Methods for Producing Active scFv Antibodies and Libraries Therefor
The present disclosure describes scFv antibody libraries, antibodies isolated from the libraries, and methods of producing and using the same.
This application claims benefit of priority from U.S. provisional application Ser. No. 60/894,947, filed Mar. 15, 2007, which is herein incorporated by reference in its entirety.
FIELDThis disclosure relates to recombinant single-chain antibodies and methods of producing and using such antibodies.
BACKGROUNDGenetic engineering approaches have allowed the production of recombinant antibodies having specific binding specificities, specific domain structures, and other desirable properties. One type of genetically engineered antibody is the single chain Fv fragment (scFv). Single chain Fv fragments are genetically engineered polypeptides that contain a heavy chain variable region (VH) linked to a light chain variable region (VL) via a flexible peptide linker. Each VH and VL domain contains three complementarity determining regions (CDRs). CDRs are short amino acid sequences that vary greatly among antibody molecules, and thus, are responsible for generating the great diversity of antibody binding specificity. The combination of the CDRs of the VH plus the CDRs of the VL determines the binding specificity of any given antibody. Single chain Fv fragments display the binding specificity and monovalent binding affinity of full-size antibodies and provide the added benefit of relative ease of genetic manipulation and expression (because scFvs are encoded by and expressed from a single coding sequence, rather than from separate coding sequences, as are full-size antibodies). Single chain Fv fragments and other recombinant antibodies are used in a broad variety of applications, for example, in medical diagnostic tests, in basic research, and as therapeutic antibody treatments for various diseases.
Intrabodies are genetically-engineered antibody molecules that are ectopically expressed within cells. Intrabodies can be used to visualize or to modulate the function of a target antigen within living cells. For example, the use of intrabodies can induce a phenotypic knockout either by directly inhibiting the function of the targeted antigen or by diverting the targeted antigen from its normal intracellular location (e.g., an intrabody can redirect its target antigen to the degradation machinery). Intrabodies can also enhance or change the function of their target antigens. For protein targets, intrabodies can be targeted to a specific post-translational modification or to a specific antigen conformation. Moreover, an intrabody-induced phenotypic knockout can be confined to a specific cell compartment by targeting an intrabody to the specific subcellular compartment using an addressing signal (e.g., a nuclear localization signal, a mitochondrial localization signal, or an endoplasmic reticulum retention signal). Intrabodies can also modulate target function by modifying the oligomeric structure of the target.
Because intrabody phenotypic knockout relies only on the binding capacity of the antibody molecule to its target, it is not necessary to express within the cell a complete antibody molecule but only its binding site, which is entirely located within the variable region (Fv). Given their advantages of small size and antigen specificity encompassed within a single polypeptide chain, scFvs are the most common type of recombinant antibody fragment used for intracellular antibody expression.
One serious limitation to the use of intrabodies is that most scFvs are not able to fold under the reducing conditions of the cell cytosol and nucleus. Under such conditions the two conserved disulfide bridges of scFvs are reduced, thereby destabilizing and inactivating the binding activity of many scFvs. In vitro, most scFvs cannot be renatured under reducing conditions. Statistical analyses of scFv sequences have shown that fewer than 1% of the scFvs are stable enough to be expressed and active in absence of disulfide bond formation. In addition, even if a scFv protein is indeed stable enough in its reduced form to be expressed and active in vivo, other parameters such as protease susceptibility or folding kinetics may also influence the final in vivo fate of the intrabody and thus are critical for ultimate intrabody expression and activity.
To obtain an active intrabody, current approaches often involve two successive steps. First, a panel of scFv or Fab antibodies that specifically bind an antigen of interest are identified (for example, by screening a phage display library). Second, the specifically-binding antibodies are tested for their ability to bind and/or inhibit the target antigen in vivo. Because fewer than 1% of scFvs are potentially useful as intrabodies (because they are not expressed and/or cannot properly fold under the reducing conditions that exist within a cell), identification of a single scFv that can be used as an intrabody requires the isolation of more than 100 scFv clones, a number that is unlikely to be obtained in most cases.
In view of the foregoing difficulties in producing and identifying antibodies that can be used as intrabodies for use in medical and research applications, what is needed are more efficient methods of producing and selecting antibodies that can be used as intrabodies.
SUMMARYIn a first aspect, described herein is an antibody library that includes at least about 106 unique scFv clones, wherein at least about 20% of the scFv clones encode an antibody that can detectably specifically bind a target antigen within a cell when the antibody encoded by the scFv clone is expressed within the cell.
In a second aspect, described herein is an antibody library, wherein the antibody library includes at least about 106 unique scFv antibody clones, wherein at least about 20% of the scFv antibody clones can be expressed within an E. coli cell to produce soluble antibody at a level of at least about 5 mgs per liter of E. coli cells, wherein the E coli cells have been grown to an OD600nm of about 5.
In a third aspect, described herein is an antibody library including at least about 106 unique scFv antibody clones, wherein each unique scFv antibody clone encodes a unique scFv antibody comprising at least one of a unique CDR3 VH sequence and a unique CDR3 VL sequence, and wherein the unique scFv antibody clones encode a framework sequence substantially identical to a framework sequence encoded by scFv13R4.
In any of the above antibody libraries, the unique scFv antibody clones can encode scFv antibodies including a unique CDR3 VH sequence.
In any of the above antibody libraries, the unique scFv antibody clones can encode scFv antibodies including a unique CDR3VL sequence.
In any of the above antibody libraries, the unique scFv antibody clones can encode scFv antibodies including a unique CDR3 VH sequence and a unique CDR3VL sequence.
In a fourth aspect, described herein is an scFv antibody that can be expressed as substantially soluble protein under reducing conditions, wherein the scFv antibody is isolated from the library described above in the third aspect. The scFv antibody can specifically bind to a target antigen under reducing conditions.
In a fifth aspect, described herein is a method of producing an scFv antibody, including expressing the scFv antibody described above in the fourth aspect within a cell, thereby producing the scFv antibody. The method can include further purifying the scFv antibody from the cell.
In a sixth aspect, described herein is a method for preparing an scFv antibody library enriched for scFv antibody clones that can be expressed within a cell, including: a) providing a first collection of scFv antibody clones, wherein the first collection comprises clones comprising a unique sequence within a CDR3 loop of VH, wherein the first collection has been enriched for scFv antibody clones that can be detectably expressed when introduced into a cell; b) providing a second collection of scFv antibody clones, wherein the second collection comprises clones comprising a unique sequence within a CDR3 loop of VL, wherein the second collection has been enriched for scFv antibody clones that can be detectably expressed when introduced into a cell; c) joining VH domains from scFv antibody clones of the first collection with VL domains from scFv antibody clones of the second collection to obtain a third collection of scFv antibody clones, wherein the third collection contains scFv antibody clones comprising a unique sequence within the CDR3 loop of VH and a unique sequence within the CDR3 loop of VL, thereby preparing the scFv antibody library enriched for scFv antibody clones that can be expressed within a cell.
In the above method for preparing an scFv antibody library, the first collection can include scFv antibody clones that contain a substantially identical VL sequence relative to other scFv antibody clones in the first collection, and the second collection can include scFv antibody clones that contain a substantially identical VH sequence relative to other scFv antibody clones in the second collection.
In the above method for preparing an scFv antibody library, the first collection can include scFv antibody clones that contain a VL sequence substantially identical to an scFv13R4VL sequence and the second collection can include scFv antibody clones that contain a VH sequence substantially identical to an scFv13R4 VH sequence.
In the above method for preparing an scFv antibody library, the first collection can include scFv antibody clones that include identical CDR1 and CDR2 sequences in the VH domain and the second collection can include scFv antibody clones that include identical CDR1 and CDR2 sequences in the VL domain.
