Cell-free synthesis of the hirudin variant 1 of the blood-sucking leech Hirudo medicinalis.

Synthesis and purification of peptide drugs for medical applications is a challenging task. The leech-derived factor hirudin is in clinical use as an alternative to heparin in anticoagulatory therapies. So far, recombinant hirudin is mainly produced in bacterial or yeast expression systems. We describe the successful development and application of an alternative protocol for the synthesis of active hirudin based on a cell-free protein synthesis approach. Three different cell lysates were compared, and the effects of two different signal peptide sequences on the synthesis of mature hirudin were determined. The combination of K562 cell lysates and the endogenous wild-type signal peptide sequence was most effective. Cell-free synthesized hirudin showed a considerably higher anti-thrombin activity compared to recombinant hirudin produced in bacterial cells.

Hirudin and Decorsins of the North American Medicinal Leech Macrobdella decora: Gene Structure Reveals Homology to Hirudins and Hirudin-like Factors of Eurasian Medicinal Leeches.

Blood-sucking leeches, some of which are referred to as medicinal leeches, have caught attention not only because of their medical purposes, but also as study organisms to conduct research within fields as diverse as neurobiology, osmoregulation, ecology, and phylogeny. Of particular interest is the question whether hemophagy in leeches is of single origin or evolved independently several times. A key component in the saliva of hematophagous leeches is hirudin, a strong natural inhibitor of thrombin and hence the blood coagulation cascade. Multiple isoforms of hirudin have been described within and among several leech species and genera, often based on sequence data only. The identification of hirudin-like factors (HLFs) illustrated the necessity to underpin such predictions by functional tests. We overexpressed and purified the hirudin of the North American medicinal leech, Macrobdella decora, and proved its thrombin-inhibiting activity. In addition, analysis of the gene structure of both hirudin and some of the decorsins of M. decora clearly indicated conserved exon and intron positions when compared to genes of hirudins and HLFs of Eurasian medicinal leeches. Our data provide evidence for the incorporation of decorsins into the hirudin superfamily and support the concept of a single origin of blood feeding in jawed leeches.

A factor XIa-activatable hirudin-albumin fusion protein reduces thrombosis in mice without promoting blood loss.

BACKGROUND: Hirudin is a potent thrombin inhibitor but its antithrombotic properties are offset by bleeding side-effects. Because hirudin's N-terminus must engage thrombin's active site for effective inhibition, fusing a cleavable peptide at this site may improve hirudin's risk/benefit ratio as a therapeutic agent. Previously we engineered a plasmin cleavage site (C) between human serum albumin (HSA) and hirudin variant 3 (HV3) in fusion protein HSACHV3. Because coagulation factor XI (FXI) is more involved in thrombosis than hemostasis, we hypothesized that making HV3 activity FXIa-dependent would also improve HV3's potential therapeutic profile. We combined albumin fusion for half-life extension of hirudin with positioning of an FXIa cleavage site N-terminal to HV3, and assessed in vitro and in vivo properties of this novel protein. RESULTS: FXIa cleavage site EPR was employed. Fusion protein EPR-HV3HSA but not HSAEPR-HV3 was activated by FXIa in vitro. FVIIa, FXa, FXIIa, or plasmin failed to activate EPR-HV3HSA. FXIa-cleavable EPR-HV3HSA reduced the time to occlusion of ferric chloride-treated murine arteries and reduced fibrin deposition in murine endotoxemia; noncleavable mycHV3HSA was without effect. EPR-HV3HSA elicited less blood loss than constitutively active HV3HSA in murine liver laceration or tail transection but extended bleeding time to the same extent. EPR-HV3HSA was partially activated in citrated human or murine plasma to a greater extent than HSACHV3. CONCLUSIONS: Releasing the N-terminal block to HV3 activity using FXIa was an effective way to limit hirudin's bleeding side-effects, but plasma instability of the exposed EPR blocking peptide rendered it less useful than previously described plasmin-activatable HSACHV3.

