Regulated secretion and purification of recombinant antibodies inE. coli

A plasmid foroptimizedproteinexpression of recombinant Fv antibodies (pOPE) inE. coli was used to express the variable domains of the murine monoclonal antibody HD39 specific for the human B-cell surface antigen CD22. The production of Fv antibodies by pOPE can be regulated over a wide range by varying the IPTG concentration. Antibodies that can discriminate between secreted and nonsecreted Fv antibody fragments were used to show that secretion is the limiting step for the production of functional Fv antibodies. IPTG concentrations above 20 μM increased the total antibody production, but did not yield larger amounts of secreted Fv antibodies. The addition of five histidines to the C terminus facilitates an easy single-step enrichment procedure based on immobilized metal affinity chromatography.     

Cloning and characterization of a single chain antibody to glucose oxidase from a murine hybridoma

Glucose oxidase (GOD) is an oxidoreductase catalyzing the reaction of glucose and oxygen to peroxide and gluconolacton (EC 1.1.3.4.). GOD is a widely used enzyme in biotechnology. Therefore the production of monoclonal antibodies and antibody fragments to GOD are of interest in bioanalytics and even tumor therapy. We describe here the generation of a panel of monoclonal antibodies to native and heat inactivated GOD. One of the hybridomas, E13BC8, was used for cloning of a single chain antibody (scFv). This scFv was expressed in Escherichia coli XL1-blue with the help of the vector system pOPE101. The scFv was isolated from the periplasmic fraction and detected by western blotting. It reacts specifically with soluble active GOD but does not recognize denatured GOD adsorbed to the solid phase. The same binding properties were also found for the monoclonal antibody E13BC8.     

Antibody engineering: the use of Escherichia coli as an expression host.

The hypervariable loops of an antibody molecule are supported on the relatively conserved beta-sheeted frameworks of the heavy- and light-chain variable domains (designated VH and VL domains, respectively). Residues within and flanking these loops interact with antigen and confer the specificity and affinity of antigen binding on the immunoglobulin molecule. Thus, the isolation and expression of VH and VL domain genes are of particular interest both for analysis of the determinants of antibody specificity and for generation of fragments with binding affinities for use in therapy and diagnosis. The PCR can now be used to isolate diverse repertoires of antibody VH and VL domain genes from antibody-producing cells from different species, including humans and mice. The genes can be expressed as either secreted or surface-bound Fv or Fab fragments, using Escherichia coli expression systems, and the desired antigen-binding specificity screened for or, preferably, selected. The use of E. coli as an expression host allows the required antigen-binding specificity to be isolated in clonal form in a matter of days. The VH and VL domain genes can also be hypermutated and higher-affinity variants isolated by screening or selection. Thus, the use of this technology should allow the isolation of novel binding specificities or specificities that are difficult to generate by hybridoma technology. It will also facilitate the isolation of human-derived Fv/Fab fragments that may be less immunogenic in therapy. This approach therefore has almost unlimited potential in the generation of therapeutics with binding specificities to order. The fragments can be used either alone or linked to effector functions in the form of antibody-constant domains or toxins. The new technology could prove to be a method of choice for the rapid and convenient production of designer antibodies.     

Efficient construction of a diabody using a refolding system: anti-carcinoembryonic antigen recombinant antibody fragment

Recombinant fragments of the variable region of antibodies are useful in many experimental and clinical applications. However, it can be difficult to obtain these materials in soluble form after their expression in bacteria. Here, we report an efficient procedure for preparing several variable-domain fragments (Fv), single-chain Fv (scFv), and a diabody (the smallest functional bispecific antibody) of anti-carcinoembryonic antigen (CEA) antibody by overexpression in Escherichia coli in inclusion bodies, using a refolding system to obtain renatured proteins. Two types of refolded Fv were prepared: (i) Heavy and light chains of the immunoglobulin variable regions (VH and VL, respectively) were coexpressed with a dicistronic expression vector (designated Fv(co)); (ii) VH and VL were expressed separately, mixed stoichiometrically, and refolded (designated Fv(mix)). All samples refolded with high efficiency; Fv(co), Fv(mix), scFv, and the bispecific diabody bound to several CEA-positive cell lines, exactly as did soluble Fv fragments secreted by E. coli (Fv(sol)) and the parent IgG. The refolded fragments inhibited binding of the parent IgG to CEA-positive cell lines, indicating that their epitope is identical to that of IgG. The bispecific diabody, which combined variable-region fragments of anti-CEA antibody with variable-region fragments of anti-CD3 antibody, was also prepared using the refolding system. This refolded diabody could bind to lymphokine-activated killer cells. In addition, its cytotoxicity toward human bile duct carcinoma TFK-1 and other several other CEA-positive cell lines was concentration-dependent. Taken together, our results suggest that a refolding procedure can be used to prepare various functional antibody fragments (Fv, scFv, and diabody).     