In a seventh aspect, described herein is an antibody library produced by the method described above in the sixth aspect.
In an eighth aspect, described herein is an antibody selected from an antibody library produced by the method described above in the sixth aspect.
In a ninth aspect, the invention features a method for constructing an antibody library including: a) selecting an scFv antibody framework; b) introducing sequence diversity into a VH CDR3 region of the scFv antibody framework to generate a first library including scFv antibody clones including a unique VH CDR3 region; c) introducing sequence diversity into a VL CDR3 region of the scFv antibody framework to generate a second library including scFv antibody clones including a unique VL CDR3 region; d) removing, from the first library, clones that do not detectably express scFv antibody; e) removing, from the second library, clones that do not detectably express scFv antibody; and f) recombining the first and second libraries to generate a final library comprising scFv antibody clones comprising a unique VH CDR3 region and a unique VL CDR3 region, thereby constructing the antibody library.
In the above method, the scFv can be scFv13R4.
It is an object of the present invention to provide a novel antibody library for the isolation of scFvs expressed in the cytoplasm that may be used as intrabodies.
It is another object of the present invention to provide a novel antibody library based on a single framework and optimized for intracellular expression.
A further object of the present invention is to provide novel methods of constructing and validating a novel antibody library for the isolation of scFvs expressed in the cytoplasm that may be used as intrabodies.
Another object of the present invention is to provide novel methods of constructing and validating a novel antibody library based on a single framework and optimized for intracellular expression.
Still another object of the present invention is to provide novel methods of using an antibody library in order to produce highly expressed scFvs that may be used as intrabodies.
Yet another object of the present invention is to provide novel methods of using an antibody library in order to produce scFvs based on a single framework and optimized for intracellular expression.
These and other objects, features, and advantages of the present invention will become apparent after review of the following detailed description of the disclosed embodiments.
Provided herein are methods for constructing an scFv library enriched for scFvs that can be expressed within a prokaryotic or eukaryotic cell. The scFvs maintain their structure under the reducing conditions present within a cell, retain their ability to specifically bind a target antigen within a cell, and thus can be used as intrabodies in various therapeutic and research approaches. Because the methods described herein can be used to produce libraries of scFvs that are stable under reducing conditions, these libraries are also useful for producing scFvs that can be expressed by and purified from prokaryotic or eukaryotic cells (e.g., by lysing the cells and purifying the desired scFv by well-known techniques). Such purified scFvs are useful as antibodies for use in research, diagnostic tests, and for disease therapies.
An improved strategy for stabilizing scFvs to be used in vivo is to construct a scFv library tailored for intracellular expression. Ideally, such a library should only contain scFvs able to fold under reducing conditions such as those found in the cytoplasm of a cell. Another strategy is to construct an scFv library based on a single optimized antibody framework for intrabody selection.
Described herein are methods for constructing a novel antibody library that is based on a single optimized antibody framework and tailored for intracellular expression. Through molecular evolution, we obtained a human scFv called scFv13R4, which is expressed at high levels in E. coli cytoplasm. In addition, this scFv is highly expressed, soluble, and displays specific binding activity to a target antigen in yeast and mammalian cells. This scFv is very stable in vitro and can be renatured in presence of a reducing agent. In addition, analysis of its folding kinetics showed that it folds faster than the parent scFv and aggregates more slowly in vitro.
The human scFv library based on the framework of the optimized scFv13R4 contains more than a billion clones, which is larger than previous libraries of 107 to 108. The diversity of the present human scFv library is much greater than that of previous libraries because we designed the present library to encode VH and VL CDR3 loops of various different lengths. In addition, we used a biased mix of degenerate oligonucleotide sequences to encode CDR3 loops that mimic human CDR3. Using optimized CDR3 loops and filtering steps to eliminate the non-expressed clones, we purged the library of non-expressed scFvs and retained the cytoplasmically expressed scFvs without compromising the diversity of the clones, as confirmed through testing with several proteins used as the antigens. Contrary to previously described scFv libraries, most of the scFvs in the library are well expressed in E. coli and in mammalian cytoplasm.
This new approach to building scFv libraries allows facile and large-scale selection of functional intrabodies. For example, several strong binders against different proteins, including the Syk and Auroroa-A protein kinases, the αβ tubulin dimer, the papillomavirus E6 proteins, the core histones, gankyrin, and MAPK11-14, have been isolated from the library. Some of the selected scFvs are expressed at an exceptionally high level in the bacterial cytoplasm, allowing the purification of 1 mg or more of active scFv from only 20 ml of culture. Moreover, after three rounds of selection against core histones as a target antigen, more than half of the selected scFvs were active when expressed in vivo in human cells and were essentially localized in the nucleus. This new type of library, methods of creating and using such libraries, and antibodies isolated from such libraries, are useful not only for the simple and large-scale selection of functional intrabodies but also for the expression and purification of highly expressed scFvs that can be used in numerous biotechnological, diagnostic, and therapeutic applications.
Intrabodies
Intrabodies are genetically-engineered antibody molecules that are ectopically expressed within cells. Intrabodies can be used to visualize or to inhibit a targeted antigen in living cells, and thus find use in various research and medical (e.g., diagnostic and therapeutic) applications. However, intrabody technology has been limited by the fact that fewer than 1% scFvs in a typical antibody expression library are stable enough to be expressed and/or active in vivo, because the intracellular environment reduces the two conserved disulfide bridges that the vast majority of scFvs require for stability. Described herein are methods of producing libraries of scFvs that are greatly enriched for scFvs that are stable under reducing conditions and thus are suitable for use as intrabodies. The intrabodies can be used for various research, diagnostic, and therapeutic approaches that employ intrabodies.
In most cases, obtaining efficient intrabodies currently requires two successive steps. First, a panel of antibodies against the target antigen must be isolated. Due to the availability of very high quality naive antibody libraries displayed on phage, this step is now easily accomplished by phage-display and can be automated in order to isolate binders against several proteins in parallel. In a second step, these antibody fragments (scFv or Fab) must be tested in vivo for their ability to inhibit their target. However, most scFvs do not fold properly under the reducing conditions found in the cytosol and the nucleus of the cell where most of the interesting targets are located. This can result in aggregated and inactive scFvs, which are unable to interact with their target. Since less than 1% of scFvs are efficient as intrabodies, getting a single binder against a protein requires the isolation of 100 different scFvs, a number which is unlikely to be obtained in most cases. This makes the process of identifying intrabodies from regular scFv libraries a difficult procedure even when the screening is done in vivo using two-hybrid or equivalent systems. In addition, this low proportion of active scFvs in the current libraries results in a 100-fold decrease in the potential repertoire screened, making the isolation of intrabodies against different epitopes of the same protein unlikely.
Libraries
Described herein are novel phage-display libraries of scFvs optimized for intracellular expression and novel methods of constructing and using the library. The library is constructed on a single antibody framework of a parental scFv which was selected because of its improved activity inside the cytoplasm. The parental scFv is very stable, has favorable folding and aggregation kinetics and is expressed at very high levels in all tested cell types. Having a single framework for the construction of a library should allow more comparable expression levels between clones since most of their sequences are conserved.
Because CDR sequences also play a role in scFv folding and expression, however, we believed that the expression level of the clones would still exhibit some variability. To minimize these differences, we introduced variability only within the CDR3 loops because these loops are the most variable in antibodies and are thus more likely to be highly tolerant to sequence and length variations. Introduction of variability in the CDR3 is sufficient to generate antibodies against most proteins. In addition, we carefully biased the frequencies of the amino acids in these loops so as to recover the distribution observed among natural human sequences. When the expression levels of randomly selected clones were compared in the cytoplasm, despite some clear differences, a high proportion of them were correctly expressed both in E. coli and in mammalian cells. This proportion of intracellularly expressed scFvs is much higher than in previously described libraries.
