重组牛肠激酶轻链基因在毕赤酵母中的表达与纯化

目的:构建重组牛肠激酶轻链的基因工程菌,并进行表达和纯化,以获得高纯度和高活性的重组牛肠激酶轻链蛋白。方法:以GenBank公共数据库中的牛肠激酶轻链基因序列(AccessionNo.NM174439)设计引物,利用RT-PCR合成牛肠激酶轻链基因片段,并克隆进pPIC9K载体,同时在基因N端插进6个组氨酸标签,转化毕赤酵母GS115,进行筛选和诱导表达。产物经镍离子螯和层析和Q-SepharoseFF柱纯化,并酶切融合蛋白检测其活性。结果:培养液中重组牛肠激酶轻链蛋白表达量为3.0mg/L。对含有肠激酶酶切位点的IL-11/MBP融合蛋白进行酶切,结果表明,酶解率可达到90%以上。结论:表达并获得了高纯度的重组肠激酶轻链蛋白,为大规模生产打下了基础。     

重组牛肠激酶轻链基因在大肠杆菌中的表达与纯化

肠激酶（Enteroloinase,EK,EC3.4.21.9）是一种以异源二聚体形式存在于哺乳动物十二指肠内的丝氨酸蛋白酶,通过在位点（Asp）4-Lys的羧基端进行高效特异酶切,将胰蛋白酶原激活为胰蛋白酶。以GenBank公共数据库中牛肠激酶轻链基因序列（Accession No.NM174439）设计引物,利用RT-PCR方法合成牛肠激酶轻链基因片段,并克隆进pET39b载体中DsbA片段的C’端,转化大肠杆菌BL21（DE3）,获得DsbA/牛肠激酶轻链融合蛋白,经镍离子螯合层析纯化,每升培养液中可得到2.7-3.0mg重组牛肠激酶,对含有肠激酶酶切位点的IL-11/MBP融合蛋白进行酶切,结果表明,酶解率可达到95%以上,为重组牛肠激酶的大规模生产打下了基础。     

Expression of recombinant chinese bovine enterokinase catalytic subunit in P. pastoris and its purification and characterization

EK (enterokinase) is a serine proteinase which consistsof a heavy chain and a light chain linked by a disulfidebond. The light chain of EK contains a chymotrypsin-likeserine proteinase domain sufficient for the normal recog-nition and cleavage of EK subst…     

Expression of catalytic subunit of bovine enterokinase in the filamentous fungus Aspergillus niger

The cDNA encoding for catalytic subunit of bovine enterokinase (EK(L)), to which the sequence for Kex2 protease cleavage site was inserted, was expressed in the protease deficient filamentous fungus Aspergillus niger AB1.13. Fungal transformants were obtained in which expression of the glucoamylase fusion gene resulted in secretion of the protein into growth medium. Fusion polypeptide was processed to mature EK(L) by endogenous Kex-2 like protease cleavage during secretory pathway. The highest quantity of EK(L), up to 5 mg l(-1), was obtained in soya milk medium. The secreted EK(L) was easily purified from other proteins found in A. niger culture supernatant, using ion exchange and affinity chromatography. The yield of the purified and highly active EK(L) was 1.9 mg l(-1) of culture.     

Expression,purification, and characterization of human enteropeptidase catalytic subunit in Escherichia coli

