCR products covalently join to vectors with the corresponding ends in vivo when transformed into E. coli. White colonies were picked, and then sequenced to ensure that the coding sequence was correct. The resulting plasmids were named pET30a/His-EDDIE-AMPs, respectively (Figure 1B).

Table 2. Antimicrobial peptides expressed in this research

Table 3. Antimicrobial peptides expressed in this research

Expression and purification of fusion protein

The pET30a/His-EDDIE-AMP plasmids were transformed into the expression host, E. coli BL21 (DE3) (Novagen, Madison, WI, USA). One colony was used to inoculate 50 mL LB (1% Bacto-tryptone, 0.5% yeast extract, and 8 mM NaCl) medium supplemented with 50 μg/mL kanamycin, and grown overnight in a 37°C in a shaking incubator. The fully grown culture was mixed with 1 L LB medium with the same antibiotics the next morning. The culture was grown at 25°C, and IPTG was added to a final concentration of 1 mM when the OD600 reached 0.5. The culture was harvested 5 h later and the cells were washed and resuspended in 30 mL PBS buffer (NaCl 137 mM, KCl 2.7 mM, Na2HPO4 4.3 mM, KH2PO4 1.4 mM, pH 7.2-7.4). The cells were lysed by freeze-thaw and the DNA was fragmented by ultrasonication. The insoluble inclusion bodies were isolated by 14,000 × g centrifugation for 30 min in 4°C. The pellet was washed three times with washing buffer (10 mM Tris/HCl, pH 7.6; 200 mM NaCl, 2 mM 2-mercaptoethanol, and 1% Triton X-100) and then solubilized in denaturing buffer (8 M urea; 20 mM Tris-HCl, pH 7.6; and 5 mM 2-mercaptoethanol).

Refolding and activity analysis

Purified His-EDDIE-AMPs inclusion bodies were refolded by rapid 1:50 dilution in optimized refolding buffer (500 mM NaCl, 20 mM Tris, 2 mM EDTA, 5% glycerol, 10 mM DTT, 0.01% Tween-20, pH 7.5) and incubated at an appropriate temperature without stirring. During refolding, EDDIE restored its correct conformation and self-cleaved at the specific site, releasing AMPs from the fusion bodies. Renatured protein solution was then clarified by 15,000 × g centrifugation for 30 min in 4°C. Then the insoluble sample was removed by filtering through 0.45 μm membrane and AMPs were left in the supernatant. The supernatants were applied to a Ni-NTA His-bind column for purification.

Standard SDS-PAGE (12% gel) was applied to assay fusion proteins. Band density was analyzed using a GEL-DOC 2000 gel documentation system (BIO-Rad, Hemel Hempstead, UK) and Quantity One software, version 4.4.0 was used to determine the fraction of target protein. EDDIE protein was quantified using a BCA protein assay kit (Pierce, Rockford, IL, USA). Antimicrobial activity of recombinant AMPs was detected using a radial diffusion assay [29]. Briefly, E. coli ATCC2592, M. luteus ACCC11001 and S. cerevisiae were grown to the mid-logarithmic phase and washed. Approximately 2 × 106 cfu/mL bacteria were incorporated into a thin (1.2 mm) agarose underlay gel that contained 1% (wt/vol) agarose. Holes of 3.5 mm diameter were punched into the solidified agarose and these were filled with 100 μL of AMP sample. After the plates were incubated for 12 h at 37°C, the diameter of the clear zone surrounding each well was measured to evaluate the antimicrobial activity. Refolding buffer and inclusion bodies were used as negative controls. The above assays were performed in triplicate.

Competing interests

The authors declare that they have no competing interests.

Authors' contributions

TK and XDM made substantial contributions to conception and design. TK and SL carried out the experiments and wrote the manuscript. JBC and JXK participated in drafted the manuscript. JH, JYH and DQL participated in the experiments. HM, CHD and SYL participated in reviewing the manuscript and given final approval of the version to be published. All authors read and approved the final manuscript.

Acknowledgements

This work was supported by Genetically modified organisms major breeding projects (Grant No. 2009ZX08004-002B), the Research Planning Project of Basic and Advanced Technology of Henan Province, China (no. 112102310093), the Natural Science Foundation of Henan Educational Department, China (no. 2009B180018), the Open Project of Key Laboratory for Oil Crops Biology, the Ministry of Agriculture, PR China (201202) and the Funding of Nanyang Normal University (no. nynu200748).

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