The disulfide bonds in antibody variable domains: effects on stability, folding in vitro, and functional expression in Escherichia coli.

The formation of the disulfide bonds in the variable domains VH and VL of the antibody McPC603 was found to be essential for the stability of all antigen binding fragments investigated. Exposure of the Fv fragment to reducing conditions in vitro resulted in irreversible denaturation of both VH and VL. In vitro refolding of the reduced Fv fragment was only possible when the disulfide bonds were allowed to form under oxidizing conditions. The analysis of a series of mutants of the Fv fragment, the Fab fragment and the single-chain Fv fragment, all secreted into the periplasm of Escherichia coli, in which each of the cysteine residues of the variable domains was replaced by a series of other amino acids, showed that functional antigen binding fragments required the presence of both the disulfide bond in VH and the one in VL. These results were also used to devise an alternative expression system based on the production of insoluble fusion proteins consisting of truncated beta-galactosidase and antibody domains, enzymatic cleavage, and refolding and assembly in vitro. This strategy should be useful for providing access to unstable antibody domains and fragments.     

原核表达载体pOPE101-8E5的改构及单链抗体的表达鉴定

本研究利用基因重组技术将链亲和素(core-streptavidin)cDNA插入原核表达载体pOPE101-8E5的3′端,并用单链抗体scFv-C4的重链和轻链可变区cDNA取代其scFv-8E5,构建重组表达载体pOPE101-C4::core-streptavidin。将该表达载体转化入在大肠杆菌中进行诱导表达,用聚丙烯酰胺凝胶电泳和免疫印迹法分析表达产物的表达量和产物活性。结果提示我们成功地获得一个分子量约为45kDa的scFv-C4::core-streptavidin的融合蛋白,它可结合KG1a细胞裂解物中分子量约为60kDa、45kDa的蛋白带,且其结合功能可以通过融合蛋白中的链亲和素基因直接测定。     

肝癌特异性鼠源及人源化单链抗体基因的构建及大肠杆菌中的表达

为探讨一株肝细胞癌特异性鼠源及其人源化单链抗体基因在大肠杆菌中的可溶性表达策略并比较二者对抗原的结构能力,在三种载体中分别以融合、分泌及胞内表达的方式进行了研究,表达产物均以包涵体形式存在;对复性后的单链抗体以细胞ＥＬＩＳＡ及竞争抑制流式细胞仪法进行检测,表明人源化单链抗体和鼠源单链抗体有相近的抗原结合能力。结论是：大肠杆菌中表达的基因工程单链抗体的可溶性可能主要由自身氨基酸一级序列决定;先前的设     

Regulation of cell cycle and productivity in NS0 cells by the over-expression of p21CIP1.

We have constructed NS0 myeloma cell lines that inducibly express the p21CIP1 cyclin dependent kinase inhibitor, using the Lacswitch system. Ectopic p21(CIP1) protein expression was rapidly induced within 12 h of addition of IPTG, causing G1-phase arrest and almost complete inhibition of cell proliferation. The production of a chimeric IgG4 antibody, expressed constitutively from an independent promoter, was found to be significantly increased by more than 4-fold in p21CIP1-arrested cells. This study demonstrates for the first time the successful construction of anchorage-independent and proliferation-controlled NS0 cell lines with enhanced secreted chimeric antibody production independent of the inducible promoter activity used to achieve cytostasis.     

