Recombinant expression of glpK and glpD genes improves the accumulation of shikimic acid in E. coli grown on glycerol.

Shikimic acid (SA) is an industrially important chiral compound used in diverse commercial applications, and the insufficient supply by isolation from plants and expensive chemical synthesis of SA has increased the importance of developing strategies for SA synthesis. In our previous studies, glycerol was observed to be an effective carbon source for SA accumulation in E. coli DHPYAAS-T7, where the PTS operon (ptsHIcrr) and aroL and aroK genes were inactivated, and the tktA, glk, aroE, aroF (fbr) , and aroB genes were overexpressed. For further investigation of the effects of glycerol aerobic fermentation on SA accumulation in E. coli BL21(DE3), the glpD, glpK genes and tktA, glk, aroE, aroF (fbr) , aroB genes were overexpressed simultaneously. The results indicated that SA production was increased 5.6-fold, while the yield was increased 5.3-fold over that of parental strain in shake flasks. It is demonstrated that the aerobic fermentation of glycerol associated with glpD and glpK gene overexpression increased glycerol flux, resulting in higher SA accumulation in E. coli BL21(DE3)-P-DK.

Production of Nα-acetylated thymosin α1 in Escherichia coli.

BACKGROUND: Thymosin α1 (Tα1), a 28-amino acid Nα-acetylated peptide, has a powerful general immunostimulating activity. Although biosynthesis is an attractive means of large-scale manufacture, to date, Tα1 can only be chemosynthesized because of two obstacles to its biosynthesis: the difficulties in expressing small peptides and obtaining Nα-acetylation. In this study, we describe a novel production process for Nα-acetylated Tα1 in Escherichia coli. RESULTS: To obtain recombinant Nα-acetylated Tα1 efficiently, a fusion protein, Tα1-Intein, was constructed, in which Tα1 was fused to the N-terminus of the smallest mini-intein, Spl DnaX (136 amino acids long, from Spirulina platensis), and a His tag was added at the C-terminus. Because Tα1 was placed at the N-terminus of the Tα1-Intein fusion protein, Tα1 could be fully acetylated when the Tα1-Intein fusion protein was co-expressed with RimJ (a known prokaryotic Nα-acetyltransferase) in Escherichia coli. After purification by Ni-Sepharose affinity chromatography, the Tα1-Intein fusion protein was induced by the thiols ß-mercaptoethanol or d,l-dithiothreitol, or by increasing the temperature, to release Tα1 through intein-mediated N-terminal cleavage. Under the optimal conditions, more than 90% of the Tα1-Intein fusion protein was thiolyzed, and 24.5 mg Tα1 was obtained from 1 L of culture media. The purity was 98% after a series of chromatographic purification steps. The molecular weight of recombinant Tα1 was determined to be 3107.44 Da by mass spectrometry, which was nearly identical to that of the synthetic version (3107.42 Da). The whole sequence of recombinant Tα1 was identified by tandem mass spectrometry and its N-terminal serine residue was shown to be acetylated. CONCLUSIONS: The present data demonstrate that Nα-acetylated Tα1 can be efficiently produced in recombinant E. coli. This bioprocess could be used as an alternative to chemosynthesis for the production of Tα1. The described methodologies may also be helpful for the biosynthesis of similar peptides.

Rationally optimized generation of integrated Escherichia coli with stable and high yield lycopene biosynthesis from heterologous mevalonate (MVA) and lycopene expression pathways.

The stability and high productivity of heterogeneous terpenoid production in Escherichia coli expression system is one of the most key issues for its large scale industrialization. In the current study on taking lycopene biosynthesis as an example, an integrated Escherichia coli system has been generated successfully, which resulted into stable and high lycopene production. In this process, two modules of mevalonate (MVA) pathway and one module of lycopene expression pathway were completely integrated in the chromosome. Firstly, the copy number and integrated position of three modules of heterologous pathways were rationally optimized. Later, a strain DH416 equipped with heterogeneous expression pathways through chromosomal integration was efficiently derived from parental strain DH411. The evolving DH416 strain efficiently produced the lycopene level of 1.22 g/L (49.9 mg/g DCW) in a 5 L fermenter with mean productivity of 61.0 mg/L/h. Additionally, the integrated strain showed more genetic stability than the plasmid systems after successive 21st passage.

Correction: An electroporation-free method based on Red recombineering for markerless deletion and genomic replacement in the Escherichia coli DH1 genome.

[This corrects the article DOI: 10.1371/journal.pone.0186891.].

