- Methodology article
- Open Access
A multi-Fc-species system for recombinant antibody production
© Moutel et al; licensee BioMed Central Ltd. 2009
- Received: 04 August 2008
- Accepted: 26 February 2009
- Published: 26 February 2009
Genomic, transcriptomic and proteomic projects often suffer from a lack of functional validation creating a strong demand for specific and versatile antibodies. Antibody phage display represents an attractive approach to select rapidly in vitro the equivalent of monoclonal antibodies, like single chain Fv antibodies, in an inexpensive and animal free way. However, so far, recombinant antibodies have not managed to impose themselves as efficient alternatives to natural antibodies.
We developed a series of vectors that allow one to easily fuse single chain Fv antibodies to Fc domains of immunoglobulins, improving their sensitivity and facilitating their use. This series enables the fusion of single chain Fv antibodies with human, mouse or rabbit Fc so that a given antibody is no longer restricted to a particular species. This opens up unlimited multiplexing possibilities and gives additional value to recombinant antibodies. We also show that this multi-Fc species production system can be applied to natural monoclonal antibodies cloned as single chain Fv antibodies and we converted the widely used 9E10 mouse anti-Myc-tag antibody into a human and a rabbit antibody.
Altogether, this new expression system, that brings constant quality, sensitivity and unique versatility, will be important to broaden the use of recombinant and natural monoclonal antibodies both for laboratory and diagnosis use.
- Chinese Hamster Ovary Cell
- Chinese Hamster Ovary
- Recombinant Antibody
- Natural Antibody
- Antibody Phage Display
Antibodies are essential tools for the identification and study of proteins involved in normal and pathological functions. Our need for specific antibodies will further increase in the post-genomic era . Recombinant antibodies like single chain Fv (scFv) represent an attractive alternative to natural antibodies. In particular, they can be selected using synthetic in vitro approaches like phage or ribosome display allowing fast, specific, animal-experiment independent and rather inexpensive selection of antibody . These antibodies can then be used, in principle, in any approach where natural antibodies are usually employed.
Nevertheless, this method of antibody generation has not imposed itself within academic use and almost no such recombinant antibodies are distributed commercially as laboratory or diagnosis reagents. This is rather surprising as currently available libraries are of large enough diversity to provide a high success rate with a very low technological investment. Some large scale approaches are currently developed partly based on recombinant antibodies [[3, 4]; see also http://www.antibody-factory.de] and we and others even showed that this approach allows the selection of antibodies that would be hard/impossible to obtain by other means [see for example [5–7]]. One of the main reasons for this lack of popularity is probably the general feeling that the sensitivity of recombinant antibodies is lower than that of natural antibodies. The apparent reduced affinity is mostly due to the fact that scFv are monovalent molecules that lack the avidity binding obtained through dimerization. Another limitation is that the end product is not exactly an antibody, but only an antibody fragment, which is more complicated to use than its natural counterpart.
To solve these limitations, we developed a series of expression vectors based on the pFuse expression system (commercially available from InvivoGen, see materials and methods) that allow expression of scFv in fusion with natural Fc regions. This approach strongly improved antibody sensitivity and ease of use, and additionally provided so far unavailable versatility since scFv can be fused to human, mouse and rabbit Fc in an easy one step cloning procedure. We further showed that this method can be applied to natural antibodies re-cloned as scFv. Thus, we fused the monoclonal anti-Myc antibody 9E10 to human and rabbit Fc and showed that, as for recombinant antibodies, it provides extended multiplexing possibilities. We believe that the described method will be decisive in allowing the recombinant antibody approach to impose itself as a robust and powerful alternative option for antibody isolation and usage.
Plasmids construction and antibody production
We sub-cloned the F2C antibody directed against alpha-Tubulin  in fusion with the human, mouse or rabbit Fc domains generating antibodies hF2C, mF2C and rF2C, respectively. Three days after transient transfection of CHO cells with these expression plasmids, secreted antibodies were purified from cell supernatants using proteinA-affarose and loaded on SDS-PAGE. Western blotting analysis showed that each CHO supernatant expressed the expected 53 kDa antibody that can be specifically detected using anti-IgG antibodies directed against the respective species (Figure 1B). Because the scFvs were fused to the hinge domain of IgGs, the Fc domains were expected to form di-sulfide bridges. We confirmed using SDS-PAGE analysis that, in non-reducing conditions, the scFv-Fc behave as dimeric proteins while they migrate as monomers upon reduction (Figure 1C).
scFv versus scFv-hFc as tools for western blotting and immunofluorescence
We tested whether scFv-Fc could be efficiently used in western blotting experiments. NP40 solubilised lysates of HeLa cells were separated by SDS-PAGE and transferred to nitrocellulose membrane. The membrane was cut and incubated with either F2C or SF9 (directed against nonmuscle MyosinIIA ) fused to either human, mouse or rabbit Fc domains. The membrane strips were then incubated with species-specific HRP-labeled secondary antibodies and subsequently developed. As shown in Figure 1D, we found that a specific band was detected in each condition indicating that direct dilution of unpurified culture medium from transfected CHO cells transiently expressing scFv-xFc (where x means human, rabbit or mouse) can be used for western blot experiments.
