Expression of recombinant kringle 1-5 domains of human plasminogen by a prokaryote expression system

Kringle1-5 (K1-5), a proteolytic fragment containing five kringle domains of human plasminogen generated by plasmin-mediated proteolysis, has been already identified by Cao et al. with relation to anti-angiogenesis and proliferation of endothelial cells. To investigate anti-angiogenesis activity of recombinant human K1-5 (rhK1-5) expressed in Escherichia coli BL21, the cDNA of human K1-5 obtained from cloning vector pUC57-K1-5 by PCR, was inserted into an expression vector pET30(+) to construct a prokaryotic expression vector pET-K1-5. Recombinant K1-5 efficiently expressed in E. coli BL21 after IPTG induction was monitored by SDS-PAGE and Western blotting with an anti-angiostatin monoclonal antibody and an anti-hexahistidine tag antibody. The expressed K1-5 accounted for approximately 32% of the total bacterial proteins as estimated by densitometry, and existed mainly as inclusion bodies. The inclusion bodies were washed, lysed, purified, and refolded to a purity of 96% as estimated by capillary electrophoresis and the final purification yield of K1-5 in E. coli system was approximately 5.8 mg/L. Purified K1-5 protein was tested on chicken embryo chorioallantoic membranes (CAMs), and a large number of newly formed blood vessels were significantly regressed. In the present study, we demonstrated that bacterial-expressed K1-5 effectively inhibited angiogenesis of the chicken embryo in a dose-dependent manner through CAM assay. In addition, the rhK1-5 potently inhibited endothelial cell proliferation but not non-endothelial cells. For the first time, these findings demonstrate that the rhK1-5 produced by a prokaryote expression system effectively inhibited angiogenesis of the chicken embryo in a dose-dependent manner and specially suppressed in vitro the proliferation of human umbilical vein endothelial cells. This fact derived from the present study further suggests the rhK1-5 can be used for anti-angiogenesis therapy of cancer.     

Partial characterization of chitinolytic enzymes from Streptomyces albidoflavus

Streptomyces albidoflavus NRRL B-16746 secreted three types of chitinolytic enzymes: N -acetyl-glucosaminidase, chitobiosidase and endochitinase. Optimal activity for all three types of enzymes occurred at pH 4–6; however 55–74% of the chitobiosidase and endochitinase activity was detectable at pH 8–10. Chitobiosidase activity originated from two strongly acidic (pI < 3.0) proteins with molecular mass of 27 kDa and 34 kDa, while endochitinase activity originated from five major acidic proteins (pI 5.1, 5.3, 5.75, 5.8–5.9 and 6.4) with molecular mass of 59, 45, 38.5, 27 and 25.5 kDa. Purified chitobiosidases significantly reduced spore germination and germ tube elongation of Botrytis cinerea and Fusarium oxysporum. Chitinolytic enzymes with significant activity at pH 4–10 may be used, transgenically, to reduce the growth and/or development of a broad spectrum of insects and fungi that are major economic pests.     

Chitinase B of "Microbulbifer degradans" 2-40 contains two catalytic domains with different chitinolytic activities

Chitinase B of "Microbulbifer degradans" 2-40 is a modular protein that is predicted to contain two glycoside hydrolase family 18 (GH18) catalytic domains, two polyserine domains, and an acidic repeat domain. Each of the GH18 domains was shown to be catalytically active against chitin. Activity assays reveal that the amino-terminal catalytic domain (GH18(N)) releases methylumbelliferone from 4'-methylumbelliferyl-N,N'-diacetylchitobiose 13.6-fold faster than the carboxy-terminal catalytic domain (GH18(C)) and releases chitobiose from the nonreducing end of chitooligosaccharides, therefore functioning as an exochitinase. GH18(C) releases methylumbelliferone from 4'-methylumbelliferyl-N,N',N"-triacetylchitotriose 2.7-fold faster than GH18(N) and cleaves chitooligosaccharides at multiple bonds, consistent with endochitinolytic activity. Each domain was maximally active from 30 to 37 degrees C and from pH 7.2 to 8.0 and was not affected by Mg(2+), Mn(2+), Ca(2+), K(+), EDTA, EGTA, or 1.0 M NaCl. The activity of each domain was moderately inhibited by Ni(2+), Sr(2+), and Cu(2+), while Hg(2+) completely abolished activity. When the specific activities of various recombinant portions of ChiB were calculated by using native chitin as a substrate, the polypeptide containing the endo-acting domain was twofold more active on native chitin than the other containing the exo-acting domain. The presence of both domains in a single reaction increased the amount of reducing sugars released from native chitin to 140% above the theoretical combined rate, indicating that the domains function cooperatively to degrade chitin. These data demonstrate that the GH18 domains of ChiB have different activities on the same substrate and function cooperatively to enhance chitin depolymerization.     