Enteropeptidase (synonym:enterokinase, EC 3.4.21.9) is a heterodimeric serine protease of the intestinal brush border that activates trypsinogen by highly specific cleavage of the trypsinogen activation peptide following the sequence (Asp)(4)-Lys. The DNA sequence encoding the light chain (catalytic subunit) of human enteropeptidase (GenBank Accession No. U09860) was synthesized from 26 oligonucleotides by polymerase chain reaction and cloned into plasmid pET-32a downstream to the gene of fusion partner thioredoxin immediately after the DNA sequence encoding enteropeptidase recognition site. The fusion protein thioredoxin/human enteropeptidase light chain was expressed in Escherichia coli BL21(DE3) strain in both soluble and insoluble forms. The soluble recombinant fusion protein failed to undergo autocatalytic cleavage and activation; however, autocatalytic cleavage and activation of recombinant human enteropeptidase light chain (L-HEP) were achieved by solubilization and renaturation of the fusion protein from inclusion bodies and the active L-HEP was purified on agarose-linked soybean trypsin inhibitor. The purified L-HEP cleaved the synthetic peptide substrate Gly-Asp-Asp-Asp-Asp-Lys-beta-naphthylamide with kinetic parameters K(m)=0.16 mM and k(cat)=115 s(-1) and small ester Z-Lys-SBzl with K(m)=140 microM, k(cat)=133 s(-1). L-HEP associated with soybean trypsin inhibitor slowly and small ester Z-Lys-SBzl cleavage was inhibited with K(i)(*)=2.3 nM. L-HEP digested thioredoxin/human epidermal growth factor fusion protein five times faster than equal activity units of bovine recombinant light chain (EKMax, Invitrogen) at the same conditions.     

Recombinant enterokinase light chain with affinity tag: expression from Saccharomyces cerevisiae and its utilities in fusion protein technology.

Enterokinase and recombinant enterokinase light chain (rEK(L)) have been used widely to cleave fusion proteins with the target sequence of (Asp)(4)-Lys. In this work, we show that their utility as a site-specific cleavage agent is compromised by sporadic cleavage at other sites, albeit at low levels. Further degradation of the fusion protein in cleavage reaction is due to an intrinsic broad specificity of the enzyme rather than to the presence of contaminating proteases. To offer facilitated purification from fermentation broth and efficient removal of rEK(L) after cleavage reaction, thus minimizing unwanted cleavage of target protein, histidine affinity tag was introduced into rEK(L). Utilizing the secretion enhancer peptide derived from the human interleukin 1 beta, the recombinant EK(L) was expressed in Saccharomyces cerevisiae and efficiently secreted into culture medium. The C-terminal His-tagged EK(L) was purified in a single-step procedure on nickel affinity chromatography. It retained full enzymatic activity similar to that of EK(L), whereas the N-terminal His-tagged EK(L) was neither efficiently purified nor had any enzymatic activity. After cleavage reaction of fusion protein, the C-terminal His-tagged EK(L) was efficiently removed from the reaction mixture by a single passage through nickel-NTA spin column. The simple affinity tag renders rEK(L) extremely useful for purification, post-cleavage removal, recovery, and recycling and will broaden the utility and the versatility of the enterokinase for the production of recombinant proteins.     

Purification and refolding optimization of recombinant bovine enterokinase light chain overexpressed in Escherichia coli

The nucleotide sequence encoding bovine enterokinase light chain (EK) from Chinese northern yellow bovine was isolated. Two single-nucleotide mutations, namely, C245G and A528T were identified. The gene encoding the Pro82Arg/Glu176Asp variant of known bovine EK was fused with glutathione S-transferase and overexpressed mainly as an inclusion body in Escherichia coli BL21 (DE3), upon induction with IPTG and glucose. Effective fusion protein purification, refolding, auto-catalytic cleavage and mature EK recovery were described. The specific activity of the purified EK was determined as 110+/- 10 U/mg, which was comparable to a specific activity of > or =20 U/mg of the E. coli expressed EK sample provided by Sigma (Cat. No. E4906). This procedure produced approximately 53 mg of EK per 500 mL of cell culture, which was much higher than previous reports, thus providing a basis for large-scale production of EK and for further applications in biotechnology.     