With the increasing power of large-sale projects in genomics, transcriptomics and proteomics and the rise of reverse genetics, the need for specific antibodies has dramatically increased [see for example [4, 12]]. The recombinant approach is certainly a powerful alternative to classical, animal based approaches, in terms of price, speed and ethics. We and others have demonstrated that a large diversity of antibodies can be obtained this way (e.g. against haptens, proteins, glycolipids, particular conformation or post-translational modifications ). However, and despite the identification of high quality recombinant antibodies, their use is still limited, with very few fee-for service recombinant antibody companies on the market and almost no recombinant antibodies in the catalog of antibody providers. This may be due to the fact that, in general, the lack of avidity of monomeric recombinant antibodies strongly limits their sensitivity and that dedicated protocols have to be followed to efficiently use these antibodies. Different approaches have been developed to improve recombinant antibody avidity [see ]. The expression system we developed here helps to solve some of the above cited limitations while bringing unique versatility to recombinant antibodies. It additionally allows production of endotoxin-free recombinant antibodies. We have used it so far for more than 12 recombinant antibodies with comparable success (unpublished data). Furthermore, we show that this strategy can be applied not only to synthetic recombinant antibodies but also to natural ones. This may be interesting not only for changing antibody isotype or species but also to save valuable monoclonal antibodies from hybridomas that grow poorly or do not produce anymore. A limitation of our approach however is that some natural antibodies cannot be adapted to the scFv format without a strong loss in affinity.
By fusing scFv to an Fc region, we observed as suggested before [14, 15], that the antibodies keep their specificity and gain in sensitivity. scFv-xFc can be used like any natural antibody, without the user actually needing to know that the antibody is a recombinant one. For general use a simple, non purified, cell culture supernatant from CHO cells expressing the antibodies can be diluted between twenty and a thousand times. Importantly, we believe that it is more important to estimate recombinant antibodies "usability" or "effectiveness" instead of their "affinity". This is what is actually done for natural antibodies where the user selects the antibody giving the best signal to noise ratio while the affinity is rarely measured.
A key feature of our strategy is to free the antibody from its species-specificity restriction with the immediate ability, in one single sub-cloning step, to fuse the scFv to different Fc regions belonging to various species. The same antibody and therefore epitope recognized, can thus be used as a human, mouse or rabbit version. This opens up previously unattainable multiplexing possibilities since the antibody species is no longer a factor limiting combinations.
We developed here a comprehensive and integrated system for multi-species antibody production. It will simplify and strengthen the use of recombinant antibodies for daily laboratory applications and permit a flexibility and choice in multiplexing, previously not feasible. This simple and fully in vitro system, with no animal use, will ensure constant and endless production of antibodies belonging to any species and to any isotype. This may represent a breakthrough not only for their general laboratory use but also for diagnosis where multiplexing and constant quality are essential.
Cells and media
HeLa cells were maintained in Dulbecco's Modified Eagle Medium (DMEM) containing 10% heat-inactivated fetal calf serum (FCS), 2 mM L-Glutamine.
Chinese hamster ovary (CHO) cells were maintained in DMEM-F12 containing 10% FCS, 2 mM L-Glutamine.
Strains and plasmids constructions
The construction of scFv 9E10 (anti-Myc tag) has been described previously .
The NotI site (4025) present in the pFUSE-hFc2(IL2ss) vector (InvivoGen, CA, USA) was mutated by fill-in using the Klenow enzyme (Biolabs) followed by auto-ligation. Then a multiple cloning site (MCS) was added between the IL2ss and the hIgG2Fc by ligating a synthetic adaptor (5' AATTC GATAT CGGCC ATGGT TTGGT ACCTT GC 3' and 5' GATCT AGCGG CCGCA AGGTA CCAAA CCATG GC 3') between EcoRI (626) and BglII(648). The final construct contains the following MCS : EcoRI-EcoRV-NcoI-NotI-BglII.
pFUSE-rFc2(IL2ss) and pFUSE-mFc2(IL2ss) vectors were mutated in their Fc part (respectively IgG and IgG2a) to remove the NcoI site using a QuikChange site-directed mutagenesis kit (Stratagene, CA, USA) and the following primers : for rabbit Fc : forward primer 5' AGCCG AAGGT CTACA CAATG GGCCC TCCCC GGGA 3' and backward primer 5' TCCCG GGGAG GGCCC ATTGT GTAGA CCTTC GGCT 3' ; for mouse Fc : forward primer 5' TGATC TCCCT GAGCC CTATG GTCAC ATGTG TGGT 3' and backward primer 5' ACCAC ACATG TGACC ATAGG GCTCA GGGAG ATCA 3'
The Fc fragment of rabbit or mouse vectors were then sub-cloned into the mutated pFUSE-hFc2(IL2ss) vector using BglII and NheI. scFvs were then inserted in the modified vectors between NcoI and NotI. The plasmids were deposited on Genbank under accession numbers FJ716123, FJ716124 and FJ716125.
