Description of a cellulose-binding domain and a linker sequence from Aspergillus fungi

A family I cellulose-binding domain (CBD) and a serine- and threonine-rich linker peptide were cloned from the fungi Aspergillus japonicus and Aspergillus aculeatus. A glutathione S-transferase (GST) fusion protein comprising GST and a peptide linker with the CBD fused to its C-terminus, was expressed in Escherichia coli. The renatured GST-CBD recovered from inclusion bodies had a molecular mass of 36.5 kDa which agrees with the 29 kDa of the GST plus the calculated 7.5 kDa of the linker with the CBD. The isolated GST-CBD protein adsorbed to both bacterial microcrystalline cellulose and carboxymethyl cellulose. Deletion of the linker peptide caused a decrease in cellulose adsorbance and a higher sensitivity to protease digestion.     

Matrix-assisted refolding of single-chain Fv- cellulose binding domain fusion proteins.

We describe a method for the isolation of recombinant single-chain antibodies in a biologically active form. The single-chain antibodies are fused to a cellulose binding domain as a single-chain protein that accumulates as insoluble inclusion bodies upon expression in Escherichia coli. The inclusion bodies are then solubilized and denatured by an appropriate chaotropic solvent, then reversibly immobilized onto a cellulose matrix via specific interaction of the matrix with the cellulose binding domain (CBD) moiety. The efficient immobilization that minimizes the contact between folding protein molecules, thus preventing their aggregation, is facilitated by the robustness of the Clostridium thermocellum CBD we use. This CBD is unique in retaining its specific cellulose binding capability when solubilized in up to 6 M urea, while the proteins fused to it are fully denatured. Refolding of the fusion proteins is induced by reducing with time the concentration of the denaturing solvent while in contact with the cellulose matrix. The refolded single-chain antibodies in their native state are then recovered by releasing them from the cellulose matrix in high yield of 60% or better, which is threefold or higher than the yield obtained by using published refolding protocols to recover the same scFvs. The described method should have general applicability for the production of many protein-CBD fusions in which the fusion partner is insoluble upon expression.     

Hexasaccharides from the histamine-modified depolymerization of porcine intestinal mucosal heparin

Specific sequences in heparin are responsible for its modulation of the biological activity of proteins. As part of a program to characterize heparin-peptide and heparin-protein binding, we are studying the interaction of chemically discrete heparin-derived oligosaccharides with peptides and proteins. We report here the isolation and characterization, by one- and two-dimensional 1H NMR spectroscopies, of ten hexasaccharides, one pentasaccharide, and one octasaccharide serine that were isolated from depolymerized porcine intestinal mucosal heparin. Hexasaccharides were chosen for study because they fall within the size range, typically tetra- to decasaccharide in length, of heparin sequences that modulate the activity of proteins. The depolymerization reaction was catalyzed by heparinase I (EC 4.2.2.7) in the presence of histamine, which binds site specifically to heparin. Histamine increases both the rate and extent of heparinase I-catalyzed depolymerization of heparin. It is proposed that oligosaccharides produced by heparinase I-catalyzed depolymerization can inhibit the enzyme by binding to the imidazolium group of histidine-203, which together with cysteine-135 forms the catalytic domain of heparinase I. The increased rate and extent of depolymerization are attributed to competitive binding of the oligosaccharides by histamine.     

Enzyme immobilization using a cellulose-binding domain: properties of a beta-glucosidase fusion protein.

Using molecular genetic techniques, a fusion protein has been produced which contains the cellulose-binding domain (CBD) of an exoglucanase (Cex) from Cellulomonas fimi fused to a beta-glucosidase (Abg) from Agrobacterium sp. The CBD functions as an affinity tag for the simultaneous purification and immobilization of the enzyme on cellulose. Binding to cellulose was stable for prolonged periods at temperatures from 4 degrees C to at least 50 degrees C, at ionic strengths from 10 mM to greater than 1 M, and at pH values below 8. The fusion protein can be desorbed from cellulose with distilled water or at pH greater than 8. Immobilized enzyme columns of the fusion protein bound to cotton fibers exhibited stable beta-glucosidase activity for at least 10 days of continuous operation at temperatures up to 37 degrees C. At higher temperatures, the bound enzyme lost activity. The thermal stability of the fusion protein was greatly improved by immobilization. Immobilization did not alter the pH stability. Except for its ability to bind to cellulose, the properties of the fusion protein were virtually the same as those of the native enzyme.     