Evaluation of a multifunctional staphylokinase variant with thrombin inhibition and antiplatelet aggregation activities produced from salt-inducible E. coli GJ1158.

Reocclusion is one of the major root causes for secondary complications that arise during thrombolytic therapy. A multifunctional staphylokinase variant SRH (staphylokinase (SAK) linked with tripeptide RGD and didecapeptide Hirulog) with antiplatelet and antithrombin activities in addition to clot specific thrombolytic function, was developed to address the reocclusion problem. We preferred to use Escherichia coli GJ1158 as the host in this study for economic production of SRH by osmotic (0.3 mol/L sodium chloride) induction, to overcome the problems associated with the yeast expression system. The therapeutic potential of SRH was evaluated in the murine model of vascular thrombosis. The SAK protein (1 mg/kg body mass) and SRH protein (1 mg/kg and 2 mg/kg) were administered intravenously to the different treatment groups. The results have shown a dose-dependent antithrombotic effect in carrageenan-induced mouse tail thrombosis. The thrombin time, activated partial thromboplastin time, and prothrombin time were significantly prolonged (p < 0.05) in the SRH-infused groups. Moreover, SRH inhibited platelet aggregation in a dose-dependent manner (p < 0.05), while the bleeding time was significantly (p < 0.05) prolonged. All of these results inferred that the osmotically produced multifunctional fusion protein SRH (SAK-RGD-Hirulog) is a promising thrombolytic agent, and one which sustained its multifunctionality in the animal models.

Production and characterization of hirudin variant-1 by SUMO fusion technology in E. coli.

Hirudin is the most potent non-covalent inhibitor of thrombin. Several expression systems have been used to produce recombinant hirudin for pharmaceutical purposes. However, high expression of active hirudin in Escherichia coli cytoplasm has not been successful owing to the fact that heterogenetic small peptide is easily degraded in the cell. To solve this problem, we constructed a recombinant form of the hirudin variant-1 (HV1) as a fusion protein with the small ubiquitin-related modifier gene (SUMO) by use of over-lap PCR. The fusion gene His(6)-SUMO-HV1 was highly expressed in E. coli BL21 (DE3) in which the SUMO-HV1 accounts for over 30% of the soluble fraction. The fusion protein was purified by Ni-NTA affinity chromatography and cleaved by a SUMO-specific protease Ulp1 to release the HV1 with natural N-terminal. The recombinant HV1 (rHV1) was further purified by Ni-NTA affinity chromatography and then by Q anion-exchange chromatography. N-terminal sequencing result demonstrated the purified rHV1 had the same N-terminal sequence as the native hirudin. MALDI-TOF/MS analysis indicated that the molecular weight of the purified rHV1 protein was 6939.161 Da, which was similar to the theoretical molecular weight of rHV1 6,944 Da. The Chromozym TH assay result showed that the anti-thrombin activity of purified rHV1 was 8,800 ATU/mg and comparable to the specific activity of native hirudin.

Robust preparative-scale extracellular production of hirudin in Escherichia coli and its purification and characterization.

Hirudin variant III (HV3) is potentially useful in the prevention and treatment of cataracts. To prepare sufficient amounts of rHV3 for further preclinical studies, we developed an effective process for robust preparative-scale extracellular production of rHV3 in Escherichia coli. In a 7-l bioreactor, under the optimal fed-batch fermentation conditions, rHV3 was excreted into the culture supernatant and yielded up to 915 mg l(-1). Then, a four-step purification procedure was applied to the product, which included ultrafiltration, hydrophobic chromatography, anion-exchange chromatography, and preparative reversed-phase fast protein liquid chromatography (FPLC). The overall maximum recovery attained was 56 %, the purity reached at least 99 % as evaluated by HPLC analysis, the molecular weight was determined to be 7,011.10 Da by matrix-assisted laser-desorption time-of-flight mass spectrometry (MALDI-TOF/MS) analysis, and the pI was 4.46 as analyzed by isoelectric focusing. The N- and C-terminal sequence analysis confirmed the product homogeneity. The final product contained at most 10 pg of residual DNA per dose (0.2 mg) of rHV3 by high-sensitivity hybridization assay and at most 3 EU endotoxin protein/mg by limulus amebocyte lysate assay. Taken together, the rHV3 produced in multigram quantities in E. coli by this bioprocess meets the regulatory criteria for biopharmaceuticals and can be used as a drug candidate for preclinical studies.