牛肠激酶轻链基因的克隆及其在大肠杆菌中的融合表达

为克隆表达牛肠激酶（enterokinase）轻链(EKL)编码基因,以期应用于融合蛋白的切割与纯化,从市售北方黄牛十二指肠组织中提取总RNA,以RT-PCR方法扩增其cDNA片段,将此片段克隆于pUCmT载体中,经过特异性限制性内切酶酶切分析片段正确后,进行全序列分析。结果表明,克隆的cDNA与GenBank上的序列相比完全一致,得到了编码正确的牛肠激酶轻链基因全序列。随后,将目的基因片段插入pET39b中,构建了融合型表达载体pET39b-EKL,转化大肠杆菌BL21(DE3),用IPTG诱导表达。所获得的pET39b-EKL经过酶切鉴定和测序,证实其插入方向、读码框架正确,所表达重组蛋白经SDS-PAGE分析,相对分子量为65 kDa,表达量达28%,通过镍亲和层析纯化得到融合蛋白DsbA-rEKL的单一条带。该粗酶经脱盐后在适宜的缓冲体系中21℃温育过夜,显示出较高的自催化切割活性,为进一步进行重组牛肠激酶活性的研究及应用奠定了基础。 Abstract:The objective of the study was to obtain the gene of bovine enterokinase light chain,which would be used in the cleavage and purification of fusion proteins．The fragment of bovine enterokinase light chain cDNA was obtained by RT-PCR from a sold bovine′s duodenal mucosa, then cloned into the pUCmT cloning vector and sequenced.Compared with the sequence deposited in GenBank,the cloned gene sequence is correct.Then the interested gene fragment was inserted into the pET39b expression plasmid.The recombinant vector pET39b-EKL was transformed into E.coli BL21(DE3) and induced by IPTG.It was confirmed that the nucleotide sequence was correct on the conjunction site between the recombinant DNA 5′terminal multi-cloning site and recombinant fragment after the analysis of the nucleotide sequence.SDS-PAGE analysis indicated that target product was about 65 kDa which occupied 28% of the total protein.A pure fusion protein was obtained by nickel chelating chromatogram using His*Binding Resin.After desalting and changing buffer,the crude kinase was incubated at 21℃ overnight and demonstrated a high autocatalytic cleavage activity.This investigation would be able to lay a foundation for enterokinase activity research and farther application of expression products on a large scale.     

A novel and simple method for high-level production of reverse transcriptase from Moloney murine leukemia virus (MMLV-RT) in <Emphasis Type="Italic">Escherichia coli</Emphasis>

A novel protocol for producing recombinant Moloney murine leukemia virus (MMLV-RT) in Escherichia coli is reported. The optimized coding sequence for mature MMLV-RT was cloned into pET28a and over-expressed as an N-terminal His6-tagged fusion protein. An enterokinase (EK) recognition site was introduced between the His6-tag and MMLV-RT to release tag-free enzyme. Optimal expression of soluble His6-MMLV-RT was achieved by chaperone co-expression and lower temperature fermentation. The His6-tagged enzyme was first purified by Ni²⁺ affinity chromatography. The bound enzyme was then eluted by EK digestion and the eluate was purified on an anion-exchange Q column to remove DNA and EK. Twenty-one milligram MMLV-RT was obtained from 1 l of bacterial culture.     

Influence of the amino acid residue downstream of (Asp)4Lys on enterokinase cleavage of a fusion protein

We have studied the cleavage efficiency of the protease enterokinase (EK) using the novel vector pESP4. pESP4 is a yeast expression vector equipped with ligation-independent cloning sites, a GST purification tag, and a FLAG epitope tag. EK is used to cleave the FLAG and GST tags leaving the protein of interest without any extraneously added amino acids. We have found that EK is relatively permissive of the amino acid residue downstream of the recognition sequence (the P'1 position). This makes EK an ideal choice to use as a protease to cleave any protein of interest cloned within the pESP4 yeast expression vector.     

Functional expression and purification of bovine enterokinase light chain in recombinant Escherichia coli

Enterokinase (EC 3.4.21.9) is a serine proteinase of the intestinal brush border that exhibits specificity for the sequence (Asp)(4)-Lys and converts trypsinogen into its active form, trypsin. A codon optimized sequence coding light chain (catalytic subunit) of bovine enterokinase gene (sBEKLC) was synthesized, and it was fused with DsbA to construct the expression vector (pET39-sBEKLC). Then, the plasmid was transformed into E. coli BL21 (DE3) for expression. Under optimal conditions, the volumetric productivity of fusion protein reached 151.2 mg L(-1), i.e., 80.6 mg sBEKLC L(-1). The cold osmotic shock technique was successfully used to extract sBEKLC from periplasmic space, and nickel affinity chromatography was employed to obtain mature sBEKLC. Finally, about 6.8 mg of bioactive sBEKLC was purified from 1 liter fermentation broth and could be used to cleave one tested fusion protein with an inter-domain enteropeptidase recognition site. This work will be helpful for large-scale production of this increasingly demanded enterokinase.     