Production of chitinolytic enzymes from a novel species ofAeromonas

A bacterial strain secreting potent chitinolytic activity was isolated from shrimp-pond water by enrichment culture using colloidal crab-shell chitin as the major carbon source. The isolated bacterium, designated asAeromonas sp No. 16 exhibited a rod-like morphology with a polar flagellum. Under optimal culture conditions in 500-ml shaker flasks, it produced a chitinolytic activity of 1.4 U ml^–1. A slightly higher enzymatic activity of 1.5 U ml^–1 was obtained when cultivation was carried out in a 5-liter jar fermentor using a medium containing crystalline chitin as the carbon source. The secretion of the enzyme(s) was stimulated by several organic nitrogenous supplements. Most carbon sources tested (glucose, maltose, N-acetylglucosamine, etc) enhanced cell growth, but they slightly inhibited enzyme secretion. Glucosamine (0.5% w/v) severely inhibited cell growth (16% of the control), but it did not significantly affect enzyme secretion. The production of chitinolytic enzymes was pH sensitive and was enhanced by increasing the concentration of colloidal chitin to 1.5%. The observed chitinolytic activity could be attributed to the presence of -N-acetylglucosaminidase and chitinase. Chitinase was purified by ammonium sulfate fractionation and preparative gel electrophoresis to three major bands on SDS-PAGE. An in-gel enzymatic activity assay indicated that all three bands possessed chitinase activity. Analysis of the enzymatic products indicated that the purified enzyme(s) hydrolyzed colloidal chitin predominantly to N,N-diacetyl-chitobiose and, to a much lesser extent, the mono-, tri, and tetramer of N-acetylglucosamine, suggesting that they are mainly endochitinases.     

Purification and properties of two chitinolytic enzymes of Serratia plymuthica HRO-C48

The chitinolytic rhizobacterium Serratia plymuthica HRO-C48 was previously selected as a biocontrol agent of phytopathogenic fungi. One endochitinase (E.C. 3.2.1.14), CHIT60, and one N-acetyl-beta-1,4- D-hexosaminidase (E.C. 3.2.1.52), CHIT100, were purified and characterized. The endochitinase CHIT60, with an apparent molecular mass of 60.5 kDa, had a N-terminal amino acid sequence highly similar to that of chitinases A from Serratia liquefaciens and Serratia marcescens. The enzyme activity had its peak at 55 degrees C and pH 5.4, and increased by more than 20% in the presence of 10 mM Ca(2+), Co(2+) or Mn(2+). Activity was inhibited by 80% in the presence of 10 mM Cu(2+). CHIT100 appeared to be a monomeric enzyme with a molecular mass of 95.6 kDa and a pI of 6.8. Optimal activity was obtained at 43 degrees C and pH 6.6, and decreased by more than 90 % in the presence of 10 mM Co(2+) or Cu(2+). CHIT100 (100 microg ml(-1)) inhibited spore germination and germ tube elongation of the phytopathogenic fungus Botrytis cinerea by 28 % and 31.6 %, respectively. With CHIT60 (100 microg ml(-1)), the effect was more pronounced: 78 % inhibition of of germination and 63.9 % inhibition of germ tube elongation.     

Optimized conditions for high-level expression and purification of recombinant human interleukin-2 in E. coli

Interleukin-2 (IL-2), a potent cytokine has been used in anti-cancer therapy for over a decade now. IL-2, originally identified as a growth factor for T lymphocytes is a 15 kDa hydrophobic glycoprotein that induces the activation, clonal proliferation and differentiation of T and B-lymphocytes and enhances the cytotoxicity of monocytes and natural killer (NK) cells. Here, we report a simple method for the cloning, high-level expression and purification of IL-2 protein, which can be easily extended to other bioactive therapeutic proteins. The IL-2 gene was amplified from human spleen cDNA and cloned in a prokaryotic (E. coli) expression system. An optimal expression of the IL-2 protein was determined by varying the expression conditions like temperature, inducer concentration and duration of induction. The protein was expressed as inclusion bodies and a panel of reagents including detergents, urea and guanidine hydrochloride were used to solubilize it. After solubilization, the protein was renatured and subjected to a single step gel-filtration chromatography to yield immunobioactive IL-2 protein with > 99% purity.     