[Biotechnological production of recombinant analogs of hirudin-1 from Hirudo medicinalis].

Hirudin-1 is a highly selective inhibitor of thrombin secreted by salivary glands of the medicinal leech Hirudo medicinalis. This direct anticoagulant is used for the treatment and prevention of disorders in blood coagulation system. Apart from the existing recombinant analog of hirudin-1 (63-desulfatohirudin-1, desirudin) its modified analogs possessing higher activity and stability are of medical value. In this study artificial genes of hirudin and two its analogs (hirudin-1, [Leu1, Thr2]-hirudin-1 and [Leu1, Thr2]-hirudin-1/3) were synthesized and cloned in an expression vector pTWIN1 in frame with the gene of mini-intein SspDnaB from Synechocystis sp. Producing strains of the corresponding fusion proteins were constructed using E. coli strain ER2566. Biotechnological schemes for the production of 63-desulfatohirudin-1 and its analogs were developed. The scheme includes the following stages: isolation of the fusion protein after the desintegration of the cell biomass, refolding of the target peptide within the fusion protein, pH-inducible cleavage of the fusion protein, and chromatographic purification of the target product. Antithrombotic activity of the obtained peptides was determined by a standard amidolytic assay. The developed methods for the production of 63-desulfatohirudin-1, [Leu1, Thr2]-desulfatohirudin-1 [Leu1, Thr2]-desulfatohirudin-1/3 allowed to obtain these peptides with high yields (14, 25 and 24 mg per liter of cell culture respectively) and high activity (13423, 33333 and 19802 ATU/mg respectively).

A novel hirudin derivative characterized with anti-platelet aggregations and thrombin inhibition.

BACKGROUND: Hirudin is an anti-coagulative product of the salivary glands of the medicinal leech Hirudo medicinalis. It is a powerful and specific thrombin inhibitor. Peptides containing the RGD motif competitively inhibit the binding of fibrinogen to GP IIb/IIIa on the platelets, thus inhibiting platelet aggregation. RESULTS: We have constructed a recombinant RGD-hirudin (r-RGD-hirudin) by fusing the tripeptide RGD sequence to the native hirudin (wt-hirudin). The r-RGD-hirudin was expressed at high levels in Pichia pastoris, and was purified to approximately 97% homogeneity. The specific anti-thrombin activity of purified r-RGD-hirudin is 12,000 ATU/mg, which is equivalent to wt-hirudin, but only r-RGD-hirudin can inhibit platelet aggregation. The biological effects of r-RGD-hirudin on Thrombin Time (TT), Prothrombin Time (PT), Activated Partial Thromboplastin Time (APTT), Bleeding Time (BT), maximum platelet aggregation (PAGm) induced by ADP were studied in rabbit model and compared with that of wt-hirudin. The rabbits were infused r-RGD-hirudin had prolonged TT, PT, and aPTT which were similar to that of wt-hirudin; but only r-RGD-hirudin was capable of inhibiting PAGm. Histopathological analyses showed that r-RGD-hirudin was two to three times more effective than wt-hirudin in preventing thrombosis. CONCLUSIONS: r-RGD-hirudin can potentially be used as a novel anti-coagulant for the prevention of thrombosis after carotid artery anastomosis or in other thrombotic events.

Expression of recombinant anticoagulant hirudin in the differentiated cultures of the porcine mammary epithelial cell line SI-PMEC.