Affinity separation using an Fv antibody fragment-"smart" polymer conjugate

Poly(N-isopropylacrylamide), or PNIPAAm, is considered a "smart" polymer because it sharply precipitates when heated above a critical temperature, about 32 degrees C in water, and redissolves when cooled. Conjugates made of PNIPAAm and IgG antibodies also exhibit the same critical temperature behavior. Interestingly, antigens that are complexed with these conjugates can also be phase-separated along with the conjugates. In this work, we conjugated PNIPAAm for the first time to the immunoglobulin Fv fragment, the smallest fragment of an antibody that still retains the antigenic affinity of the whole antibody. For our studies, we used an Fv fragment that strongly binds hen egg white lysozyme (HEL). The purified Fv fragment-polymer conjugate precipitated at the same temperature as did the pure polymer. After addition of the conjugate to a mixture containing HEL and after thermal separation of the conjugate at 37 degrees C, the amount of HEL in solution was reduced by as much as 80%. We were able to demonstrate the reversibility of the separation through three cycles of precipitation and dissolution. It was also possible to recover free HEL by thermal separation of the conjugate in the presence of an eluant, 50 mM diethylamine. The conjugate can then be recycled for second use. In conclusion, immunoseparations can be performed using smart polymer conjugates made with just the variable domains of an antibody. Unlike whole antibodies, fragments of antibodies can be produced in Escherichia coli, allowing easier genetic engineering of the antibody and tailoring of the conjugate.     

Expression of an antibody Fv fragment in myeloma cells

The antigen binding site on antibodies is fashioned by loops at the tips of the beta-sheet framework of both heavy and light chain variable domains. A heterodimer of both variable domains (Fv fragment), incorporating loops from an anti-lysozyme antibody, was expressed and secreted from myeloma cells in good yield (8 mg/l in supernatant from roller bottles), and shown to bind lysozyme. The two subunits were found to be in dynamic equilibrium but are overwhelmingly associated at neutral pH. The small size of Fv fragments (25 x 10(3) Mr) make them attractive for structural studies, in vivo imaging, and therapy.     

Preparation and application of anti-idiotypic antibody against anti-gibberellin A4 antibody.

A monoclonal anti-idiotypic antibody was raised against anti-gibberellin A4 (GA4) antibody, which recognizes biologically active gibberellins such as GA1 and GA4 specifically. Amino acid sequences of variable regions of both anti-GA4 and anti-idiotypic antibodies were analyzed. By using the property of the anti-idiotypic antibody to compete with GA1/4 in binding to the anti-GA4 antibody, we successfully applied the anti-idiotypic antibody to ELISA as a tracer for measuring GA1/4. The single-chain Fv (scFv) gene of the anti-idiotypic antibody was constructed, and scFv expressed in E. coli showed binding activity to anti-GA4 antibody. These results suggest the possible application of anti-idiotypic antibody as a handy and stable source of an enzymatic tracer for ELISA by production of fusion protein of the scFv and an appropriate enzyme.     

The intervening removable affinity tag (iRAT) production system facilitates Fv antibody fragment‐mediated crystallography

Fv antibody fragments have been used as co‐crystallization partners in structural biology, particularly in membrane protein crystallography. However, there are inherent technical issues associated with the large‐scale production of soluble, functional Fv fragments through conventional methods in various expression systems. To circumvent these problems, we developed a new method, in which a single synthetic polyprotein consisting of a variable light (V_L) domain, an intervening removable affinity tag (iRAT), and a variable heavy (V_H) domain is expressed by a Gram‐positive bacterial secretion system. This method ensures stoichiometric expression of V_L and V_H from the monocistronic construct followed by proper folding and assembly of the two variable domains. The iRAT segment can be removed by a site‐specific protease during the purification process to yield tag‐free Fv fragments suitable for crystallization trials. In vitro refolding step is not required to obtain correctly folded Fv fragments. As a proof of concept, we tested the iRAT‐based production of multiple Fv fragments, including a crystallization chaperone for a mammalian membrane protein as well as FDA‐approved therapeutic antibodies. The resulting Fv fragments were functionally active and crystallized in complex with the target proteins. The iRAT system is a reliable, rapid and broadly applicable means of producing milligram quantities of Fv fragments for structural and biochemical studies.     