We were also able to select binders (i.e., antibodies that specifically bind to a selected target antigen) against five different proteins (Aurora-A, GST:Syk, tubulin, histones, and E6 protein from papillomavirus HPV16). In subsequent studies we have also isolated binders against new targets including gankyrin and MAPK11-14. For MAPK11-14, the four proteins involved are the four isoforms of the p38 MAP kinase. These proteins are very homologous (˜60-74% identity). In all cases we were able to isolate scFvs specific for the isoform used for the selection. This underlines the specificity of the scFvs that can be isolated from this library.
A frequent concern when constructing scFv libraries is the simultaneous optimization of the library's diversity and size. Generally, the size of such a library is limited by the transformation efficiency to about 1010 clones. Given this limited number of clones, it is thus of premium importance to avoid non-expressed scFvs or duplicates. To solve this problem we first selected an antibody framework that was already optimized for intracellular expression, and then used a two-step procedure to further optimize the library.
First, we constructed 18 “small” libraries for each CDR3 length (13 VH CDR3 lengths and 5 VL CDR3 lengths) to be used for constructing the scFv library (see Example 1, herein below). Each of these 18 libraries was made by replacing the corresponding CDR3 of the parental scFv13R4 by the randomized CDR3. The resulting library with one and only one randomized CDR3 was then fused to the gene encoding chloramphenicol acetyltransferase (CAT), which we used as a selectable marker. After transformation of each CDR3 library into E. coli, the libraries were plated on chloramphenicol (CAM)-containing medium to select for those CDR3-CAT fusions that were expressed in the E. coli cytoplasm. This step reduced the diversity of each library by about 10-30%.
Although the CAT gene is used in the examples provided herein, one of ordinary skill in the art will understand that nucleic acids encoding any appropriate selectable marker can be fused with CDR3-encoding-nucleic acids and used in the methods provided herein to enrich scFv libraries for scFvs that are expressed in prokaryotic or eukaryotic cells. For example, suitable selectable markers for use in bacterial cells include, but are not limited to, the kanamycin resistance gene. Examples of selectable markers for use in mammalian cells include but are not limited to, e.g., the neomycin resistance gene, the puromycin resistance gene, and the hygromycin resistance gene. Examples of selectable markers for yeast cells include URA3, HIS3, and purE. In addition, markers such as green fluorescent protein (GFP) and derivatives thereof, beta-galactosidase, luciferase, or other luminescent, fluorometric, and/or colorimetric markers can be used, in all types of cells, for example, with fluorescence-activated cell sorting (FACS), to enrich scFv libraries for clones that encode scFvs that are capable of being expressed. One of ordinary skill in the art will understand how to use the teachings herein, together with what is known in the art, to select an appropriate selectable marker and an appropriate selection scheme to construct the scFv libraries described herein.
In a second step, we used PCR to randomly assemble the selected VH and VL libraries to generate the final diversity, based on the hypothesis that if a newly-generated scFv clone containing a new CDR3 sequence in its VH region plus the original VL of scFv13R4 was expressed, and if a newly-generated scFv clone containing a new CDR3 sequence in its VL region plus the original VH region of scFV13R4 was expressed, then a recombined scFv clone containing the new CDR3 sequence in its VH region plus the new CDR3 sequence in its VL region would also be expressed, thereby resulting in a library containing only expressed scFvs. This was the case since 19 out of 20 clones selected at random were expressed at least partially in a soluble form in E. coli cytoplasm. Importantly, since this selection step was done early during the library construction, the diversity of the final library was only limited by the final transformation. This final recombination step, by generating a high diversity, ensured that all the clones were unique in the final library. Altogether, this approach resulted in a library of 1.5 billion expressed and different scFvs.
Successful use of scFvs as intrabodies on a large scale requires several essential points to be fulfilled by the library. First, the scFv must be easy to isolate. This is the case for the presently-described methods, since not only we were able to isolate binders against all the tested proteins, but also a single cycle of selection was enough to get close to 100% of binders. This very high enrichment rate is presumably due both to the high quality of the biased library which contains only well expressed scFvs and to the use of the trypsin-sensitive helper phage KM13. This is of premium importance since it may be possible to use a single panning cycle before in vivo testing of the scFvs as intrabodies, allowing a better diversity of the targeted epitopes. Also, this high enrichment rate also reduces by a huge amount the quantity of purified antigen needed for the panning steps. We were able to select on microtiter plates with as little as 1 μg of protein per well. Since further selection and confirmation of the binding activity by ELISA is not necessary because of the very high proportion of binders, it is now possible to isolate good intrabodies with a very small amount of antigen. Second, the scFv should be able to fold in all the cell compartments, particularly in the reducing ones such as the cytoplasm and the nucleus. Again, this is the case for the scFv library described herein, since more than 80% of the tested clones are at least partially soluble in the cell. In addition, we have shown that good cytoplasmic binders can be obtained from the phage selected scFvs in E. coli and in eukaryotic cells.
Provided herein are antibody libraries that comprises at least about: 106, 5×106, 107, 5×107, 108, 5×108, 109, 1.5×109, 5×109, 1010, 5×1010, 1011, 5×1011, 1012, 1013, 1014, 1015, or 1016 unique scFv clones, wherein at least about: 20%, 30%, 40%, 50%, 60%, 70%, 80%, 85%, or more of the scFv clones encode an antibody that can detectably specifically bind a target antigen when the antibody encoded by the scFv clone is expressed within a cell (e.g., as an intrabody). The scFvs described herein can be expressed to detectably specifically bind to a target antigen in any prokaryotic or eukaryotic cell in which it would be desirable to detectably specifically bind a target antigen (e.g., but not limited to, a bacterial cell, a yeast cell, an insect cell, an amphibian cell, an avian cell, a mammalian cell, and the like).
By “specifically binds” is meant that an scFv antibody preferentially binds to its target antigen rather than to another antigen. By “detectably specifically binds” is meant that specific binding of scFv antibody to its target antigen can be observed, e.g., but not limited to a phenotypic change in the cell in which the scFv antibody binds to its target antigen, or detection of the interaction between the scFv antibody and its target antigen (e.g., co-localization of the scFv antibody and its target antigen within a cell).
EXEMPLARY USESThough the libraries described herein have been optimized for the isolation of intrabodies, the libraries can also be used to select scFvs for diagnostic and therapeutic applications. Furthermore, because we designed the CDR3 diversity using expressed human sequences, the scFvs present in the library are fully human and should not induce an anti-scFv antibody response in patients.
The libraries described herein and the antibodies produced by it are useful not only for identifying functional intrabodies but also for the isolation of highly expressed scFvs that could be used in numerous biotechnological and therapeutic applications. For example, the library and the antibodies produced by it may be have uses related to or including, but not limited to, gene delivery strategies therapeutic agents, drug discovery tools, counteracting agglutination of unwanted target molecules, combating disease states relating to misfolded protein disorders, and binding, neutralizing, or modifying the function of a cancer-related target.
For example, the intrabodies described herein can be used to modulate the activity of syk tyrosine kinase and other proteins implicated in allergic disorders (see, e.g., WO2005106481; see also Ulanova et al., Expert Opin Ther Targets 2005, 9:901-921. MAP kinases (MAPK) are key mediators of cell proliferation and are often targeted for inhibition in cancer therapy (see, e.g., Sebolt-Leopold J S and Herrera, R, Nat Rev Cancer, 4:937-947 (2004)) Other interesting targets are microtubules and associated proteins (see Jordan M A and Wilson, L, Nat Rev Cancer, 4:253-265 (2004)).