Purification and characterization of a recombinant rat prohaptoglobin expressed in baculovirus-infected Sf9 insect cells

To generate hemoglobin-free full-length haptoglobin the cDNA encoding rat haptoglobin alphabeta subunits was cloned into shuttle vector pVT-Bac-His and used to produce a recombinant baculovirus Autographa californica Nuclear Polyhedrosis Virus (AcNPV) as an expression vector, named HpAcNPV. Recombinant virus was used to infect Spodoptera frugiperda (Sf9) insect cells. The 50 kDa protein expressed was mostly secreted into the culture medium at relatively high titer (15 microg/mL) and was found to be rat prohaptoglobin having a vector-derived N-terminal extension of 37 amino acids, containing both a hexahistidine tag and an enterokinase recognition sequence. The protein was successfully purified by a three step procedure including nickel-linked agarose and DEAE-Sepharose chromatography steps. Hemoglobin was not detected in the purified preparations. Purified recombinant rat prohaptoglobin protein was also found to be glycosylated, and to be capable of forming a complex with rat hemoglobin in vitro.     

Sequence analysis of the catalytic subunit of H(+)-ATPase from porcine renal brush-border membranes.

The catalytic subunit of the H(+)-ATPase from brush-border membranes of porcine renal proximal tubules was labeled with the hydrophobic SH-group reagent 10-N-(bromoacetyl)amino-1-decyl-beta-glucopyranoside (BADG) which irreversibly inhibits proton pump activity in the absence but not in the presence of ATP. The labeled protein was purified and digested with proteinases. After isolation and sequencing of proteolytic peptides two BADG-labeled cysteines were identified. The amino acid sequences of the obtained proteolytic peptides were homologous to the catalytic subunit of V-ATPases. From mRNA of porcine kidney cortex a catalytic H(+)-ATPase subunit was cloned. 181 of the 183 amino acids which overlap in the sequence derived from the cDNA and the proteolytic peptides were identical, and the two deviations are due to single base exchanges. A comparison of the amino acid sequence derived from the cloned cDNA with sequences of catalytic H(+)-ATPase subunits communicated by other laboratories revealed 98%, 96% and 94% identity with sequences from bovine adrenal medulla, from bovine kidney medulla and from clathrin-coated vesicles of bovine brain. Between 64% and 69% identity was obtained with sequences from fungi and plants. The data show that the catalytic subunit of V-ATPases is highly conserved during evolution. They indicate organ and species specificity in mammalians.     

Preparation of recombinant thioredoxin fused N-terminal proCNP: Analysis of enterokinase cleavage products reveals new enterokinase cleavage sites

C-type natriuretic peptide (CNP) acts as a paracrine hormone to dilate blood vessels and is also required for the growth of long bones. In vivo, CNP is produced by cleavage from the C-terminal end of a larger proCNP peptide. The remaining N-terminal proCNP fragment (NT-proCNP) escapes into the circulation where its concentration is much higher than that of CNP due presumably to a lower clearance rate. Our strategy to obtain large quantities of pure NT-proCNP for further physiological investigations was to express it as a fusion protein with His(6)-tagged thioredoxin followed by cleavage using enterokinase to yield NT-proCNP alone. We have successfully designed and artificially synthesized the coding sequence specifying both mouse and human NT-proCNP with built-in codon bias towards Escherichia coli codon preference. An enterokinase recognition sequence was incorporated immediately upstream of the NT-proCNP coding sequence to allow the fusion protein to be cleaved without leaving any extra residues on the NT-proCNP peptide. High levels of fusion proteins were obtained, constituting 50-58% of total bacterial proteins. Greater than 90% of recombinant thioredoxin/NT-proCNP was expressed in the soluble form and purified to near homogeneity in a single chromatographic step using nickel as the metal ion in IMAC. A time course analysis of the products released from enterokinase cleavage of the recombinant proteins by ESI-MS revealed three sensitive secondary cleavage sites: two were located on vector-associated sequences linking the thioredoxin moiety and NT-proCNP, and one at the C-terminal end of NT-proCNP. Clearly, substrate specificity of both the native and recombinant forms of enterokinase for the recognition sequence DDDDK was by no means exclusive. Hydrolysis at the unexpected LKGDR site located towards the carboxyl end on NT-proCNP was significantly more efficient than at the internally sited DDDDK target sequence. However, when this same sequence was sited internally replacing the DDDDK in another construct of thioredoxin/mouse NT-proCNP, it was found to be poorly processed by enterokinase. Our results showed that non-target sequences can be preferentially recognized over the canonical DDDDK sequence when located accessibly at the ends of proteins.     