Cloning,expression, and identification of anti‐carbofuran single chain Fv gene

Phage display method was used to clone anti‐carbofuran (CBF) single chain Fv (scFv) gene. The heavy chain and light chain variable region genes were amplified by the polymerase chain reaction from the CBF‐specific hybridoma cell lines 5D3 and assembled as a scFv DNA fragment with linker peptide (Gly₄Ser)₃. The scFv DNA fragment was cloned into M13 phagemid vector pCANTAB5E and the anti‐CBF antibody libraries were then constructed. After one round of panning with CBF‐ovalbumin (CBF‐OVA) as a conjugate, antigen‐binding positive recombinant phage clones were successfully selected by enzyme‐linked immunosorbent assay (ELISA). The positive phages were used to infect Escherichia coli HB2151 cells and the expression of the soluble scFv antibodies was then induced by IPTG. The scFv antibody was about 31 kDa by SDS‐PAGE and showed HRP‐anti‐E‐tag antibody‐recognized activity by Western blotting. The indirect competitive ELISA (icELISA) showed that the recombinant scFv antibody could competitively combine with CBF, with the IC₅₀ value of 1.07 ng/mL. The cross reactivity studies showed that the anti‐CBF scFv antibody, similar to the parent monoclonal antibody, poses high specificity to CBF and has little reactivity to the analogs. Taken together, these findings suggest that the recombinant scFv antibody can be used for further developing immunoassay method for CBF. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Production of monoclonal antibodies specific for Eimeria tenella microgametocytes

A panel of 4 monoclonal antibodies specific for Eimeria tenella, the causative agent of cecal coccidiosis of birds in the genus Gallus, was produced by standard techniques. The indirect fluorescent antibody (IFA) test demonstrated specificity of these 4 antibodies for the microgametocytes. Hybridoma TIA3B9 secreted a monoclonal antibody of subisotype IgG2b that was used throughout the course of this study. Immunologic potency of this antibody was demonstrated by in vitro experiments that revealed a greater than 50% reduction in oocyst production, indicating an apparent inhibition of fertilization.     

Aglycosylated antibodies and antibody fragments produced in a scalable in vitro transcription-translation system

We describe protein synthesis, folding and assembly of antibody fragments and full-length aglycosylated antibodies using an Escherichia coli-based open cell-free synthesis (OCFS) system. We use DNA template design and high throughput screening at microliter scale to rapidly optimize production of single-chain Fv (scFv) and Fab antibody fragments that bind to human IL-23 and IL-13α1R, respectively. In addition we demonstrate production of aglycosylated immunoglobulin G (IgG₁) trastuzumab. These antibodies are produced rapidly over several hours in batch mode in standard bioreactors with linear scalable yields of hundreds of milligrams/L over a 1 million-fold change in scales up to pilot scale production. We demonstrate protein expression optimization of translation initiation region (TIR) libraries from gene synthesized linear DNA templates, optimization of the temporal assembly of a Fab from independent heavy chain and light chain plasmids and optimized expression of fully assembled trastuzumab that is equivalent to mammalian expressed material in biophysical and affinity based assays. These results illustrate how the open nature of the cell-free system can be used as a seamless antibody engineering platform from discovery to preclinical development of aglycosylated monoclonal antibodies and antibody fragments as potential therapeutics.     

Evaluating the Use of Antibody Variable Region (Fv) Charge as a Risk Assessment Tool for Predicting Typical Cynomolgus Monkey Pharmacokinetics

The pharmacokinetic (PK) behavior of monoclonal antibodies in cynomolgus monkeys (cynos) is generally translatable to that in humans. Unfortunately, about 39% of the antibodies evaluated for PKs in cynos have fast nonspecific (or non-target-mediated) clearance (in-house data). An empirical model relating variable region (Fv) charge and hydrophobicity to cyno nonspecific clearance was developed to gauge the risk an antibody would have for fast nonspecific clearance in the monkey. The purpose of this study was to evaluate the predictability of this empirical model on cyno nonspecific clearance with antibodies specifically engineered to have either high or low Fv charge. These amino acid changes were made in the Fv region of two test antibodies, humAb4D5-8 and anti-lymphotoxin α. The humAb4D5-8 has a typical nonspecific clearance in cynos, and by making it more positively charged, the antibody acquires fast nonspecific clearance, and making it less positively charged did not impact its clearance. Anti-lymphotoxin α has fast nonspecific clearance in cynos, and making it more positively charged caused it to clear even faster, whereas making it less positively charged caused it to clear slower and within the typical range. These trends in clearance were also observed in two other preclinical species, mice and rats. The effect of modifying Fv charge on subcutaneous bioavailability was also examined, and in general bioavailability was inversely related to the direction of the Fv charge change. Thus, modifying Fv charge appears to impact antibody PKs, and the changes tended to correlate with those predicted by the empirical model.     