Immunobodies can be used to treat or prevent diseases in commercially valuable plants, such as crops, e.g., using the methods described in Villani, M E et al. Immunomodulation of cucumber mosaic virus infection by antibodies selected in vitro from a stable single-framework phage display library, Plant Molecular Biology 58(3):305 (2005)).
The intrabodies described herein can be used to treat, or prevent infections in human or animal cells. For example, intrabodies can be used to treat, ameliorate, or prevent infection of cells by the human immunodeficiency virus, using methods as described, for example, in Swan, C H et al, T-cell protection and enrichment through lentiviral CCR5 gene delivery, Gene Ther. 13:1480-1492.
The intrabodies described herein can be used to target proteins involved in neurological disorders, e.g., as described, e.g., in Miller, T W et al (A human single-chain Fv intrabody preferentially targets amino-terminal Huntingtin's fragments in striatal models of Huntington's disease, Neurobiol dis. 19:47-56 (2005)) and Miller and Messer (Intrabody applications in neurological disorders: progress and future prospects, Mol. Ther. 12:394-401 (2005).
The intrabodies described herein can be used for cancer therapy by targeting a protein involved in cancer like oncoproteins, as described, e.g., in Williams, B R and Zhu, Z (Intrabody-based approaches to cancer therapy: status and prospects, Current med Chem 13:1473-1480 (2006) and Doorbar J. and Griffin H. (2007) Intrabody strategies for the treatment of human papillomavirus-associated disease. Expert Opin. Biol. Ther. 7(5), 677-689.
The intrabodies described herein can be used to treat infections (e.g. but not limited to Epstein-Barr Virus) by targeting a protein expressed by an infectious agent, e.g., as described in Fang C Y et al (Modulation of Epstein0-Barr Virus Latent Membrane Protein 1 Activity by Intrabodies, Intervirology 50:254-263 (2007)
As described herein, an intrabody can be administered to a cell by administering to the cell an expression vector encoding the intrabody of interest. Expression vectors that are suitable for expression of intrabodies are well-known in the art. Administration of expression vectors that encode the intrabodies described herein, can be achieved by any one of numerous, well-known approaches, for example, but not limited to, direct transfer of the nucleic acids, in a plasmid or viral expression vector, alone or in combination with carriers such as cationic liposomes. Such expression vectors (which contain promoter and enhancer sequences suitable for expressing an operably-linked coding sequence when the expression vector is introduced into a cell) and methods for making, using, and delivering such vectors to cells are well known in the art and readily adaptable for use for administering intrabodies to cells.
Vectors can be any nucleotide construction used to deliver genes into cells, e.g., a plasmid or viral vector, such as a retroviral vector which can package a recombinant retroviral genome (see e.g., Pastan et al., Proc. Natl. Acad. Sci. U.S.A. 85:4486, 1988; Miller et al., Mol. Cell. Biol. 6:2895, 1986). The recombinant retrovirus can then be used to infect and thereby deliver a nucleic acid of the invention to the infected cells. The exact method of introducing the altered nucleic acid into mammalian cells is, of course, not limited to the use of retroviral vectors. Other techniques are widely available for this procedure including the use of adenoviral vectors (Mitani et al., Hum. Gene Ther. 5:941-948, 1994), adeno-associated viral (AAV) vectors (Goodman et al., Blood 84:1492-1500, 1994), lentiviral vectors (Naidini et al., Science 272:263-267, 1996), pseudotyped retroviral vectors (Agrawal et al., Exper. Hematol. 24:738-747, 1996). Physical transduction techniques can also be used, such as liposome delivery and receptor-mediated and other endocytosis mechanisms (see, for example, Schwartzenberger et al., Blood 87:472-478, 1996). This invention can be used in conjunction with any of these or other commonly used gene transfer methods. Appropriate means for transfection, including viral vectors, chemical transfectants, or physico-mechanical methods such as electroporation and direct diffusion of DNA, are described by, for example, Wolff, J. A., et al., Science, 247, 1465-1468, (1990); and Wolff, J. A. Nature, 352, 815-818, (1991).
Cell-permeable intrabodies (transbodies) can be administered to cells by fusing an scFv antibody with a protein transduction domain (PTD) that allows the cell-permeable intrabody to cross the cell membrane and enter the cell, for example, according to the methods described in Heng, B C and Cao, T (Making cell-permeable antibodies (Transbody) through fusion of protein transduction domains (PTD) with single chain variable fragment (scFv) antibodies: potential advantages over antibodies expressed within the intracellular environment (Intrabody), Med Hypotheses 64:1105-1108 (2005)). Alternatively, the scFv could be mixed with cationic lipids and delivered efficiently into cells, as shown with complete antibodies (Courtête J., Sibler A. P., Zeder-Lutz G., Dalkara D., Zuber G. & Weiss E. (2007) Suppression of cervical carcinoma cell growth by intracytoplasmic co-delivery of anti-oncoprotein E6 antibody and siRNA. Mol. Cancer Ther. 6, 1728-36). Such cell-permeable intrabodies can be used in cell culture (e.g., for research purposes) and for diagnostic purposes (e.g., to detect a virus or microorganism in sample of cells from a human, animal, or plant suspected of harboring an infectious agent. Such cell-permeable intrabodies can be administered to research animals (e.g. but not limited to systemic administration, e.g., by intravenously administering an intrabody to a research animal, or by topical administration, for example) to modulate the activity of a particular target antigen and thereby alter a phenotype in the animal. Such cell-permeable intrabodies can also be administered to human or non-human animal patients to treat or prevent disease or infection as described above. For example, cell-permeable intrabodies can be administered intravenously, topically, orally, or by other well-known methods, as will be appreciated by one of ordinary skill in the art.
Use of the Present scFv Antibodies for Large-Scale Antibody Production
Because the scFv antibody clones encode antibodies that fold under reducing conditions, the libraries described herein are also useful for identifying scFv antibodies that can be produced in large quantities by expressing the scFv antibodies in cells (e.g., prokaryotic cells such as bacterial cells, or eukaryotic cells such as yeast cells, insect cells, mammalian cells, or the like) and isolating the scFv antibodies from the cells. Single chain scFv antibodies for which it would be desirable to purify large quantities of antibody include but are not limited to, for example, scFv antibodies that are useful in laboratory research, for medical diagnostic tests, for commercial diagnostic tests or other types of diagnostic tests (e.g., to detect contaminating microorganisms in drinking water or food), and for antibody therapeutics (e.g., to treat cancer or to treat infectious or other types of diseases in which an antibody can be used to treat the disease).
Provided herein are antibody libraries for the isolation of expressed scFv antibodies, wherein the antibody library comprises at least about: 106, 5×106, 107, 5×107, 108, 5×108, 109, 1.5×109, 5×109, 1010, 5×1010, 1011, 5×1011, 1012, 1013, 1014, 1015, or 1016 unique scFv antibody clones, wherein at least about: 20%, 25%, 30%, 35%, 40%, 50%, 55%, 60%, 65%, 70%, 75%, 80%, or more than 80% of the scFv antibody clones can be expressed within a cell to produce soluble antibody at a level of at least about: 5 mgs, 8 mgs, 10 mgs, 15 ms, 20 mgs, 25 mgs, 30 mgs, 35 mgs, 40 mgs, 45 mgs, 50 mgs, or more than 50 mgs per liter of cells in a flask grown to an OD600nm of about 5.
There are many well-accepted approaches for expressing and purifying proteins such as expressed scFv antibodies from cells and one of ordinary skill in the art will understand how to select the most appropriate type of cell expression system from which to express and purify scFv antibodies. Many manuals that describe methods for protein expression are known in the art. See, e.g., Current Protocols in Molecular Biology, John Wiley and Sons, 2006.