To express recombinant proteins in the spontaneously immortalized porcine mammary epithelial cell line (SI-PMEC) currently established in our laboratory, a chemically synthesized DNA fragment encoding the anticoagulant hirudin was used to construct a mammalian expression vector under the control of the goat beta-casein regulatory sequence. The vector, named pGB562/Hi, was transfected into the SI-PMEC cells to yield pGB562/Hi/SI-PMEC. The pGB562/Hi/SI-PMEC cells expressed recombinant hirudin only when they were differentiated into functional structures by growth on a Matrigel-coated petri dish supplemented with the lactogenic hormone prolactin. The differentiated pGB562/Hi/SI-PMEC cells produced about 0.5-0.6microg of recombinant hirudin/mg of total cellular protein. These results suggest that the established SI-PMEC cells have pharmaceutical potential to inducibly express bioactive heterogeneous proteins.

Two characteristics of a recombinant fusion protein composed of staphylokinase and hirudin: high thrombus affinity and thrombus-targeting release ofanticoagulant activity.

To improve thrombolytic effect, a fusion protein SFH composed of staphylokinase (SAK) and hirudin (HV) with blood coagulation factor Xa (FXa) recognition peptide as a linker, was designed. SFH showed improved thrombolytic effect and low bleeding in vivo. Two thrombus-targeting mechanisms might account for the above features of SFH. This study was designed to study the two thrombus-targeting mechanisms of SFH. ELISA and immunohistochemistry assay were used to study the improved thrombus selectivity of SFH and the results showed that SFH, compared with SAK, displayed higher affinity for thrombin and thrombin-rich thrombus. To verify the thrombus-targeting release of anticoagulant activity of SFH, FH-a derivative of HV with only FXa recognition sequence at N terminus of HV was designed and used in animal tests. In inferior vena cava thrombosis model, FH showed equal antithrombotic effect as HV, indicating that HV could be successfully released from FH by FXa cleavage in vivo. More importantly, no prolongation of plasma TT, APTT and PT were found in FH group, but significant prolongations were discovered in HV group. This revealed that the anticoagulant activity of FH was released in thrombus-targeting way and limited in the vicinity of the thrombus, and this could be extrapolated to SFH. In conclusion, the high thrombus affinity and thrombus-targeting release of anticoagulant activity of SFH assigned low bleeding risk to SFH.

[Research progress in hirudin fusion protein--review].

Natural hirudin extracted from the secretion of medical leech salivary gland is a single-chain peptide containing 65 aminoacid residues with molecular weight of 7000 D, and exists in three isomers of HV1, HV2 and HV3. Hirudin possesses three disulfide bridges forming the structure of core cyclic peptides, which binds to the catalytic site of thrombin so as to inhibit the catalysis of thrombin. Its c-terminus rich in acidic aminoacid residues possesses hydrophilicity, and is free on the molecular surface, and can bind with fibrin recognition site of hirudin. The minimal segment of 12 - 16 C-terminal acidic residues keeps the minimal activity of anti-thrombosis. Thus, hirudin, as a potent and specific inhibitor of thrombin, can be used to protect from and to treat clinically thrombosis. As it has some disadvantages such as short half-life, bleeding side-effect and mono-function, and so on, hirudin has been fused with some other functional proteins in recent years. The obtained fusion proteins can prolong the half life of hirudin, or relieve it bleeding side effect, or bring new functions, such as thrombolysis, inhibiting the platelet aggregation, targeting specifically. The research progress in hirudin fusion protein was summarized in this review.

Recombinant expression of selectively sulfated proteins in Escherichia coli.

Although tyrosine sulfation is a post-translational modification widespread across multicellular eukaryotes, its biological functions remain largely unknown. This is in part due to the difficulties of synthesizing selectively sulfated proteins. Here we report the selective incorporation of sulfotyrosine into proteins in bacteria by genetically encoding the modified amino acid in response to the amber nonsense codon TAG. Moreover, we show that this strategy enables direct expression in Escherichia coli of sulfo-hirudin, previously inaccessible through recombinant methods. The affinity of sulfo-hirudin toward human thrombin is enhanced more than tenfold over that of desulfo-hirudin, suggesting that sulfo-hirudin may offer clinical advantages for use as an anticoagulant. This general approach to the biosynthesis of sulfated proteins should facilitate further study and application of tyrosine sulfation.