Production of mycobacterial antigenes merged with cellulose binding protein domain in order to produce subunit vaccines against tuberculosis

Protein genes Ag85A, Esat-6, and Cfp10 of Mycobacterium tuberculosis were sequenced using the database GenBank to implement selection and synthesis of primer pairs of given genes. PCR was used to obtain target amplicons of the genes. Chromosome DNA of M. tuberculosis H37Rv was used as the DNA amplification matrix. The PCR products were obtained using the plasmid pQE6, cloned, and amplified in the Escherichia coli M15 strain. Chimere products containing mycobacterial genes and cellulose binding protein domain (CBD), were obtained using the plasmid treated with restriction endonucleases. CBD fragment obtained using similar treatment of the ptt10 plasmid. The plasmids containing merged sequences of mycobacterial genes-antigenes and CBD were selected. The 3 mycobacterial genes were expressed in the E. coli M15 cells resulting in biosynthesis of corresponding recombinant proteins of expected molecular weight. Concentration of CBD, Cfp10-CBD, Ag85A-CBD, and ESAT6-CBD was 20%, 15%, and 15% total protein, respectively. The resulting chimere proteins provide high affinity for cellulose and high stability. Immobilization of CBD-containing recombinant proteins proceeds as one-stage process providing target protein purification and adsorption on cellulose. The vaccines produced using this technology are inexpensive because of low cost of cellulose sorbents as well as simultaneous use of cellulose for purification and immobilization of protein. Many cellulose preparations are not toxic, biocompatible, and widely used in medicine.     

Cellulose affinity purification of fusion proteins tagged with fungal family 1 cellulose-binding domain

N- or C-terminal fusions of red-fluorescent protein (RFP) with various fungal cellulose-binding domains (CBDs) belonging to carbohydrate binding module (CBM) family 1 were expressed in a Pichia pastoris expression system, and the resulting fusion proteins were used to examine the feasibility of large-scale affinity purification of CBD-tagged proteins on cellulose columns. We found that RFP fused with CBD from Trichoderma reesei CBHI (CBD(Tr)(CBHI)) was expressed at up to 1.2g/l in the culture filtrate, which could be directly injected into the cellulose column. The fusion protein was tightly adsorbed on the cellulose column in the presence of a sufficient amount of ammonium sulfate and was efficiently eluted with pure water. Bovine serum albumin (BSA) was not captured under these conditions, whereas both BSA and the fusion protein were adsorbed on a phenyl column, indicating that the cellulose column can be used for the purification of not only hydrophilic proteins but also for hydrophobic proteins. Recovery of various fusion proteins exceeded 80%. Our results indicate that protein purification by expression of a target protein as a fusion with a fungal family 1 CBD tag in a yeast expression system, followed by affinity purification on a cellulose column, is simple, effective and easily scalable.     

Specific adhesion to cellulose and hydrolysis of organophosphate nerve agents by a genetically engineered Escherichia coli strain with a surface-expressed cellulose-binding domain and organophosphorus hydrolase