RimJ is responsible for N(alpha)-acetylation of thymosin alpha1 in Escherichia coli.

N(alpha)-Acetylation is one of the most common protein modifications in eukaryotes but a rare event in prokaryotes. Some endogenously N(alpha)-acetylated proteins in eukaryotes are frequently reported not to be acetylated or only very partially when expressed in recombinant Escherichia coli. Thymosin alpha1 (Talpha1), an N(alpha)-acetylated peptide of 28 amino acids, displays a powerful general immunostimulating activity. Here, we revealed that a fusion protein of thymosin alpha1 and L12 is partly N(alpha)-acetylated in E. coli. Through deletion of some N(alpha)-acetyltransferases by Red recombination, we found that, when rimJ is disrupted, the fusion protein is completely unacetylated. The relationship of rimJ and N(alpha)-acetylation of Talpha1 was further investigated by gene rescue and in vitro modification. Our results demonstrate that N(alpha)-acetylation of recombinant Talpha1-fused protein in E. coli is catalyzed by RimJ and that fully acetylated Talpha1 can be obtained by co-expressing with RimJ. This is the first description that an ectopic protein acetylation in bacterial expression systems is catalyzed by RimJ, a known prokaryotic N(alpha)-acetyltransferase.

Enhanced production of biosynthesized lycopene via heterogenous MVA pathway based on chromosomal multiple position integration strategy plus plasmid systems in Escherichia coli.

The multiple plasmid system, mostly relied, for heterogeneous gene expression, results in genetic instability and low mean productivity. To address this, an integration method was employed for investigating expression of heterogenous pathway in E. coli cells; where mevalonate upper pathway was found efficiently expressed. Subsequently, to improve lycopene production, chromosomal multiple position integration strategy was used to strengthen mevalonate upper pathway. Meanwhile, the plasmid system was employed for mevalonate lower pathway and lycopene pathway expression to finally generate the mutant D711 strain. Comparatively, highest level of 68.5 mg/L lycopene was produced by D711 outperforming its maximum average productivity of 2.85 mg/L/h with over 2-folds enhancement. In addition, lycopene level was almost 224 mg/L after optimization of induction time, which was 3.3-fold higher than standard control condition. Finally, expression Performance Parameter was developed for scoring mutants and evaluating these two strategies, indicating chromosomal multiple position integration strategy as more efficient approach.

Highly effective biosynthesis of N-acetylated human thymosin ß4 (Tß4) in Escherichia coli.

Thymosin ß4 (Tß4) is a multifunctional N-acetylated peptide with distinct activities important at various stages. Due to its potential multiple therapeutic uses in many fields, there is an increasing need of Tß4 at lower costs than with the use of chemical synthesis. In this research, we developed a method to produce rhTß4 with N-acetylation in E. coli. Firstly, the E. coli strain whose chromosome being integrated by the specific N-terminal acetyltransferase ssArd1 was constructed. Secondly, the rhTß4-Intein was constructed, in which rhTß4 was fused to the N-terminus of the smallest mini-intein Spl DnaX. The rhTß4 could be fully acetylated when the rhTß4-Intein was expressed in the engineering strain. After purification, the rhTß4-Intein fusion protein was induced with dithiothreitol (DTT) to release rhTß4 through intein-mediated N-terminal cleavage. Under the optimal conditions, the N-terminal serine residue was shown to be 100% acetylated and the yield of N-acetylated rhTß4 can reach 200 mg per litre. The N-acetylated rhTß4 could be stable at 2-8 °C for 24 months in PBS buffer without protein degradation and concentration change. The N-acetylated rhTß4 also showed the activity of binding with actins from different sources and excellent therapeutic effect on the rats with moderate to severe dry eye disease.

An electroporation-free method based on Red recombineering for markerless deletion and genomic replacement in the Escherichia coli DH1 genome.

The λ-Red recombination system is a popular method for gene editing. However, its applications are limited due to restricted electroporation of DNA fragments. Here, we present an electroporation-free λ-Red recombination method in which target DNA fragments are excised by I-CreI endonuclease in vivo from the landing pad plasmid. Subsequently, the I-SceI endonuclease-cutting chromosome and DNA double-strand break repair were required. Markerless deletion and genomic replacement were successfully accomplished by this novel approach. Eight nonessential regions of 2.4-104.4 kb in the Escherichia coli DH1 genome were deleted separately with selection efficiencies of 5.3-100%. Additionally, the recombination efficiencies were 2.5-45%, representing an order of magnitude improvement over the electroporation method. For example, for genomic replacement, lycopene expression flux (3.5 kb) was efficiently and precisely integrated into the chromosome, accompanied by replacement of nonessential regions separately into four differently oriented loci. The lycopene production level varied approximately by 5- and 10-fold, corresponding to the integrated position and expression direction, respectively, in the E. coli chromosome.