DEFINITIONSBy “unique sequence” is meant that, within a collection of scFv antibody clones, there are at least 106 clones that contain a CDR3 sequence that is different from the CDR3 sequences of other clones within the collection of scFv antibody clones. With reference to an scFv antibody clone or a library of such clones, a “unique sequence” is different from the sequence present at the corresponding position within scFv13R4.
The terms “antibody framework” and “framework sequence” refer to any non-unique portion of the scFv antibody clones, e.g., any portion of the scFv antibody that is not a unique CDR3 VH region and/or unique CDR3VL region. As referred to herein, the antibody framework or framework sequence is that of scFv13R4, the parental scFv clone upon which the present libraries are based.
By “substantially identical” is meant that two or more amino acid sequences being compared are at least 98%, 98.5%, 99%, or 99.5% the same, or that two or more nucleic acid sequences being compared encode amino acid sequences that are at least 98%, 98.5%, 99%, or 99.5% the same.
By “common sequence” is meant a nucleotide or amino acid sequence that is shared among scFv clones.
By “scFv antibody clone” is meant a nucleic acid molecule that encodes an individual species of scFv antibody that comprises a unique sequence within the VH CDR3 domain, the VL CDR3 domain, or within both VH and VL CDR3 domains.
By “target antigen” is meant an antigen that is preferentially bound by a particular antibody, compared to the binding of that particular antibody to another antigen that is not a target antigen.
By “specifically binds” binds is meant that an antibody strongly and preferentially binds to a particular target antigen, compared to the binding of the antibody to other antigens.
By “ectopically expressed” is meant that expression of an antibody of interest is not naturally expressed within a particular type of cell in which the antibody is being expressed, i.e., the antibody is expressed within the cell because an expression construct encoding the antibody has been introduced into the cell.
By “isolated” or “purified” is meant that an scFv antibody has been substantially separated, produced apart from, or purified away from other biological components in the cell in which it has been produced, that is, substantially separated away from other cellular components, such as other cellular proteins, DNA, RNA, lipids, and the like. The term “isolated” or “purified” does not require absolute purity; rather, it is intended as a relative term. Preferably, an scFv antibody is purified or isolated away from other cellular components such that the scFv antibody represents at least: 25%, 30%, 40%, 50%, 60%, 70% 80%, 90%, 95%, or greater, of the total content of the scFv antibody preparation.
By “soluble” antibody means that an antibody molecule is not in aggregate form. A soluble antibody has the ability to specifically bind its target antigen.
By “substantially soluble” is mean that at least 20%, e.g., at least 25%, 30%, 40%, 50%, 60%, 70%, 80%, or more of an scFv antibody as described herein is properly folded and thus can specifically bind its target antigen.
Example 1 Construction of an scFv Library Optimized for Intracellular Expression Materials Bacterial Strains, Chemicals and EnzymesLB and 2xYT media were previously described (Miller, J. H. A Short Course in Bacterial Genetics: a Laboratory Manual and Handbook for Escherichia coli and Related Bacteria. Cold Spring Harbor Laboratory Press; 1992). Strain C-Max5F′ (Bio-rad laboratories) is E. coli K-12, [F′ laclq Tn10]φ80dlacZΔM15 Δ(lacZYA-argF)U169 recA1 endA1 hsdR17(rk−mk+) phoA supE44λ-thi-1 gyrA96 relA1. MC1061 (ATCC #53338) is E. coli K-12, F-λ-hsdR2 hsdM+ hsdS+ mcrA mcrB1 araD139 Δ(ara-leu)7696 Δ(lacIPOZY)X74 galE15 galU galK16 rpsL thi. Non-suppressor strain HB2151 is E. coli K-12 [F′proA+B+laclq lacZΔM15] ara Δ(lac-pro) thi. Chemicals were purchased from Sigma. Restriction enzymes and cloned Taq polymerase were from Fermentas. ProofStart and Pfu DNA polymerases were respectively purchased from Qiagen and Promega. Plasmid DNA, PCR and agarose-separated DNA were purified using Macherey-Nagel Nucleospin kits.
OligonucleotidesEighteen spiked oligonucleotides used to introduce degenerate CDR3 loops were synthesized and purified using high-pressure liquid chromatography (HPLC) by IBA GmbH (Goettingen, Germany). The sequences of the 18 spiked oligonucleotides is as follows. H3_n=n amino acid long VH CDR3 loop; K3_n=n amino acid long VL kappa (κ) CDR3 loop; L3_n=n amino acid long VL lambda (λ) CDR3 loop. For the degenerate positions, the percentages of the 4 bases are given as N(A/C/G/T). The proportions of each nucleotide used at each spiked (degenerate) position is shown in Table 1 below.
Other oligonucleotides use to construct the libraries were synthesized by MWG and have the following sequences:
Phagemid vector pCANTAB6 (McCafferty J et al., Appl Biochem Biotechnol 1994, 47:157-171) was used for N-terminal fusion of NcoI/NotI-scFv fragments to the minor coat protein pIII of filamentous phage M13. This phagemid is derived from pUC 119 and contains the following sequences in the following order: a lac promoter, the pelB leader sequence, NcoI and NotI sites for scFv cloning, a His6 and a c-myc tag recognized by the 9E10 monoclonal antibody, an amber codon and the pIII gene sequence.
For cytoplasmic expression of the scFvs in E. coli we used plasmid pET23NN. This plasmid is derived from pET23d(+) (Novagen) and contains a T7 promoter, followed by a NcoI site containing the ATG initiator, a NotI site followed by a c-myc and a His6 tag.
Plasmid pscFv CAT is derived from pTrc99A and contains a tac promoter, followed by a NcoI site containing the ATG initiator of an out-of-frame scFv, a NotI site followed by the CAT gene. When a scFv is inserted within the NcoI-NotI sites, the scFv is expressed as a fusion with the CAT protein. The construction was done as follows: first, the unique BstEII site of pTrc99A (A13038) was removed by digestion followed by 5′ overhang fill-in to form blunt ends, and ligation. The resulting plasmid was digested with NcoI and NotI, and the 4210 bp fragment purified (fragment I). Second, the unique NcoI site of plasmid pACYC1 84 (X06403) located within the CAT gene was removed by site directed mutagenesis by changing the Thr172 codon from ACC to ACG. Then the CAT gene was amplified by PCR using CAT-NotI.for (TAAGGCGGCCGCAATGGAGAAAAAAATCACTG; SEQ ID NO: 28) and CAT-HindIII.back (ACTGCCTTAAAAAGCTTACGCC; SEQ ID NO: 29). In the oligonucleotide sequences, the introduced restriction sites are underlined and the beginning and the end of the CAT gene are in bold-italic. The 660 bp PCR fragment was digested by NotI and HindIII, and purified (fragment II). Third, a 750 bp NcoI-NotI scFv13E6 fragment (a grafted version of the scFv13R4 containing the CDR loops of an anti-E6 monoclonal antibody. Philibert et al., to be published) was purified (fragment III). Fourth, the three fragments I, II and III were ligated to give plasmid pscFvCAT. Finally, an internal deletion of 165 bp was introduced in the scFv by removing the fragment between the two PstI sites of the gene. The resulting plasmid, called pscFvCAT, is AmpR and CAMS since the deletion of the PstI fragment resulted in a frameshift in the scFv.
Plasmid p513-EGFP is a derivative of pSG5 (Green, S., et al. Nucleic Acids Res 1988, 16:369) and harbors the EGFP coding region (Clontech, Inc.) under the control of the SV40 early promoter. The p513-scFv-EGFP constructs correspond to in frame fusions of the scFv's and the EGFP coding region with a linker of 10 residues.
The scFv coding regions were amplified with oligonucleotide primers
and inserted into the HindIII-SpeI digested p51 3-EGFP vector.