A genetically engineered Escherichia coli cell expressing both organophosphorus hydrolase (OPH) and a cellulose-binding domain (CBD) on the cell surface was constructed, enabling the simultaneous hydrolysis of organophosphate nerve agents and immobilization via specific adsorption to cellulose. OPH was displayed on the cell surface by use of the truncated ice nucleation protein (INPNC) fusion system, while the CBD was surface anchored by the Lpp-OmpA fusion system. Production of both INPNC-OPH and Lpp-OmpA-CBD fusion proteins was verified by immunoblotting, and the surface localization of OPH and the CBD was confirmed by immunofluorescence microscopy. Whole-cell immobilization with the surface-anchored CBD was very specific, forming essentially a monolayer of cells on different supports, as shown by electron micrographs. Optimal levels of OPH activity and binding affinity to cellulose supports were achieved by investigating expression under different induction levels. Immobilized cells degraded paraoxon rapidly at an initial rate of 0.65 mM/min/g of cells (dry weight) and retained almost 100% efficiency over a period of 45 days. Owing to its superior degradation capacity and affinity to cellulose, this immobilized-cell system should be an attractive alternative for large-scale detoxification of organophosphate nerve agents.     

Effects of the PT region of EngD and HLD of CbpA on solubility, catalytic activity and purification characteristics of EngD-CBD(CbpA) fusions from Clostridium cellulovorans

Chimeric proteins combining the catalytic N-terminal region of native EngD with its proline-threonine-threonine (PT) linker region, hydrophilic domain (HLD) and cellulose binding domain (CBD) of cellulose binding protein A (CbpA) from Clostridium cellulovorans were constructed, expressed, and analyzed. The chimeric proteins with CBD(CbpA) all demonstrated strong affinity to Avicel. The chimeric protein with the PT region of EngD and the HLD had the best catalytic activity and the highest estimated percentage of soluble protein amongst the chimeric proteins. Native EngD and two of the chimeric proteins (EngD-PT-HLD-CBD and EngD-CBD) were purified and their characteristics analyzed. Their binding affinities to Avicel as well as their enzymatic activities against various substrates were found to be consistent with the results we saw from protein lysate samples, which was good binding to Avicel but a decrease in solubility and catalytic activities in chimeric proteins without PT and/or HLD. The reasons for these are discussed. These fusion proteins may be important in applications, such as immobilization to solid cellulose substrate for purification of proteins and enrichment/aggregation of protein complexes.     

Production of heparin oligosaccharides by fusion protein of MBP–heparinase I and the enzyme thermostability

Enzymatic depolymerization of heparin to produce LMWH, a useful anticoagulant, has attracted much attention due to its mild reaction conditions and high selectivity. In this paper, we examined the feasibility of heparin depolymerization by heparinase I fused with maltose-binding protein (MBP) (MBP–HepA), which was functionally expressed in recombinant Escherichia coli with high activity. Our results showed that MBP–HepA degraded heparin effectively and the LMWHs with the weight average molecular weight (M_w) less than 3000 Da and narrow polydispersity were formed by controlling the reaction time. Thermostability of the fused enzyme was studied and possible mechanism for heat inactivation was proposed. The results showed that the MBP–HepA was relatively unstable and the enzyme inactivation was dependent on a third-order kinetics at the high temperature below 45 °C.     

Characterization of a cellulose binding domain from Clostridium cellulovorans endoglucanase-xylanase D and its use as a fusion partner for soluble protein expression in Escherichia coli

Different chimeric proteins combining the non-catalytic C-terminal putative cellulose binding domain of Clostridium cellulovorans endoglucanase-xylanase D (EngD) with its proline-threonine rich region PT-linker, PTCBD(EngD), cellulose binding domain of C. cellulovorans cellulose binding protein A, CBD(CbpA), cohesin domains Cip7, Coh6 and CipC1 from different clostridial species and recombinant antibody binding protein LG were constructed, expressed, purified and analyzed. The solubilities of chimeric proteins containing highly soluble domains Cip7, CipC1 and LG were not affected by fusion with PTCBD(EngD). Insoluble domain Coh6 was solubilized when fused with PTCBD(EngD). In contrast, fusion with CBD(CbpA) resulted in only a slight increase in solubility of Coh6 and even decreased solubility of CipC1 greatly. PTCBD(EngD) and Cip7-PTCBD(EngD) were shown to bind regenerated commercial amorphous cellulose Cuprophan. The purity of Cip7-PTCBD(EngD) eluted from Cuprophan was comparable to that purified by conventional ion exchange chromatography. The results demonstrated that PTCBD(EngD) can serve as a bi-functional fusion tag for solubilization of fusion partners and as a domain for the immobilization, enrichment and purification of molecules or cells on regenerated amorphous cellulose.     