[Markerless DNA deletion based on Red recombination and in vivo I-Sec I endonuclease cleavage in Escherichia coli chromosome].

Red-based recombineering has been widely used in Escherichia coli genome modification through electroporating PCR fragments into electrocompetent cells to replace target sequences. Some mutations in the PCR fragments may be brought into the homologous regions near the target. To solve this problem in markeless gene deletion we developed a novel method characterized with two-step recombination and a donor plasmid. First, generated by PCR a linear DNA cassette which comprises a I-Sec I site-containing marker gene and homologous arms was electroporated into cells for marker-substitution deletion of the target sequence. Second, after a donor plasmid carrying the I-Sec I site-containing fusion homologous arm was chemically transformed into the marker-containing cells, the fusion arms and the marker was simultaneously cleaved by I-Sec I endonuclease and the marker-free deletion was stimulated by double-strand break-mediated intermolecular recombination. Eleven nonessential regions in E. coli DH1 genome were sequentially deleted by our method, resulting in a 10.59% reduced genome size. These precise deletions were also verified by PCR sequencing and genome resequencing. Though no change in the growth rate on the minimal medium, we found the genome-reduced strains have some alteration in the acid resistance and for the synthesis of lycopene.

Direct cloning and transplanting of large DNA fragments from Escherichia coli chromosome.

We applied a resistance split-fusion strategy to increase the in vivo direct cloning efficiency mediated by Red recombination. The cat cassette was divided into two parts: cma (which has a homologous sequence with cmb) and cmb, each of which has no resistance separately unless the two parts are fused together. The cmb sequence was integrated into one flank of a target cloning region in the chromosome, and a linear vector containing the cma sequence was electroporated into the cells to directly capture the target region. Based on this strategy, we successfully cloned an approximately 48 kb DNA fragment from the E. coli DH1-Z chromosome with a positive frequency of approximately 80%. Combined with double-strand breakage-stimulated homologous recombination, we applied this strategy to successfully replace the corresponding region of the E. coli DH36 chromosome and knock out four non-essential genomic regions in one step. This strategy could provide a powerful tool for the heterologous expression of microbial natural product biosynthetic pathways for genome assembly and for the functional study of DNA sequences dozens of kilobases in length.

Receptor-binding domain of SARS-Cov spike protein: soluble expression in E. coli, purification and functional characterization.

AIM: Spike protein of coronavirus is responsible for virus binding, fusion and entry, and is a major inducer of neutralizing antibodies. This paper was to find a soluble and functional recombinant receptor-binding domain of severe acute respiratory syndrome-associated coronavirus (SARS-Cov), and to analyze its receptor binding ability. METHODS: Three fusion tags (glutathione S-transferase, GST; thioredoxin, Trx; maltose-binding protein, MBP), which preferably contributes to increasing solubility and to facilitating the proper folding of heteroprotein, were used to acquire the soluble and functional expression of RBD protein in Escherichia coli (BL21(DE3) and Rosetta-gamiB(DE3) strains). The receptor binding ability of the purified soluble RBD protein was then detected by ELISA and flow cytometry assay. RESULTS: RBD of SARS-Cov spike protein was expressed as inclusion body when fused as TrxA tag form in both BL21 (DE3) and Rosetta-gamiB (DE3) under many different cultures and induction conditions. And there was no visible expression band on SDS-PAGE when RBD was expressed as MBP tagged form. Only GST tagged RBD was soluble expressed in BL21(DE3), and the protein was purified by AKTA Prime Chromatography system. The ELISA data showed that GST/RBD antigen had positive reaction with anti-RBD mouse monoclonal antibody 1A5. Further flow cytometry assay demonstrated the high efficiency of RBD's binding ability to ACE2 (angiotensin-converting enzyme 2) positive Vero E6 cell. And ACE2 was proved as a cellular receptor that meditated an initial-affinity interaction with SARS-Cov spike protein. The geometrical mean of GST and GST/RBD binding to Vero E6 cells were 77.08 and 352.73 respectively. CONCLUSION: In this paper, we get sufficient soluble N terminal GST tagged RBD protein expressed in E.coli BL21(DE3); data from ELISA and flow cytometry assay demonstrate that the recombinant protein is functional and binding to ACE2 positive Vero E6 cell efficiently. And the recombinant RBD derived from E.coli can be used to developing subunit vaccine to block S protein binding with receptor and to neutralizing SARS-Cov infection.