To maximize the effectiveness of the scFv library, construction of the library began with the selection of a single optimized antibody framework for intrabody selection. Through molecular evolution, a human scFv called scFv13R4 was obtained, which is expressed at high levels in E. coli cytoplasm. This scFv is also expressed and has a soluble and active conformation in both yeast and mammalian cells. This scFv is very stable in vitro and can be renatured in presence of a reducing agent. In addition, analysis of its folding kinetics showed that it folds faster than the parent scFv and aggregates more slowly in vitro. The mutations isolated are mainly located in the VH domain and seem to be highly specific to this particular scFv since they cannot be transferred to a very homologous VH domain. The nucleotide and amino acid sequences of scFv13R4 are shown below.
Release 5 (August, 1992) of the Kabat database was used (Johnson, G., and Wu, T. T.: Kabat Database and its applications: 30 years after the first variability plot. Nucleic Acids Res 2000, 28:214-218). This dataset contained 44990 sequences. First, 4643 human VH sequences which were not a pseudogene and were not humanized were extracted. H3 sequences were then extracted from this dataset, first taking into account the nucleotide sequence when present, then the amino acid sequence. Finally, the 3469 complete H3 sequences that contained only the 20 regular amino acids were kept, among which 2703 were unique. The same procedure was followed for λ and κ light chains, respectively, resulting in 1044 and 1291 sequences from which 775 and 828 were unique.
CDR3 sequences from the IMGT/LIGM-DB database as it existed on 27 Nov. 2003 were also extracted (Giudicelli, V., et al. IMGT/LIGM-DB, the IMGT(R) comprehensive database of immunoglobulin and T cell receptor nucleotide sequences. Nucleic Acids Res 2006, 34:D781-784). Only the “productive/regular/human/cDNA+RNA/rearranged” genes were considered. 5179H3, 1432 K3, and 1131 L3 sequences were obtained, of which 4323H3, 974 K3, and 812 L3 sequences were unique.
127 additional human antibody sequences were also collected from the Protein data bank (Berman, H. M., et al. The Protein Data Bank. Nucleic Acids Res 2000, 28:235-242.). For this we used the file of 510 sequences already compiled by Andrew Martin on Aug. 19, 2003 (Allcorn, L. C., and Martin, A. C. R. SACS-self-maintaining database of antibody crystal structure information. Bioinformatics 2002, 18:175-181).
Spiked Oligonucleotide DesignIn biasing the representations of the amino acids, optimized mixtures of the nucleotides at each of the three codon positions were calculated as described previously (Wang, W., and Saven, J. G. Designing gene libraries from protein profiles for combinatorial protein experiments. Nucleic Acids Res 2002, 30:e120; Park, S., et al. Progress in the development and application of computational methods for probabilistic protein design. Comput Chem Eng 2005, 29:407-421.).
Premature termination of protein sequences was limited by imposing an upper bound of 0.05 on the probability of realizing a stop codon. For the 34 positions which did not satisfactorily recover the desired probabilities of the amino acids, a second optimization was done with the same method, but with no constraint on the stop codon frequency. For oligonucleotide synthesis, the calculated frequencies were rounded in increments of 5% as follows: all the frequencies between 0% and 5% were rounded to 5%; other frequencies were rounded to the nearest 5%; if the resulting sum was higher than 100%, 5% was removed from the rounded amino acid frequency larger than 5% for which the difference between the rounded and the target frequency was maximal and the process iterated until the sum was 100%; if the sum was lower than 100%, 5% was added to the rounded frequency lower than 95%, for which the difference between the rounded and the target frequency was maximal and the process iterated until the sum was 100%.
Construction of VH and VL LibrariesVariable CDR3 sequences were introduced in scFv13R4 by PCR assembly using a hot-start proofreading polymerase (ProofStart, Qiagen) using as a template plasmid pAB1-scFv13R4p (Martineau, P., and Betton, J. M. In vitro folding and thermodynamic stability of an antibody fragment selected in vivo for high expression levels in Escherichia coli cytoplasm. J Mol Biol 1999, 292:921-929.) To introduce random H3 loops, the 5′ of the gene with the random H3 sequence was obtained with oligonucleotides M13rev-49 and one of the 13 degenerate oligonucleotides, and the 3′ was obtained with PliaisonH3 and M13uni-43 (both for 20 cycles at 55° C.). The two purified bands were thus assembled by PCR (30 cycles, 55° C.) using M13rev-49 and M13uni-43. The resulting PCR was purified using a commercial kit (Nucleospin, Macherey-Nagel), digested for 16 hours at 37° C. with NcoI and NotI enzymes, and then purified on a gel. The same procedure was followed to introduce random L3 and K3 loops except that the pairs of primers used were M13rev-49/PliaisonL3 for the 5′ and one of the degenerate oligonucleotides encoding the L3/K3 loop (K3_n or L3_n) with M13uni-43 for the 3′ part of the gene.
Each digested band was ligated for 16 hours at 16° C. with 1 μg of NcoI-NotI, digested, and purified pscFvΔCAT in 100 μl using 10 Weiss units of T4 DNA ligase. The ligation was heat inactivated and purified using a commercial kit (Nucleospin). The ligation was then electroporated in 300 μl of MC1061 competent cells (Sidhu, S. S., et al. Phage display for selection of novel binding peptides. Methods Enzymol 2000, 328:333-363) and plated on a 600 cm2 square plate of LB containing 100 μg/ml of ampicillin, then incubated for 16 hours at 37° C. The 18 libraries (13 VH and 5 VL) were scrapped in 10 ml of LB with 10% glycerol, and 109 bacteria were immediately plated on a 600 cm2 square plate of LB containing 100 μg/ml of ampicillin, 1 mM IPTG and 30 μg/ml of CAM, then incubated for 16 hours at 37° C. The 18 libraries were then scrapped in 10 ml of LB with 10% glycerol and frozen at −80° C. An aliquot was used to prepare DNA for the library assembly.
Library AssemblyThe 13 VH libraries were amplified using primers M13rev-49/PliaisonH3.back using Pfu polymerase, and the 5 VL libraries were amplified using scFvCAT.rev/H3_Liaison (30 cycles, 55° C.). The 18 PCR bands were first purified, then carefully quantified on gel using ImageJ software. The 13 VH bands were pooled in amounts proportional to their frequency in human H3. This mix was called VHpool. The 2 VL κ bands were pooled in order to obtain 75% of 9 amino acid-length loops and 25% of 10 amino acid-length loops. The VL λ bands were pooled to obtain 30% of the 9, 30% of the 10, and 40% of the 11 amino acid-length loops. Finally, the κ and λ mixes were pooled in order to get 50% of each class in the final mix called VLpool.
VHpool and VLpool were assembled by PCR using Taq DNA polymerase and primers M13rev-49/scFvCAT2.rev in 500 μl (30 cycles, 55° C.). The PCR was successively digested with 20 units of NcoI and NotI for at least 6 h each, purified, and then quantified on gel. 50 μg of vector pCANTAB6 was successively digested with 80 units of NcoI and NotI for at least 6 h each, purified then quantified on gel. 5 μg of linearized pCANTAB6 was ligated with an equal molar amount of insert (0.84 μg) in 500 μl at 16° C. using 50 Weiss units of T4 DNA ligase. The ligation was heat inactivated and purified using a commercial kit (Nucleospin). The purified ligation was then electroporated in 10×300 μl of C-Max5αF′ competent cells (Sidhu, S. S., et al. Phage display for selection of novel binding peptides. Methods Enzymol 2000, 328:333-363), and plated on ten 600 cm2 square plate of LB containing 1% of glucose and 100 μg/ml of ampicillin. After incubation for 16 h at 37° C., cells were scrapped in 2xYT containing 10% of glycerol and kept frozen at −80° C. in aliquots corresponding to twenty times the diversity.