Constitutive long-term production and characterization of recombinant human interferon-gammas from two different mammalian cells

Two expression plasmids (pSVIFN gamma/BPV97 and pSVIFN gamma/AdDHFR) for constitutive production of human interferon-gamma (HuIFN-gamma) were constructed and introduced into the two different mammalian cell lines, mouse C127 cells and Chinese hamster ovary (CHO) cells. Genetically engineered C127 and CHO cells grew on microcarriers having high productivity of HuIFN-gammas for at least six months. Isoelectric focusing patterns and molecular weight analyses suggest that C127- and CHO-HuIFN-gammas are glycoproteins and that both HuIFN-gammas have different molecular structures. The development of a microcarrier culture system for genetically engineered mammalian cells has enabled us to prepare glycosylated HuIFN-gammas on a large scale.     

Optimized bioprocess for production of fructofuranosidase by recombinant Aspergillus niger

A comprehensive approach of bioprocess design at various levels was used to optimize microbial production of extracellular fructofuranosidase, important as biocatalyst to derive fructooligosaccharides with broad application in food or pharmaceutical industry. For production, the recombinant strain Aspergillus niger SKAn1015 was used, which expresses the fructofuranosidase encoding gene suc1 under control of a strong constitutive promoter. In a first screening towards an optimized medium, glucose, nitrate, Fe²⁺, and Mn²⁺ were identified as beneficial for production. A minimal medium with optimized concentration of these key nutrients, obtained by central composite design experiments and quadratic modelling, provided a threefold increased fructofuranosidase activity in the culture supernatant (400 U/mL) as compared to the originally described medium. Utilizing the optimized medium, the process was then transferred from shake flask into a fed-batch-operated bioreactor. Hereby, the intended addition of talc microparticles allowed engineering the morphology of A. niger into a highly active mycelial form, which strongly boosted production. Fructofuranosidase production was highly specific as confirmed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis. The secreted enzyme activity of 2,800 U/mL, corresponding to about 3 g/L of fructofuranosidase, achieved by the microparticle-enhanced fed-batch process, is tenfold higher than that of any other process reported so far, so that the presented bioprocess strategy appears as a milestone towards future industrial fructofuranosidase production.     

Chimeric allosteric citrate synthases: construction and properties of citrate synthases containing domains from two different enzymes.

The citrate synthases of the gram-negative bacteria, Escherichia coli and Acinetobacter anitratum, are allosterically inhibited by NADH. The kinetic properties, however, suggest that the equilibrium between active (R) and inactive (T) conformational states is shifted toward the T state in the E. coli enzyme. We have now manipulated the cloned genes for the two bacterial enzymes to produce two chimeric proteins, in which one folding domain of each subunit is derived from each enzyme. One chimera (the large domain from A. anitratum and the small domain from the E. coli enzyme) is designated CS ACI::eco; the other is called CS ECO::aci. Both chimeras are roughly as active as the wild type parents, but their Km values for both substrates are lower than those for the E. coli enzyme, and NADH inhibition is markedly sigmoid, while that for E. coli citrate synthases is hyperbolic. Curve-fitting to the allosteric equation suggests that these differences are the result of the destabilization of the T state in the chimeras. The ACI::eco chimera exists almost entirely as a hexamer, like the A. anitratum enzyme, while the ECO::aci chimera, like the E. coli synthase, forms three major bands on nondenaturing polyacrylamide gels, two of them hexamers of different net charge, and one a dimer. These findings indicate that subunit interactions leading to hexamer formation in allosteric citrate synthases of gram-negative bacteria involve mainly the large domains. The chimeras are also used to show that the NADH binding site of E. coli citrate synthase is located entirely in the large domain. Sensitivity of the chimeras to denaturation by urea, to which the A. anitratum enzyme is much more resistant than the E. coli enzyme, is determined by the large domains. Sensitivity to inactivation by subtilisin is intermediate between those shown by the E. coli (very sensitive) and A. anitratum (quite resistant) synthases. This result suggests that digestibility by subtilisin is determined by conformational factors as well as the amino acid sequences of the target regions.     

Optimized production of recombinant bluetongue core-like particles produced by the baculovirus expression system.

The baculovirus-expression vector system (BEVS) has been widely used for the experimental production of many human and animal single- and multi-unit vaccines, heterologous proteins, and viral insecticides. In this work, the production of recombinant bluetongue virus core-like particles (CLPs), using Sf9 cells in shaker-suspension culture with the SF900 II medium (GIBCO, NY), has been studied. This system involved the simultaneous production of two proteins, VP7 and VP3, and was shown to achieve high volumetric productivities. The key parameters of the time of infection (TOI), and the multiplicity of infection (MOI) were studied. The results show that the peak-volumetric yields and cell-specific yields achieved using low MOIs at low-cell densities were the same as those obtained following infections with a high MOI at high-cell densities. This work establishes the feasibility of using low MOIs in the baculovirus system to produce complex multiprotein particles.     