[Construction and expression of humanized anti-HBsAg scFv targeting interferon-alpha in escherichia coli].

OBJECTIVE: To develop a bacteria expression system to produce the fusion protein of humanized anti-HBsAg scFV and interferon-alpha. METHODS: The expression vector was constructed after cleaving the plasmids harboring the humanized anti-HBsAg scFv and interferon alpha respectively and ligating to linearized pET22b subsequence. The expression of fusion protein in E.coli was analyzed by SDS-PAGE. The binding activity and antiviral activity of the fusion protein was characterized by competing inhibition test and cytopathic effect reduction. RESULTS: The plasmid harboring the in frame arranged fusion gene was constructed and identified. After induction for 12h, a new band close to 4.5 10(4) was observed using SDS-PAGE. Results of competing ELISA and cytopathic effect reduction showed the fusion protein retained its specific binding activity and antiviral activities. CONCLUSIONS: The construction and expression of the fusion gene of humanized anti-HBsAg scFv and interferon in E.coli are successful.

Influence of time and length size feature selections for human activity sequences recognition.

In this paper, Viterbi algorithm based on a hidden Markov model is applied to recognize activity sequences from observed sensors events. Alternative features selections of time feature values of sensors events and activity length size feature values are tested, respectively, and then the results of activity sequences recognition performances of Viterbi algorithm are evaluated. The results show that the selection of larger time feature values of sensor events and/or smaller activity length size feature values will generate relatively better results on the activity sequences recognition performances.

Human activity recognition based on feature selection in smart home using back-propagation algorithm.

In this paper, Back-propagation(BP) algorithm has been used to train the feed forward neural network for human activity recognition in smart home environments, and inter-class distance method for feature selection of observed motion sensor events is discussed and tested. And then, the human activity recognition performances of neural network using BP algorithm have been evaluated and compared with other probabilistic algorithms: Naïve Bayes(NB) classifier and Hidden Markov Model(HMM). The results show that different feature datasets yield different activity recognition accuracy. The selection of unsuitable feature datasets increases the computational complexity and degrades the activity recognition accuracy. Furthermore, neural network using BP algorithm has relatively better human activity recognition performances than NB classifier and HMM.

Deletion of the aroK gene is essential for high shikimic acid accumulation through the shikimate pathway in E. coli.

Shikimic acid (SA) is an important metabolic intermediate with diverse commercial applications. In this work, antisense RNA interference and gene deletion were carried out to inactivate the aroK gene in an SA-producing Escherichia coli strain, DHPYA-T7. In this strain, the aroL, ptsHIcrr and ydiB genes are deleted, and the tktA, glk, aroE and aroB genes are overexpressed. Flask cultivations of the DHPYA-T7 derivative strains showed that the accumulation of SA increased 2.69-fold after aroK gene deletion (DHPYAAS-T7) and 1.29-fold after antisense RNA interference (DHPYAS-T7). Furthermore, the activity of shikimate kinase in DHPYAAS-T7 was 0.21-fold of that in strain DHPYAS-T7. In a 10-L fermentation, SA accumulation increased to 1850 mg L(-1) in strain DHPYAAS-T7, which is a 1.5-fold increase over that in strain DHPYAS-T7. These results demonstrate that aroK gene inactivation in DHPYA-T7 leads to high SA accumulation, especially when this inactivation is caused by chromosomal deletion.

[Biosynthesis of amorpha-4,11-diene, a precursor of the antimalarial agent artemisinin, in Escherichia coli through introducing mevalonate pathway].

Artemisinin-based combination therapies (ACTs) are recommended to be the most effective therapies for the first-line treatment of uncomplicated falciparum malaria. However, artemisinin is often in short supply and unaffordable to most malaria patients, which limits the wide use of ACTs. Production of amorpha-4,11-diene, an artemisinin precursor, was investigated by engineering a heterologous isoprenoid biosynthetic pathway in Escherichia coli. The production of amorpha-4,11-diene was achieved by expression of a synthetic amorpha-4,11-diene synthase gene in Escherichia coli DHGT7 and further improved by about 13.3 fold through introducing the mevalonate pathway from Enterococcus faecalis. After eliminating three pathway bottlenecks including amorpha-4,11-diene synthase, HMG-CoA reducase and mevalonate kinase by optimizing the metabolic flux, the yield of amorpha-4,11-diene was increased by nearly 7.2 fold and reached at 235 mg/L in shaking flask culture. In conclusion, an engineered Escherichia coli was constructed for high-level production of amorpha-4,11-diene.