Specific Adhesion to Cellulose and Hydrolysis of Organophosphate Nerve Agents by a Genetically Engineered Escherichia coli Strain with a Surface-Expressed Cellulose-Binding Domain and Organophosphorus Hydrolase

A genetically engineered Escherichia coli cell expressing both organophosphorus hydrolase (OPH) and a cellulose-binding domain (CBD) on the cell surface was constructed, enabling the simultaneous hydrolysis of organophosphate nerve agents and immobilization via specific adsorption to cellulose. OPH was displayed on the cell surface by use of the truncated ice nucleation protein (INPNC) fusion system, while the CBD was surface anchored by the Lpp-OmpA fusion system. Production of both INPNC-OPH and Lpp-OmpA-CBD fusion proteins was verified by immunoblotting, and the surface localization of OPH and the CBD was confirmed by immunofluorescence microscopy. Whole-cell immobilization with the surface-anchored CBD was very specific, forming essentially a monolayer of cells on different supports, as shown by electron micrographs. Optimal levels of OPH activity and binding affinity to cellulose supports were achieved by investigating expression under different induction levels. Immobilized cells degraded paraoxon rapidly at an initial rate of 0.65 mM/min/g of cells (dry weight) and retained almost 100% efficiency over a period of 45 days. Owing to its superior degradation capacity and affinity to cellulose, this immobilized-cell system should be an attractive alternative for large-scale detoxification of organophosphate nerve agents.     

Obtaining of ScFv-CBD fusion protein and its application for affinity purification of recombinant human interferon alpha2b

The gene of ScFv-CBD-fusion protein has been designed using the DNA sequences encoding of single-chain antibody (ScFv) against human interferon alpha2b (IFN-alpha2b) and cellulose-binding domain (CBD) from Clostridium thermocellum cellulosome. Biosynthesis of ScFv-CBD utilizing high-productive Escherichia coli system was carried out and the accumulation of target protein in bacterial inclusion bodies was shown. After the purification of the inclusion bodies and their subsequent in vitro refolding the soluble ScFv-CBD-fusion protein was directly immobilized on cellulose by bioaffinity coupling. The possibility to obtain the preparative quantities of ScFv-CBD in biologically-active form using different refolding schemes was accurately investigated in the paper. The general applicability of biologically immobilized ScFv-CBD-fusion proteins for affinity purification of recombinant IFN-alpha2b is shown.     

不同蛋白标签对LMO2融合蛋白沉淀实验的影响

融合蛋白沉淀技术是一种用来研究蛋白质相互作用的新的体外实验技术, 通常利用蛋白亲和标签与探针蛋白融合表达来钓取未知相互作用蛋白或验证已知蛋白间的相互作用, 其中以谷胱甘肽巯基转移酶(GST)标签最为常用。LMO2(由LIM only缩写得名, 也称Ttg-2或Rbtn2)是一种小分子量难溶蛋白。利用原核系统分别表达了含有GST和麦芽糖结合蛋白(MBP)两种标签的LMO2融合蛋白, 发现GST-LMO2融合蛋白以包涵体的形式表达, 而MBP-LMO2融合蛋白则能够以可溶形式表达, 而且MBP-LMO2的表达量明显高于GST-LMO2融合蛋白。将可溶性的MBP-LMO2融合蛋白和复性后的GST-LMO2融合蛋白分别用于钓取K562细胞中LMO2的结合蛋白, 结果显示二者都可以结合K562细胞中内源性的GATA1蛋白, 而MBP-LMO2融合蛋白捕获的GATA1蛋白明显多于复性后的GST-LMO2融合蛋白。这一结果提示, 在研究一些分子量小、疏水性强的蛋白质时改变标签蛋白可能是一种有益的尝试。     