The rumen: a unique source of enzymes for enhancing livestock production

Increasing competition in the livestock industry has forced producers to cut costs by adopting new technologies aimed at increasing production efficiency. One particularly promising technology is feeding enzymes as supplements for animal diets. Supplementation of diets for non-ruminants (e.g., swine and poultry) with fibrolytic enzymes, such as cellulases, xylanases and beta-glucanases, increases the feed conversion efficiency and growth rate of the animals. Enzymatic hydrolysis of plant cell wall polymers (e.g., cellulose, xylan, beta-glucans) releases glucose and xylose and eliminates the antinutritional effects of beta-glucans and arabinoxylans. Enzyme supplementation of diets for ruminants has also been shown to improve growth performance, even though the rumen itself represents the most potent fibrolytic fermentation system known. Implementation of this technology in the livestock industry has been limited largely because of the cost of development and production of enzymes. Over the last decade, however, developments in recombinant DNA technology have increased the efficiency of existing microbial production systems and facilitated exploitation of alternative sources of industrial enzymes. The ruminal ecosystem is among the novel enzyme sources currently being explored. Understanding the role of enzymes in feed digestion through characterization of the enzymology and genetics involved in digestion of feedstuffs by ruminants will provide insight required to improve the products currently available to producers. Characterization of genes encoding a variety of hydrolytic enzymes, such as cellulases, xylanases, beta-glucanases, amylases, pectinases, proteases, phytases and tannases, will foster the development of more efficacious enzyme supplements and enzyme expression systems for enhancing nutrient utilization by domestic animals. Characteristics of the original source organism need no longer restrict the production of a useful enzyme. Recent reports of transgenic plants expressing fibrolytic or phytase activity and of transgenic mice able to produce endoglucanase in the pancreas speak to the feasibility of improving feed digestion through genetic modification of the feedstuffs and the animals.     

重组大肠杆菌产尿素酶B高密度发酵条件的优化

探究重组大肠杆菌产尿素酶B（urease B subunit, UreB）的高密度发酵条件。通过实验室摇瓶和30 L发酵罐对UreB基因工程菌的发酵条件进行优化。结果表明：30 L发酵罐中以TB培养基为发酵培养基,接种量为5%,发酵温度为37 ℃,pH为6.8,溶氧量为30%左右,培养至2 h开始恒速流加50%甘油,4 h流加50%酵母提取物和50%胰蛋白胨,并加入终浓度为0.5 mmol/L的异丙基β-D-硫代半乳糖苷（isopropyl β-D-thiogalactoside,IPTG),诱导表达4 h,结束发酵,所得菌体干物质约为25.7 g/L,UreB表达量为31.4%。此工艺可以提高UreB的产量。     

重组大肠杆菌右旋糖酐蔗糖酶的表达条件优化

通过设计正交实验,考察了培养基中各组分及其浓度对右旋糖酐蔗糖酶工程菌Escherichia coli BL21(DE3)/pET28-dexYG诱导产酶结果的影响。在获得最佳培养条件的基础上,考察温度、蔗糖浓度和pH值对右旋糖酐产量的影响。结果表明:菌浓OD600达到2.0时,加入异丙基硫代-β-D-呋喃半乳糖苷(IPTG)至0.25mmol/L,25°C诱导培养4h,产酶活力最高,达到110.16U/mL,蔗糖浓度对产量的影响比较显著。研究结果得到高效表达的培养条件,为实现该酶的工业化应用打下了基础。     

酿酒酵母产油脂条件的优化

微生物细胞通常仅含2%3%油脂,但少数微生物含油脂率却可达70%以上,所以高含油脂量使微生物油脂实际开发成为可能。目前用于生产多不饱和脂肪酸的微生物主要为藻类和真菌。尽管微生物油脂是当前的研究热点,已经引起广大研究者的重视,但目前国内外研究大都集中在含油脂量在干重20%以上的微生物,如浅白色隐性酵母、粘红酵母等,而对于酿酒酵母来说,则很少见到研究其产油脂的相关报道。     

Comparison of chitinolytic enzymes from an alkaline, hypersaline lake and an estuary