De novo purine nucleotide biosynthesis: cloning, sequencing and expression of a chicken PurH cDNA encoding 5-aminoimidazole-4-carboxamide-ribonucleotide transformylase-IMP cyclohydrolase

The purH cDNA, encoding 5-aminoimidazole-4-carboxamide-ribonucleotide (AICAR) transformylase-inosine monophosphate cyclohydrolase (ATIC), was cloned by functional complementation of an Escherichia coli purH mutant using a chicken liver cDNA expression library. This represents the first report of the cloning of any eukaryotic ATIC-encoding cDNA (PurH). The avian ATIC mRNA is 2.3 kb long and encodes a protein with an Mr of 64,422. The deduced amino acid sequence is 36% identical to the bacterial purH-encoded enzymes from Bacillus subtilis and E. coli. The avian cDNA was expressed as a glutathione S-transferase (GST) fusion protein that was purified in a single step by affinity chromatography. A novel vector was employed which permits rapid and highly efficient cleavage of the GST fusion protein yielding 10 mg of purified PurH product per liter of bacterial culture. Km values were determined with the purified fusion protein utilizing AICAR and (6-R)N10-formyl-tetrahydrofolate as substrates. These values compare favorably with the isolated avian enzyme, supporting the idea that kinetic, as well as other physical properties of the recombinant fusion protein are similar to the native avian enzyme. Large quantities of purified enzyme and the ability to generate site-directed mutations should make mechanistic studies possible. The recombinant enzyme also affords a simple and reliable approach to identifying new antifolates.     

Efficient preparation of an acyclic permutant of kalata B1 from a recombinant fusion protein with thioredoxin

A new approach to prepare an acyclic permutant of kalata B1, a cysteine-rich plant cyclopeptide with uterotonic activity, is described. The synthetic codon-optimized cDNA sequence encoding this 29-residue peptide was cloned and fused in-frame to the His₆-tagged thioredoxin gene in the bacterial expression vector pET-32a. The fusion protein was overexpressed in the bacterial host, Escherichia coli strain BL21 (DE3), and isolated by affinity chromatography on a metal-chelating Sepharose column. An enterokinase recognition sequence incorporated immediately upstream of the target peptide allowed the 29-residue peptide to be released without any unwanted residues upon treatment with enterokinase. This peptide was subsequently separated from the larger thioredoxin moiety by ultracentrifugation through a semipermeable membrane. Further purification was achieved using reversed-phase HPLC. Hydrogen peroxide was found to enhance the rate of enterokinase cleavage in a concentration-dependent manner. Thermal stability studies demonstrated that the recombinant acyclic kalata B1 (ac kalata) was exceptionally stable against thermal denaturation. Mass spectrometric analysis revealed that the recombinant ac kalata was obtained in a fully oxidized form, indicating a high reducing potential and a strong tendency of the 29-residue peptide to form a tightly folded structure.     