AntigensAurora-A is an His-tagged protein and was produced in E. coli. GST:Syk was expressed in E. coli. (Dauvillier, S., et al. Intracellular single-chain variable fragments directed to the Src homology 2 domains of Syk partially inhibit Fc epsilon RI signaling in the RBL-2H3 cell line. J Immunol 2002, 169:2274-2283). E6 protein from papillomavirus HPV16 was expressed in cyanobacterium Anabaena (Desplancq et al., to be published). Histones (a mix of H2a, H2b, H3 and H4) were purchased from Sigma (type II-AS. #H7755). Tubulin was purified from pig brain (Williams, R. C. J., and Lee, J. C. Preparation of tubulin from brain. Methods Enzymol 1982, 85 (Pt B):376-385).
Library Rescue and SelectionLibrary rescue was done essentially as previously described using a trypsin-sensitive helper phage (Kristensen, P., and Winter, G. Proteolytic selection for protein folding using filamentous bacteriophages. Fold Des 1998, 3:321-328). Briefly, an aliquot of the library corresponding to a 10 to 20-fold excess over the diversity (2−3×1010 bacteria) was inoculated in 1000 ml of 2xYT containing 100 μg/ml ampicillin and 1% glucose and grown with shaking at 37° C. until OD600nm was 0.7. 200 ml (˜3×1010 cells) were infected with 5×1011 helper phage KM13 (Kristensen, P., and Winter, G. Proteolytic selection for protein folding using filamentous bacteriophages. Fold Des 1998, 3:321-328) and incubated without shaking for 30 min at 37° C. Cells were pelleted, resuspended in 1000 ml of 2xYT containing 100 μg/ml ampicillin and 25 μg/ml kanamycin and incubated overnight with vigorous shaking at 30° C. The supernatant containing phages was precipitated twice by adding ⅕th of the volume of PEG-8000 20%, NaCl 2.5 M, and resuspended in PBS supplemented with 15% of glycerol. Aliquots containing 1011-1012 phages were stored at −80° C.
To select for binders, 100 μl of purified antigens were coated in a Nunc Maxisorp 96-well plate. For the first round, an antigen concentration of 10-100 μg/ml was used. For subsequent rounds, an antigen concentration of 1-10 μg/ml was used. The plate was washed 3 times with PBS containing 0.1% of Tween20 (PBST) and saturated for 2 hours at room temperature with PBS containing 2% non-fat milk (MBPS). 1011-1012 phages were added per well in 2% MPBS and incubated for 2 hours at room temperature. The plate was washed 20 times (first round) or 40 times (2nd and 3rd rounds) with PBST, and then washed 3 times with PBS. Excess PBS was removed, and the phages were eluted by adding 100 μl of 100 mM triethylamine for 10 minutes at room temperature. The eluted phage suspension was neutralized with 50 μl of 1 M Tris-HCl pH 7.4, then digested 15 minutes at room temperature with trypsin by adding 1.5 μl of 0.1 M CaCl2 and 15 μl of 10 mg/ml TPCK-treated trypsin (Sigma). 1 ml of a 37° C. exponentially growing Cmax5αF′ strain in 2xYT was infected with 40 μl of trypsin-treated phages, incubated 30 min at 37° C. without shaking, then plated on a 15 cm round Petri dish (LB, 100 μg/ml ampicillin, 1% glucose). After overnight incubation at 37° C., bacteria were recovered from the plate and used to prepare a new stock of phages using KM13 helper phage. 1011-1012 phages of this stock were used for the next round of selection.
Periplasmic and Cytoplasmic ScreeningFor periplasmic screening, phages from round 3 were used to infect the non-suppressive strain HB2151. Individual clones were tested for scFv expression by ELISA on antigen-coated 96-well microtiter plates as described (Harrison, J. L., et al. Screening of phage antibody libraries. Methods Enzymol 1996, 267:83-109.) For cytoplasmic screening, plasmid was prepared from the pool of bacteria of the 2nd or 3rd selection round, digested with NcoI and NotI enzymes, and the 750 bp band was cloned in NcoI-NotI digested and dephosphorylated plasmid pET23NN. Ligation was transformed in C-Max5αF′, and the cells were plated on LB with 100 μg/ml ampicillin and incubated for 16 hours at 37° C. Cells were scrapped, and the plasmid DNA was prepared and used to transform chemically competent BL21(DE3) pLysS. Individual clones were grown in a 96-well microtiter plate containing 100 μl of 2xYT, 100 μg/ml of ampicillin with vigorous shaking at 37° C. until OD600nm reached 0.6. IPTG was added to 0.4 mM final and the microtiter plate was incubated for 16 hours at 24-30° C. with vigorous shaking in a humidified atmosphere. After centrifugation, cells were resuspended in 100 μl of 50 mM Tris-HCl pH7.5, 5 mM EDTA, freeze/thawed, and incubated 1 hour on ice. MgCl2 was added up to 10 mM and the DNA was digested with 10 μg/ml of DNAseI. 5-20 μl were used in an ELISA on an antigen-coated 96-well microtiter plate (Nunc Maxisorp). Revelation was done using 9E10 monoclonal antibody followed by an HRP conjugated anti-mouse IgG antibody.
Purification of scFv
scFvs cloned in plasmid pET23NN were purified from the cytoplasm of BL21(DE3) pLysS and purified on a Ni-NTA column as described for the parental scFv13R4 (Martineau, P., et al. Expression of an antibody fragment at high levels in the bacterial cytoplasm. J Mol Biol 1998, 280:117-127.).
Cell Transfection and ImmunofluorescenceHeLa cells were maintained in Dulbecco's modified Eagle's tissue culture medium (DMEM; Invitrogen) supplemented with L-glutamine (2 mM), penicillin (100 IU/ml), streptomycin (25 μg/ml) and 10% heat-inactivated fetal calf serum at 37° C. in a humidified 5% CO2 atmosphere. Transient transfection was carried out with the TransFectin lipid reagent (Bio-Rad, Hercules, Calif., USA) according to the manufacturer's instructions. Cells were seeded on coverslips in 6-well plates at 2.5×105 cells/well the day before transfection. 1 μg DNA and 2 μl of reagent diluted in 100 μl of DMEM were mixed and left at room temperature for 20 minutes. Cells were grown at 37° C. for 24 hours after addition of the mixture. The expressed GFP-tagged proteins were visualized after fixation of the transfected cells with 4% paraformaldehyde in PBS for 45 minutes at room temperature. After extensive washing with PBS, cells were dried and mounted with Fluoromount-G (SouthernBiotech, Birmingham, UK). The processed cells were examined with a Zeiss Axioplan fluorescence microscope equipped with an Olympus DP50 camera. Images were collected with a Zeiss 40× plan-neofluar objective and processed using Adobe Photoshop 5.5. For
In order to maximize the effectiveness of the scFv library, construction of the library began with the selection of a single optimized antibody framework for intrabody selection. Through molecular evolution, a human scFv called scFv13R4 was obtained, which is expressed at high levels in E. coli cytoplasm. This scFv is also expressed and has a soluble and active conformation in both yeast and mammalian cells. This scFv is very stable in vitro and can be renatured in presence of a reducing agent. In addition, analysis of its folding kinetics showed that it folds faster than the parent scFv and aggregates more slowly in vitro. The mutations isolated are mainly located in the VH domain and seem to be highly specific to this particular scFv since they cannot be transferred to a very homologous VH domain. The nucleotide and amino acid sequences of scFv13R4 are shown below.