Improvement of cell viability and hirudin production by ascorbic acid in Pichia pastoris fermentation.

In recombinant Pichia pastoris fermentation for hirudin production, copious cells were not viable and most of the secreted hirudin molecules were C-terminally truncated at the end of fermentation. In this work, the influences of reactive oxygen species (ROS) on cell viability and hirudin production were subsequently studied. In contrast to the untreated control condition, the addition of ascorbic acid at the methanol fed-batch phase could obviously relieve the damage of intracellular ROS to cell membranes. As a result, the cell viability could be increased to 91% from 74% in control at the end of fermentation and the extracellular proteolysis of hirudin reduced. Intact and total hirudin production, by supplying ascorbic acid, could reach 2.90 and 5.03 g/l, respectively, in contrast to 1.75 and 4.70 g/l at the control condition. Ascorbic acid, 4 mmol/l or more, in the fermentation broth increased markedly the production of the intact hirudin, despite a little effect on total hirudin production.

[Construction and expression of a fusion protein made of tissue-type plasminogen activator and hirudin in Pichia pastoris].

To combine the fibrinolytic with anticoagulant activities for therapy of thrombotic deseases, a fusion protein made of tissue-type plasminogen activator (t-PA) and hirudin was constructed and expressed in chia pastoris. To improve thrombolytic properties of t-PA and reduce bleeding side effect of hirudin, FXa-recognition sequence was introduced between t-PA and hirudin molecules.The anticoagulant activity of hirudin can be target-released through cleavage of FXa at thrombus site. t-PA gene and hirudin gene with FXa-recognition sequence at its 5'-terminal were obtained by RT-PCR and PCR respectively. The fusion protein gene was cloned into plasmid pIC9K and electroporated into the genome of Pichia pastoris GS115. The expression of fusion protein was induced by methanol in shaking flask and secreted into the culture medium. Two forms of the fusion protein, single-chain and double-chain linked by a disulfide bond (due to the cleveage of t-PA at Arg275-Ile276), were obtained. The intact fusion protein retained the fibrinolytic activity but lacked any anticoagulant activity. After cleavage by FXa, the fusion protein liberated intact free hirudin to exert its anticoagulant activity. So, the fusion protein is a bifunctional molecule having good prospect to develop into a new targeted therapeutic agent with reduced bleeding side effect for thrombotic diseases.

Improvement of recombinant hirudin production by controlling NH4+ concentration in Pichia pastoris fermentation.

In recombinant Pichia pastoris fermentation for hirudin production in a 5 l fermenter, a new strategy was explored to match the short fermentation time at low NH4+ concentration with decreased hirudin degradation at high NH4+ concentration. A combination of a defined medium containing initial 0.025 m NH4+ with NH4+ addition up to 0.6 m in the growth phase was achieved in both the improvement of hirudin production and the repression of hirudin degradation. Intact and total hirudin reached 2.63 g l(-1) and 4.25 g l(-1), respectively.

Production of antithrombotic hirudin in GAL1-disrupted Saccharomyces cerevisiae.

A gratuitous strain was developed by disrupting the GAL1 gene (galactokinase) of recombinant Saccharomyces cerevisiae harboring the antithrombotic hirudin gene in the chromosome under the control of the GAL10 promoter. A series of glucose-limited fed-batch cultures were carried out to examine the effects of glucose supply on hirudin expression in the gratuitous strain. Controlled feeding of glucose successfully supported both cell growth and hirudin expression in the gratuitous strain. The optimum fed-batch culture done by feeding glucose at a rate of 0.3 g h(-1) produced a maximum hirudin concentration of 62.1 mg l(-1), which corresponded to a 4.5-fold increase when compared with a simple batch culture done with the same strain.

[Fermentation, purification and identification of recombinant RGD-Hirudin].