We examined the genetic and physiological characteristics of chitin degrading enzymes expressed by fosmids cloned from two strains of chitinolytic gammaproteobacteria isolated from alkaline, hypersaline Mono Lake, California; and from a metagenomic library derived from an estuarine bacterial community (Dean Creek, Sapelo Island, GA, USA). The Mono Lake chitinolytic enzymes presented unique adaptations in terms of halo- and alkalitolerance. The sequence from one of the Mono Lake isolates (strain 12A) was a conventional family 18 glycosyl hydrolase; however, the expressed protein had a novel secondary activity peak at pH 10. We obtained a novel family 20 glycosyl hydrolase sequence from Mono Lake strain AI21. The activity of the expressed protein had a pH optimum of 10, several pH units higher than any other enzyme currently assigned to this family, and the enzyme retained 80% of its activity at pH 11. The enzyme was also halotolerant, retaining activity in salt solutions of up to 225 g l(-1). Sequence analysis indicated a molecular weight of approximately 90 kDa for the protein, and that it contained two active sites. Culture supernatant contained two chitinolytic proteins, 45 and 31 kDa, suggesting possible post-expression modification of the gene product. In contrast, the sequence found in the estuarine metagenomic library and the functional characteristics of the protein expressed from it were those of a conventional family 18 glycosyl hydrolase.     

Optimization of cultural conditions for enhancing the expression of human interferon-α2a by recombinant yeast

When adenine (Ade) was added to basal culture medium at 12 h after inoculation, antivirus activity and specific activity of interferon-α2a (IFN-α2a) were increased. Expression of IFN-α2a was realized when a low residual glucose concentration was maintained during the mid- and late-phase of cultivation. In addition, biological activity and specific activity of IFN-α2a were increased by more than 100% if the ratio of glucose and sucrose in the basal medium was 1:0.1. The addition of glutamate also led to the intensive enhancement of the expression level of IFN-α2a. The initial pH of the basal medium proved to be crucial to the expression level. When the above optimal cultivation condition obtained in the shake flask was applied to the fed-batch culture using a 2.6 l jar fermenter, human IFN-α2a biological activity reached 1.3×10⁷ IU/ml, which was four times that of the control.     

A statistical method for enhancing the production of succinic acid from Escherichia coli under anaerobic conditions

The most influential parameters for succinic acid production obtained through one at a time method were sucrose, tryptone, magnesium carbonate, inoculum size and incubation period. These resulted in the production of 7.0 g L(-1) of succinic acid in 60 h from Escherichia coli W3110 under anaerobic conditions. Based on these results, a statistical method, face centered central composite design (FCCCD) falling under response surface method (RSM) was employed for further enhancing the succinic acid production and to monitor the interactive effect of these parameters, which resulted in a twofold increase in yield (14.3 g L(-1) in 48 h). The analysis of variance (ANOVA) showed the adequacy of the model and the verification experiments confirmed its validity. On subsequent scale-up in a 10-L bioreactor using conditions optimized through RSM, 24.2 g L(-1) of succinic acid was obtained in 30 h. This clearly indicated that the model stood valid even on large-scale. Thus, the statistical optimization strategy led to a 3.5-fold increase in the yield of succinic acid. This is the first report on the use of FCCCD to improve succinic acid production from E. coli.     

Effect of environmental conditions on the production of two extracellular proteolytic enzymes byVibrio SA1

The production of two extracellular proteases, an endopeptidase and an aminopeptidase, by the marine bacteriumVibrio SA1 was studied in batch cultures. The production of the proteases was induced during growth of the organism in peptone media and by several amino acids during growth in minimal media. It was repressed by easily metabolisable carbon compounds such as glucose, lactate and succinate during growth in peptone media. During growth in a lactate basal medium, phenylalanine was one of the best inducers and this amino acid was therefore used in further experiments. That lactate dit not repress the synthesis of the proteases during growth in the lactate basal medium supplemented with 2mm phenylalanine as an inducer, appeared to be a consequence of the low iron content of this medium. Growth curves ofVibrio SA1 on such media showed a period of linear growth during which protease production was observed. When the iron concentration was made sufficiently high to prevent linear growth, the synthesis of the proteases remained repressed. Apparently by imposing an iron limitation on the organism, catabolite repression by lactate was relieved. Similarly, when growth was limited by very low values of the dissolved oxygen tension in the medium, a high rate of protease synthesis was found which was immediately repressed when the oxygen limitation was released. The results indicate that the growth rate and/or a factor associated with the energy metabolism play a role in the regulation of the synthesis of the enzymes.This study was supported by the Foundation for Fundamental Biological Research (BION), which is subsidised by the Netherlands Organization for the Advancement of Pure Research (ZWO).