Studies of the in vitro Nalpha-acetyltransferase activities of E. coli RimL protein.

Although the Escherichia coli N(alpha)-acetyltransferase RimL catalyzing the N-terminal acetylation of L12 have been identified through mutant analysis, little is known about its enzymatic activity and auxiliary subunit requirement. This study was to investigate the enzymatic activities of RimL and its substrate specificity. RimL, its substrate L12, and two mutant substrates L12S1A and L12I2D were overexpressed and purified from E. coli. In vitro experimental results revealed that RimL itself can convert L12 to L7 by acetylation of the N-terminal serine residue. The K(m) value for L12 was 0.55 microM and the V(max) was 25.71 min(-1) as determined by a spectrophotometrical method. We also found that RimL acetylated the L12S1A mutant with an N-terminal alanine residue instead of the native serine residue, suggesting RimL can acetylate other N-terminal residues. Furthermore, when the second N-terminal residue isoleucine was replaced by aspartic acid, the mutant L12I2D was also acetylated by RimL but under a much lower rate.

[Expression, purification and characterization of rat procarboxypeptidase B in Pichia pastoris].

Carboxypeptidase B is a metalloenzyme, which is widely used for commercial and research purposes. Commercially available CPB purified from porcine or bovine pancreas is very expensive, and is not totally free from other proteases. In order to express the rat proCPB in Pichia pastoris, total RNA extracted from SD rat pancreas cells was reversely transcripted to synthesize cDNA, and the proCPB ORF was synthesized by PCR. After digestion with Xho I and EcoR I , the fragment was inserted into pPIC9, and the recombinant plasmid was named as pPIC9-proCPB. By digestion with Sac I , the lined pPIC9-proCPB was transformed into Pichia pastoris strains GS115 with PEG1000 and integrated into their genomes. In the inducement of methanol, recombinant proCPB was successfully expressed in Pichia pastoris, and could be secreted into the supernatant in the culture. After optimizing the fermentation conditions, a higher production could be obtained when GS115-proCPB was induced in BMGY (pH6.0) at 28CC, with addition of 0.5% casein. The yield of recombinant protein reached 500mg/L, achieving over 94% of total protein in the culture supernatant. The purity of recombinant CPB can reach 96% after two step phenyl sepharose F F purification, and 38% of total protein can obtained after optimizing the pufication method. Comparing to the specific activity 180u/mg of CPB purchased from Sigma, the specific activity of recombinant CPB is 110u/mg. Mass spectrometry analyses showed the mass of the recombinant CPB was 35.1 kD, which is very close to the theory value 35.2 kD. Amino acid sequencing of N-terminal of recombinant CPB further indicated proCPB was expressed successfully and modificated correctly after translation.

[Recombinant batroxobin expressed highly in Pichia pastoris].

Methylotrophic yeast, Pichia pastoris was used to express recombinant batroxobin, and a technology route of producing recombinant protein was finally established. We synthesized batroxobin gene artificially by means of recursive PCR. pPIC9-batroxobin was constructed and transformed into Pichia pastoris GS115 (his4). Recombinant batroxobin was expressed in yeast engineering strain and it was purified from the culture supernatant. 10 mg of recombinant batroxobin was purified from 1 liter fermentation media, it exhibited specific activity of 238 NIH units/mg and had molecular weight of 30.55 kD. The purified recombinant protein converted fibrinogen into fibrin clot in vitro, and shortened bleeding time in vivo. This study laid a foundation of development of hemostatic of recombinant snake venom thrombin-like enzyme.

Expression and purification of ancrod, an anticoagulant drug, in Pichia pastoris.

Ancrod is known as a thrombin-like enzyme from the venom of Calloselasma rhodostoma. The cDNA encoding ancrod was synthesized with a yeast bias codon and inserted into the eukaryotic expression vector pPIC9 and was subsequently expressed in the yeast Pichia pastoris. Recombinant ancrod was produced in 5-L bioreactor using a sorbitol-methanol feeding strategy and recovered from the fermentation broth by hydrophobic, affinity, and ion exchange chromatography. SDS-PAGE analysis revealed that ancrod was heterogeneously glycosylated and running at the expected molecular weight of 43-48 kDa which decreased to about 29 kDa after deglycosylation with N-glycosidase F. The fibrinogenolytic and zymographic activity of the recombinant ancrod were determined and were found to be similar to that of the native protein.