Expression and purification of a recombinant antibacterial peptide, cecropin, from Escherichia coli

Insect cecropins are small basic polypeptides synthesized in fat body and hemocytes in response to bacterial infections or hypodermic injuries. To explore a new approach for high expression of soluble cecropin in Escherichia coli cells, we fused the sequence encoding Musca domestica mature cecropin (named Mdmcec) in-frame to thioredoxin (TRX) gene to construct an expression vector pTRX-6His-Mdmcec. An enterokinase cleavage site was introduced between the 6xHis-tag and Mdmcec to facilitate final release of the recombinant Mdmcec. The fusion protein TRX-6His-Mdmcec was purified successfully by HisTrap HP affinity column and a high yield of 48.0mg purified fusion protein was obtained from 1L culture. Recombinant Mdmcec was readily obtained by enterokinase cleavage of the fusion protein followed by HPLC chromatography, and 11.2mg pure active recombinant Mdmcec was obtained from 1L E. coli culture. The molecular mass of recombinant Mdmcec determined by electrospray ionization-mass spectrometry (ESI-MS) is identical to that of native cecropin. Analysis of recombinant Mdmcec by circular dichroism (CD) indicated that recombinant Mdmcec contained predominantly alpha-helix with some random coil. Antimicrobial activity assays demonstrated that recombinant Mdmcec had a broad spectrum of activity against fungi, Gram-positive and negative bacteria. The procedure described in this study will provide a reliable and simple method for production of different cationic peptides for biological studies.     

Strategy for improvement of enteropeptidase efficiency in tag removal processes

Enteropeptidase (synonym: enterokinase, EC 3.4.21.9) is a heterodimeric serine protease of the intestinal brush border that activates trypsinogen by highly specific cleavage of the trypsinogen activation peptide following the sequence (Asp)(4)-Lys. It has also great biotechnological interest because of the unique substrate specificity of the serine protease domain. The high degree of specificity exhibited by enteropeptidase makes it a suitable reagent for cleaving recombinant proteins to remove affinity or other tags. However often unwanted cleavages elsewhere in the protein occurred during cleavage of fusions when high amount of enzyme is required. In this study we have improved the efficiency of fusion proteins cleavage by enteropeptidase by substitution of the Lys residue by Arg in specific cleavage sequence (Asp)(4)-Lys. We have demonstrated that 3-6-fold lower amounts of the catalytic subunit of human and bovine enteropeptidase is required for 95% cleavage of Trx/TRAIL and Trx/FGF-2 fusions with (Asp)(4)-Arg cleavage sequence in comparison to native sequence (Asp)(4)-Lys. As a result, reduced amount of non-specifically cleaved peptide fragments were observed during cleavage of (Asp)(4)-Lys/Arg mutated fusions. These findings overcome limitations of enteropeptidase in tag removal processes during recombinant proteins purification and extend its commercial benefit in the biopharmaceutical industry.     

Expression, purification and characterization of human urodilatin in E. coli

Urodilatin is a 32-amino acid peptide hormone synthesized in kidney to regulate natriuresis and diuresis. It has been shown clinically useful for the treatment of acute decompensated heart failure. A synthetic deoxyoligonucleotide encoding urodilatin was cloned into a pET32a vector immediately after the thioredoxin encoding sequence with a hexa-hisditine tag and an enterokinase recognition site incorporated in between. The fusion protein was overexpressed in Escherichia coli, which constituted 28% of the total cell proteins. More than 85% of Trx-urodilatin was soluble and purified nearly homogenous by Ni-Sepharose affinity chromatography. Urodilatin was then released from the fusion protein by the enterokinase treatment and separated from the fusion partner by the subtractive chromatography using Ni-Sepharose once again. The urodilatin sample was further purified with reverse phase HPLC. Via a biological activity assayed in vitro, it was found that urodilatin had a potent vasodilatory effect on rabbit aortic strips with an EC50 of (2.02+/-0.36)x10(-6)mg/ml, which was similar to that of the synthetic urodilatin standard. The method described here promises to produce about 4.5mg fully active recombinant urodilatin with homogeneity over 97% from one liter shaking flask culture of E. coli.     

Expression of cDNA for batroxobin, a thrombin-like snake venom enzyme

The cloned cDNA for batroxobin has been expressed in E. coli. Batroxobin could only be obtained as intracellular aggregates of fusion proteins, fused with a small peptide. To obtain the mature batroxobin, the recognition sequence for thrombin was inserted between the peptide and the mature batroxobin. This fusion protein accumulated in an insoluble form and could easily be purified. After site-specific cleavage of the fusion protein with thrombin, recombinant batroxobin was isolated by preparative electrophoresis. Batroxobin with enzymatic activity was obtained by the refolding of recombinant batroxobin.