Recombinant RGD-Hirudin ( r-RGD-Hirudin ) has double functions: anti-thrombin activity and anti-platelet aggregation activity. To identify these functions, the expression plasmid, RGD-Hirudin-pPIC9K, was constructed by inserting cDNA of RGD-hirudin in yeast expression vector pPIC9K. The high expression clone was gained after screening. This clone was fermented for 3 days. The r-RGD-hirudin was secreted into the culture. It was ultra-filtrated from culture supernatant, then after gel filtration chromatography and anion exchange chromatography, the purified r-RGD-hirudin was gained. Its purity was larger than 97% and its specific activity was 12 000 ATU/mg. The yield per liter culture of purified r-RGD-hirudin was 1 g and overall recovery yield was more than 75% . The purified r-RGD-hirudin was identified by reductive SDS-PAGE, anti-thrombin activity assay, anti-platelet aggregation assay, LC/MS and isoelectrofocusing assay. It is proved that r-RGD-Hirudin is ramification of wt-Hirudin and it has anti-thrombin activity and anti-platelet aggregation activity.

Finding of an isoleucine derivative of a recombinant protein for pharmaceutical use.

Protein modification generally occurs by addition to the amino acid side-chains of protein at the post-translational stage, for example, by enzymatic or chemical reactions after polypeptide synthesis. Recently, the recombinant hirudin analog CX-397, a potent thrombin inhibitor, was found to contain methylated Ile residues when it was overproduced by Escherichia coli in the absence of amino acids in the culture medium. The Ile derivatives, deduced to be beta-methylnorleucine [betaMeNle; (2S, 3S)-2-amino-3-methylhexanoic acid] by systematic chromatographic analysis, do not appear to be normal post-translational modifications of the protein because Ile has no functional group in its side-chain. We, therefore, propose that betaMeNle is biosynthesized by E. coli, activated by E. coli isoleucyl-tRNA synthetase (IleRS), then incorporated into the overproduced recombinant hirudin analog. The biosynthesis of betaMeNle in E. coli is thought to occur as follows: alpha-ketovalerate is synthesized from alpha-ketobutyrate by three Leu biosynthetic enzymes, alpha-isopropylmalate synthase (IPMS) (EC 4.1.3.12), alpha-isopropylmalate isomerase (ISOM) (EC 4.2.1.33) and beta-isopropylmalate dehydrogenase (IPMD) (EC 1.1.1.85), which have broad substrate specificities. alpha-Ketovalerate is then converted to alpha-keto-beta-methylcaproate by three Ile and Val biosynthetic enzymes, acetohydroxy acid synthase (AS) (EC 4.1.3.18), acetohydroxy acid isomeroreductase (IR) (EC 1.1.1.86) and dihydroxy acid dehydratase (DH) (EC 4.2.1.9). Finally, this is converted to betaMeNle by branched-chain amino acid transaminase (EC 2.6.1.42), one of the Ile and Val biosynthetic enzymes.

Efficient expression and secretion of recombinant hirudin III in E. coli using the L-asparaginase II signal sequence.

One of the hirudin variants HV3 was efficiently expressed in Escherichia coli using the L-asparaginase II signal sequence and the product was secreted into the culture medium. For the secretory manufacture of HV3, the L-asparaginase II signal sequence containing a single NheI restriction site at its 3' end was designed using the degenerate codons and PCR-amplified from E. coli chromosomal DNA. The synthetic HV3 coding sequence was fused to the signal sequence in-frame by its 5' NheI restriction site. The above signal-HV3 fusion gene was inserted into an expression vector pTA, which was derived from pkk223-3 such that its expression was under the control of the tac promotor. The resulting HV3 secretion expression vector pTASH thus constructed was introduced into an E. coli host cell AS1.357 with high L-asparaginase II producing level. After inducing with IPTG, the expression product was efficiently secreted into the culture medium and shake-flask culturing gave a yield of approximately 5 x 10(5)ATU/L (approximately 60mg/L). The secreted HV3 was easily purified from culture supernatant using ultrafiltration, ion-exchange column chromatography, and FPLC reverse-phase chromatography. The purified rHV3 from the culture supernatant had the expected N-terminal amino sequence and strong antithrombin activity, suggesting that the signal sequence was completely removed and the product was processed accurately during the secretion process.