CHO cells were cultivated into 75 cm2 tissue culture flasks. Twenty four or forty eight hours after, when the cells reached 90% confluence, transfection was performed using 20 μg of plasmid DNA and 30 μL of lipofectamine2000 (Invitrogen, La Jolla, USA) during 4h30 according to the manufacturer's recommendations. Transfection medium was then removed and cells were incubated at 30°C with fresh DMEM-F12 for 72–96 hours. Cell supernatants were then harvested and kept at 4°C, or aliquoted and stored at -20°C. Stable cell lines were also selected for some antibodies. Depending on the antibody expressed, we obtained between 0.2 and 2 mg of antibody per Liter of medium. It is likely however that higher production may be achievable after optimization [see ].
After boiling in SDS-PAGE loading buffer, the samples were separated on a 12% SDS-PAGE and transferred to nitrocellulose membranes (Whatman GmbH, Dassel, Germany). For the experiment presented in Figure 1C, a loading buffer that did not contain DTT was used. Membranes were blocked in 3% non-fat milk-PBS (Phosphate Buffer Saline) with 0.2% Tween 20 for 1 h at room temperature or overnight at 4°C. Supernatants of scFv-xFc were used at 1/300 and added to the membranes for 1 h. Blots were then washed and incubated 1 h with secondary anti-human (or anti-mouse or anti-rabbit) HRP labeled antibodies (diluted at 1/10000 in PBS 0.1% Tween 20) (Jakson ImmunoResearch Laboratories, Westgrove, PA, USA). After 5 washes with PBS 0.1% Tween 20, secondary antibodies were then revealed using the SuperSignal chemoluminescent reagent (Pierce, Rockford, IL, USA) and Hyperfilm ECL (GE HealthCare, Velizy, France).
Immunofluorescence labeling were performed on HeLa cells. Cells were either fixed in 3% paraformaldehyde and permeabilized with PBS plus 0.1% saponin or fixed and permeabilized with cold methanol for 4 min at -20°C. scFv-xFc-containing supernatants were used diluted from 1/20 (anti-Myc) to 1/1000 (anti-Giantin) times and incubated for 1 hr on cells. Cells were then rinsed twice and incubated with secondary antibodies for 30 min (Jackson ImmunoResearch Laboratories, Westgrove, PA, USA). Purified scFv were used as described using short washes .
The authors would like to thank Dr. Joanne Young (Institut Curie, Paris, France) for proofreading and helpful comments on the manuscript. This work was supported by the Centre National de la Recherche Scientifique (CNRS) and by the Translational Department and the Research Center of the Institut Curie. FP was supported by a "Program Incitatif et Coopératif" (Immunotherapy, Institut Curie), by a grant from the Association pour la Recherche contre le Cancer (ARC) and by the Human Frontier Science Program Organization (HFSPO). SD was supported by the SMP Antibody Factory Grant of the German National Genome Research Network (NGFN).