不同蛋白标签对LMO2融合蛋白沉淀实验的影响

融合蛋白沉淀技术是一种用来研究蛋白质相互作用的新的体外实验技术, 通常利用蛋白亲和标签与探针蛋白融合表达来钓取未知相互作用蛋白或验证已知蛋白间的相互作用, 其中以谷胱甘肽巯基转移酶(GST)标签最为常用。LMO2(由LIM only缩写得名, 也称Ttg-2或Rbtn2)是一种小分子量难溶蛋白。利用原核系统分别表达了含有GST和麦芽糖结合蛋白(MBP)两种标签的LMO2融合蛋白, 发现GST-LMO2融合蛋白以包涵体的形式表达, 而MBP-LMO2融合蛋白则能够以可溶形式表达, 而且MBP-LMO2的表达量明显高于GST-LMO2融合蛋白。将可溶性的MBP-LMO2融合蛋白和复性后的GST-LMO2融合蛋白分别用于钓取K562细胞中LMO2的结合蛋白, 结果显示二者都可以结合K562细胞中内源性的GATA1蛋白, 而MBP-LMO2融合蛋白捕获的GATA1蛋白明显多于复性后的GST-LMO2融合蛋白。这一结果提示, 在研究一些分子量小、疏水性强的蛋白质时改变标签蛋白可能是一种有益的尝试。     

High yield, purity and activity of soluble recombinant Bacteroides thetaiotaomicron GST-heparinase I from Escherichia coli

Heparinase I from Flavobacterium heparinum, a source of diverse polysaccharidases, suffers from low yields, insufficient purity for structural studies and insolubility when expressed as a recombinant product in Escherichia coli that is devoid of glycosaminoglycan polysaccharidases. In this study, cDNA coding for the orthologue of F. heparinum heparinase I was constructed from genomic information from the mammalian gut symbiont Bacteroides thetaiotaomicron and expressed in E. coli as a fusion protein with GST at the N-terminus. This resulted in high yield (30 mg/g dry bacteria) of soluble product and facilitated one-step affinity purification to homogeneity. Purified heparinase I bearing the GST fusion exhibited a K_m of 2.3 μM and V_max of 42.7 μmol/min with a specific activity of 164 U/mg with heparin (average 12,000 Da) as substrate. The results indicate a 2-fold improvement in yield, specific activity and affinity for heparin as substrate over previous reports. The data suggest that the heparinase I from the gut symbiont exhibits a higher intrinsic affinity for heparin than that from F. heparinum. The purified GST fusion enzyme exhibited a requirement for Ca²⁺ and a pH optimum between 6.7 and 7.3 that was similar to the enzyme freed of the N-terminal GST portion. Our study revealed that catalytic activity of heparinase I requires a reducing environment. The GST facilitated immobilization of heparinase I in solid phase either for clinical purposes or for structural studies in absence of interference by contaminating polysaccharidases.     

Improved immobilization of fusion proteins via cellulose-binding domains

Cellulose-binding domains (CBDs) are structurally and functionally independent, noncatalytic modules found in many cellulose or hemicellulose degrading enzymes. Recent biotechnological applications of the CBDs include facilitated protein immobilization on cellulose supports. In some occasions there have been concerns about the stability of the CBD driven immobilization. Here we have studied the chromatographic behavior of variants of the Trichoderma reesei cellobiohydrolase I CBD belonging to family I. Both CBDs fused to antibody fragments and isolated CBDs were studied and compared. Tritium labeling by reductive methylation was used as a sensitive detection method. The fusion protein as well as the isolated CBD was found to leak from the column at a rate of 0.3-0.5% of the immobilized protein per column volume. However, the leakage could be overcome by using two CBDs instead of a single CBD for the immobilization. In this way leakage was reduced to less than 0.01% per column volume. The improved immobilization could also be seen as a decreased migration of the protein down the column in extended washes.     