Aglycosylated antibodies and antibody fragments produced in a scalable in vitro transcription-translation system

We describe protein synthesis, folding and assembly of antibody fragments and full-length aglycosylated antibodies using an Escherichia coli-based open cell-free synthesis (OCFS) system. We use DNA template design and high throughput screening at microliter scale to rapidly optimize production of single-chain Fv (scFv) and Fab antibody fragments that bind to human IL-23 and IL-13α1R, respectively. In addition we demonstrate production of aglycosylated immunoglobulin G (IgG1) trastuzumab. These antibodies are produced rapidly over several hours in batch mode in standard bioreactors with linear scalable yields of hundreds of milligrams/L over a 1 million-fold change in scales up to pilot scale production. We demonstrate protein expression optimization of translation initiation region (TIR) libraries from gene synthesized linear DNA templates, optimization of the temporal assembly of a Fab from independent heavy chain and light chain plasmids and optimized expression of fully assembled trastuzumab that is equivalent to mammalian expressed material in biophysical and affinity based assays. These results illustrate how the open nature of the cell-free system can be used as a seamless antibody engineering platform from discovery to preclinical development of aglycosylated monoclonal antibodies and antibody fragments as potential therapeutics.Key words: cell-free protein synthesis, Fab antibody, aglycosylated antibodies, HER2, trastuzumab     

Expression of a Chlamydia anticarbohydrate single-chain antibody as a maltose binding fusion protein.

A single-chain antibody fragment has been constructed for an antibody that binds to the Chlamydia specific carbohydrate structure of the lipopolysaccharide. Single-chain protein was expressed and secreted into the periplasmic space of E. coli as a fusion protein with the maltose binding protein. The fusion protein was purified in one step by virtue of its ability to bind to maltose. In a sandwich ELISA, the eluted protein bound Chlamydia lipopolysaccharide, which demonstrates that the single-chain protein domain will function as part of a fusion protein. The expression of maltose binding fusion proteins into the periplasmic space could be used for production of other single-chain antibodies or protein fragments requiring appropriate folding and disulfide bond formation.     

Isolation of human B-cell subpopulations for pharmacological studies.

Three groups of human peripheral blood B-lymphocytes were separated from each other by countercurrent centrifugal elutriation and free-flow electrophoresis. They differed in their state of maturation and in their capability to produce antibodies in vitro. These B-cell subpopulations were used to study features of a drug such as BAY R 1005. BAY R 1005 is a synthetic glycolipid analogue (GLA), which is supposed to modulate antibody synthesis. Mature, immunoglobulin- (Ig-) secreting B-lymphocytes secreted equal quantities of antibodies in the presence and in the absence of the GLA. BAY R 1005 was found to be without mitogenic activity on resting B-cells and did not induce them to produce antibodies. However, it supported the antibody production of preactivated B-lymphocytes. The in vitro preactivated B-cells were affected via monocytes. Only in vivo preactivated B-lymphocytes increased their antibody production under the direct influence of BAY R 1005.     

Generation of functional scFv intrabodies for triggering anti-tumor immunity

Intracellular expression of recombinant antibodies (intrabodies) allows to interfere with the functions of oncogenic or viral molecules expressed in different cell compartments and has therefore a vast clinical potential in therapy. Although the use of phage-display libraries has made it possible to select Fab or single chain Fv (scFv) antibody fragments usable for intracellular targeting, a major source of recombinant antibodies for therapeutic use still remains hybridoma B cells producing well-characterized monoclonal antibodies (mAbs). However, the cloning and the intracellular expression of antibody fragments derived from mAbs can be markedly hampered by a number of technical difficulties that include failure of cloning functional variable regions as well as lack of binding of the antibody fragments to the targeted molecule in an intracellular environment. We discuss herein various molecular methods that have been developed to generate functional recombinant antibody fragments usable as anti-tumor triggering agents when expressed in tumor cells. Such antibodies can neutralize or modify the activity of oncogenic molecules when addressed in specific subcellular compartments and/or they can be used to trigger anti-tumor immunity when expressed on tumor cell surface.