- Konthur Z, Hust M, Dübel S: Perspectives for systematic in vitro antibody generation. Gene. 2005, 364: 19-29. 10.1016/j.gene.2005.05.042.View ArticleGoogle Scholar
- Hoogenboom HR: Selecting and screening recombinant antibody libraries. Nat Biotechnol. 2005, 23: 1105-16. 10.1038/nbt1126.View ArticleGoogle Scholar
- Schofield DJ, Pope AR, Clementel V, Buckell J, Chapple SDj, Clarke KF, Conquer JS, Crofts AM, Crowther SR, Dyson MR, Flack G, Griffin GJ, Hooks Y, Howat WJ, Kolb-Kokocinski A, Kunze S, Martin CD, Maslen GL, Mitchell JN, O'Sullivan M, Perera RL, Roake W, Shadbolt SP, Vincent KJ, Warford A, Wilson WE, Xie J, Young JL, McCafferty J: Application of phage display to high throughput antibody generation and characterization. Genome Biol. 2007, 8 (11): R254-10.1186/gb-2007-8-11-r254.View ArticleGoogle Scholar
- Taussig MJ, Stoevesandt O, Borrebaeck C, Bradbury A, Dübel S, Frank R, Gibson T, Gold L, Herberg F, Hermjakob H, Hoheisel J, Joos T, Konthur Z, Landegren U, Plückthun A, Ueffing M, Uhlen M: ProteomeBinders: Planning a European Resource of Affinity Reagents for Analysis of the Human Proteome. Nature Methods. 2007, 4: 13-17. 10.1038/nmeth0107-13.View ArticleGoogle Scholar
- Lev A, Denkberg G, Cohen CJ, Tzukerman M, Skorecki KL, Chames P, Hoogenboom HR, Reiter Y: Isolation and Characterization of Human Recombinant Antibodies Endowed with the Antigen-specific, Major Histocompatibility Complex-restricted Specificity of T Cells Directed toward the Widely Expressed Tumor T-cell Epitopes of the Telomerase Catalytic Subunit. Cancer Res. 2002, 62: 3184-94.Google Scholar
- Nizak C, Monier S, Del Nery E, Moutel S, Goud B, Perez F: Recombinant Antibodies to the Small GTPase Rab6 as Conformation Sensors. Science. 2003, 300: 984-987. 10.1126/science.1083911.View ArticleGoogle Scholar
- Dimitrov A, Quesnoit M, Moutel S, Cantaloube I, Pous C, Perez F: Detection of GTP-Tubulin Conformation in Vivo Reveals a Role for GTP Remnants in Microtubule Rescues. Science. 2008, 322: 1353-1356. 10.1126/science.1165401.View ArticleGoogle Scholar
- Nizak C, Martin-Lluesma SM, Moutel S, Roux A, Kreis TE, Goud B, Perez F: Recombinant antibodies selected against subcellular fractions to track endogenous protein dynamics in vivo. Traffic. 2003, 7: 739-753. 10.1034/j.1600-0854.2003.00132.x.View ArticleGoogle Scholar
- Nizak C, Moutel S, Goud B, Perez F: Selection and application of recombinant antibodies as sensors of Rab protein conformation. Meth Enzymol. 2005, 403: 135-153. 10.1016/S0076-6879(05)03012-0.View ArticleGoogle Scholar
- Fuchs P, Breitling F, Little M, Dübel S: Primary structure and functional scFv antibody expression of an antibody against the human protooncogen c-myc. Hybridoma. 1997, 16: 227-33.View ArticleGoogle Scholar
- Perez F, Diamantopoulos GS, Stalder R, Kreis TE: CLIP-170 highlights growing microtubule ends in vivo. Cell. 1999, 96: 517-27. 10.1016/S0092-8674(00)80656-X.View ArticleGoogle Scholar
- Uhlen M, Bjorling E, Agaton C, Szigyarto CA, Amini B, Andersen E, Andersson AC, Angelidou P, Asplund A, Asplund C, Berglund L, Bergstrom K, Brumer H, Cerjan D, Ekstrom M, Elobeid A, Eriksson C, Fagerberg L, Falk R, Fall J, Forsberg M, Bjorklund MG, Gumbel K, Halimi A, Hallin I, Hamsten C, Hansson M, Hedhammar M, Hercules G, Kampf C, Larsson K, Lindskog M, Lodewyckx W, Lund J, Lundeberg J, Magnusson K, Malm E, Nilsson P, Odling J, Oksvold P, Olsson I, Oster E, Ottosson J, Paavilainen L, Persson A, Rimini R, Rockberg J, Runeson M, Sivertsson A, Skollermo A, Steen J, Stenvall M, Sterky F, Stromberg S, Sundberg M, Tegel H, Tourle S, Wahlund E, Walden A, Wan J, Wernerus H, Westberg J, Wester K, Wrethagen U, Xu LL, Hober S, Ponten F: A Human Protein Atlas for Normal and Cancer Tissues Based on Antibody Proteomics. Mol Cell Proteomics. 2005, 4 (12): 1920-1932. 10.1074/mcp.M500279-MCP200.View ArticleGoogle Scholar
- Dubel S, Kontermann RE: Recombinant Antibodies. Antibody Engineering. 2001, Springer, editor, New-York, 3-16.View ArticleGoogle Scholar
- Persic L, Roberts A, Wilton J, Cattaneo A, Bradbury A, Hoogenboom HR: An integrated vector system for the eukaryotic expression of antibodies or their fragments after selection from phage display libraries. Gene. 1997, 187: 9-18. 10.1016/S0378-1119(96)00628-2.View ArticleGoogle Scholar
- Powers DB, Amersdorfer P, Poul M, Nielsen UB, Shalaby MR, Adams GP, Weiner LM, Marks JD: Expression of single-chain Fv-Fc fusions in Pichia pastoris. J Immunol Methods. 2001, 251: 123-35. 10.1016/S0022-1759(00)00290-8.View ArticleGoogle Scholar
- Wurm FM: Production of recombinant protein therapeutics in cultivated mammalian cells. Nat Biotechnol. 2004, 22 (11): 1393-8. 10.1038/nbt1026.View ArticleGoogle Scholar
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