Expression, immobilization, and enzymatic characterization of cellulose-binding domain-organophosphorus hydrolase fusion enzymes

Bifunctional fusion proteins consisting of organophosphate hydrolase (OPH) moieties linked to a Clostridium-derived cellulose-binding domain (CBD) were shown to be highly effective in degrading organophosphate nerve agents, enabling purification and immobilization onto different cellulose materials in essentially a single step. Enzyme kinetics studies were performed for the CBD-OPH fusions using paraoxon as the substrate. The kinetics values of the unbound fusion enzymes were similar to OPH with a modest increase in K(m). Immobilization of the enzymes onto microcrystalline cellulose resulted in a further increase in the K(m) values of approximately twofold. The pH profile of the cellulose-immobilized enzymes was also only minimally affected. The CBD-OPH fusion proteins could be immobilized onto a variety of cellulose matrixes, and retained up to 85% of their original activity for 30 days. The durability of the bound fusions increased with the amount of Avicel used, suggesting that protein/cellulose interactions may have a dramatic stabilizing effect. Repeated hydrolysis of paraoxon was achieved in an immobilized enzyme reactor with 100% degradation efficiency over 45 days. These fusion proteins should prove to be invaluable tools for the development of low cost, OPH-based cellulose materials for the simultaneous adsorption and degradation of stored or spilled organophosphate wastes.     

Preparation of recombinant RNase single-chain antibody fusion proteins

This article describes the construction, expression, and purification of RNase single-chain antibody fusion proteins. To construct a fusion protein, the gene for each moiety, the RNase and the binding ligand, is modified separately to contain complementary DNA encoding a 13 amino acid spacer that separates the RNase from the binding moiety. Appropriate restriction enzyme sites for cloning into the vector are also added. The modified DNA is combined and fused using the PCR technique of splicing by overlap extension (1). The resulting DNA construct is expressed in inclusion bodies in BL21(DE3) bacteria that are specifically engineered for the expression of toxic proteins (2). After isolation and purification of the inclusion bodies, the fusion protein is solubilized, denatured, and renatured. The renatured RNase fusion protein mixture is purified to homogeneity by two chromatography steps. The first column, a CM-Sephadex C-50 or a heparin Sepharose column, eliminates the majority of contaminating proteins while the second column, an affinity column (Ni²⁺-NTA agarose), results in the final purification of the RNase fusion protein.     

Affinity purification of antibodies by using Ni2+-resins on which inclusion body-forming proteins are immobilized

Bacterially expressed recombinant proteins are widely used for producing specific antibodies. Unfortunately, many recombinant proteins are recovered as insoluble materials, so-called inclusion bodies. Inclusion bodies are rather advantageous from a point of view of immunogens because fairly pure proteins can be feasibly extracted from the inclusion bodies. However, we encounter a problem with an insoluble protein when we make an antigen-immobilized column for affinity purification of antibodies because we need a soluble protein in usual immobilization methods. Histidine-tagged proteins can be bound to Ni(2+)-resins in buffer containing 6M guanidine-HCl, in which most insoluble proteins are solubilized. Taking advantage of this feature, we have successfully purified antigen-specific antibodies by directly using Ni(2+)-resins onto which denatured proteins are bound.     

Column flow reactor using acetohydroxyacid synthase I from Escherichia coli as catalyst in continuous synthesis of R-phenylacetyl carbinol

We tested the possibility of utilizing acetohydroxyacid synthase I (AHAS I) from Escherichia coli in a continuous flow reactor for production of R-phenylacetyl carbinol (R-PAC). We constructed a fusion of the large, catalytic subunit of AHAS I with a cellulose binding domain (CBD). This allowed purification of the enzyme and its immobilization on cellulose in a single step. After immobilization, AHAS I is fully active and can be used as a catalyst in an R-PAC production unit, operating either in batch or continuous mode. We propose a simplified mechanistic model that can predict the product output of the AHAS I-catalyzed reaction. This model should be useful for optimization and scaling up of a R-PAC production unit, as demonstrated by a column flow reactor.