Step 2: Introduction of Diversity into CDR3Sequences
a)Database of Human CDR3 Sequences
Human CDR3 sequences were compiled from three main sources: the Kabat database (Johnson, G. and Wu, T. T. Kabat Database and its applications: 30 years after the first variability plot. Nucleic Acids Res 2000, 28:214-218), the IMGT database (Giudicelli, V., et al. IMGT/LIGM-DB, the IMGT(R) comprehensive database of immunoglobulin and T cell receptor nucleotide sequences. Nucleic Acids Res 2006, 34:D781-784), and the RCSB PDB (Berman, H. M., et al. The Protein Data Bank. Nucleic Acids Res 2000, 28:235-242). After removing the duplicates, the database contained 5179H3, 1432 K3, and 1131 L3 CDR3 unique sequences. It can be noted that most of the H3 sequences were unique since, for instance, in the Kabat database, 2368 H3 sequences (88%) were found only once among the 2703 complete H3 sequences. The result was comparable in the case of L3 and K3 since, respectively, 87% and 82% of the sequences were unique in the Kabat database. This underlines the very high variability of the human CDR3 sequences.
This variability, however, is not evenly distributed in the loop, and the frequency of each amino acid varies from one position to another and for each loop length. In addition, the amino acid distribution depends on the origin of the antibody sequence. This bias can be due to a structural constraint as for instance in the case of the antepenultimate residue which is frequently an aspartate (D101 using Kabat numbering scheme) and plays an important role in the switch between the extended and the kinked conformation of the H3. In other cases, this bias may only be due to the limited number of sequences available for the D and J segments, and amino acids other than those found in natural antibodies may be tolerated.
For the construction of the library it was decided to make CDR3s that mimic the natural distribution for two main reasons: i) one goal was to general scFvs that would be as human as possible for possible use in human therapy; and ii) maintaining the natural amino acid distribution will be more likely result in functional antibodies.
CDR3 sequences from the database were aligned by length, and the frequency for each of the 20 possible amino acids at each position and for each loop length were calculated. In the case of the light chain CDR3s, sequences were analyzed independently for each class. In the case of the H3 sequences, this resulted in 35 tables, one for each H3 length between 1 and 34 amino acids. For a loop of length n, this table contained 20n frequencies.
b) Oligonucleotide Design for Encoding CDR3 LoopsEighteen oligonucleotides were designed to follow the amino acid distribution found in the compiled CDR3 database. One-hundred-ninety-two optimized mixes of the four nucleotides at each position of the codon were used, to match as well as possible with the desired amino acid distribution. The main advantage of this approach is that it only requires classical oligonucleotide synthesis resulting in better oligonucleotide quality. Due to the restrictions of the genetic code, however, it is not possible to follow precisely an arbitrary amino acid distribution. In addition, if the library does not strictly follow the natural amino acid distribution, this may introduce interesting non-natural diversity in the CDR3 loops.
Optimized mixes for the 249 variable positions were first calculated to match the distribution with a minimal frequency of stop codons, then 34 positions which were too distant from the target distribution were further optimized by relaxing this last constraint. Due to the constraint of the genetic code, some positions were not perfectly optimized. For instance, at position 3, alanine and glycine were under-represented in our mix and it was necessary to introduce a substantial amount of some non-naturally found amino acids like cysteine in order to match other amino acid frequencies. There was, however, a good overall agreement between the database and the oligonucleotide-encoded frequencies since the most frequently found amino acids were represented at the highest rates in the library and the rare amino acids were usually present at a low frequency. The sequences of the 18 degenerate oligonucleotides used to construct the CDR3 loops are provided above.
c) Construction of CDR3 Loop Libraries for VH and VL ChainsIndependent libraries for each CDR3 loop length were constructed. This was done independently for each of the heavy and the two classes of light chains. For each library, random CDR3 loops were introduced by PCR and the resulting library was then cloned back in the scFv13R4 gene, which was fused to the CAT gene in vector pscFvCAT. This resulted in libraries of scFv13R4 clones with one and only one randomized CDR3 loop.
The 5 amino acid long H3 loop library was constructed first. Forty-three randomly chosen clones were sequenced. Some positions diverged from the expected values of frequencies for the 20 amino acids, but on average, the distribution of amino acids in the library matched the expected distribution. This showed that the quality of the oligonucleotides was good and that the resulting library followed the natural distribution of the amino acid in human H3 loops.
As expected, not all of the clones formed from the construction of the VH and VL libraries were functional for three main reasons: i) oligonucleotides used to introduce diversity may contain stop codons; ii) stop codons or frameshifts may be introduced by the PCR and the cloning steps; or iii) the scFvs are poorly expressed in the cytoplasm. To remove these non-functional scFv clones, expressed clones were selected by fusing the scFv gene and the chloramphenicol acethyl transferase (CAT) enzyme using the method of Maxwell K L et al. (A simple in vivo assay for increased protein solubility, Protein Sci 1999; 8:1908-1911) as described below.
Creation of scFV-CAT Fusion Proteins
Briefly, the scFv libraries were independently cloned between the NcoI and NotI sites of vector pscFvCAT under the control of the tac promoter and in frame with a downstream CAT gene. The scFv-CAT fusion protein was thus expressed in the cytoplasm. If a scFv was not properly expressed because of the inclusion of a stop codon or frameshift mutation, or if it was unable to fold in the cytoplasm, the resulting scFv-CAT protein would be either not expressed or not active, resulting in a chloramphenicol sensitive (CAMS) phenotype. On the other hand, if the scFv was properly expressed, the resulting scFv-CAT protein would be well expressed in the cytoplasm, and the bacterium would be chloramphenicol resistant (CAMR). By adjusting the chloramphenicol (CAM) concentration, one can even select for expression of different solubility levels of the scFv-CAT protein.
Different CAM concentrations were tested for this selection step ranging from 15 to 200 μg/ml. At the highest concentration of CAM, the library was enriched in well-expressed scFvs, but also in clones containing recombined plasmids harboring partial or complete deletions of the scFv gene. Next, the libraries were plated on a medium CAM concentration (30 μg/ml). This concentration was high enough to remove all the non-expressed or strongly aggregating scFvs, but did not result in a detectable amount of plasmids harboring scFv deletion.
To estimate the final size of the libraries, at least 12 clones were isolated from each initial library, which was selected on ampicillin and on CAM to determine the fraction of CAMR clones. Some clones grew quickly and formed colonies on ampicillin/CAM/IPTG plates (Table 2, column ++), some grew slowly (column+), and some did not grow at all (column−). The size of the libraries of expressed scFv (selected on Amp+CAM+IPTG) was thus estimated as the product of the original library size (selected on ampicillin) by the frequency of the CAMR clones. The sizes of the 18 libraries are given in the last column of Table 2 and ranged from 2.5×106 to 1.9×108.
Step 4: Assembly of CAM-Selected LibraryThe final library was assembled by recombining the 13 CAM-selected VH libraries with the 5 CAM-selected VL libraries. The theoretical possible diversity is about 1015 (˜13 VH×107×5 VL×106). This is much larger than a library that could be obtained by electroporation. It is thus very unlikely to obtain twice the same clone in the final library.
The 13 VH and 5 VL libraries were amplified by PCR with an overlapping sequence of 17 nucleotides, then purified and quantified on agarose gel. The VH and VL purified fragments were then pooled in amounts proportional to the natural distribution of the CDR3 loop lengths in human antibodies (
One hundred and eighteen clones were sequenced to determine loop lengths and sequences. Almost all loop lengths were found in the library. 11 and 16 amino acid long loops were also under-represented in the library. This is presumably due to the poor quality of these oligonucleotides as shown by their profile on an Agilent Bioanalizer. Loop lengths ranging from 7 to 12 were over-represented in the library but only by a two-fold factor. The loop lengths between 8 and 17 amino acids, which are the most frequently found in human antibodies, were all present in the library. The number of sequenced clones was too small to analyze the frequency of the amino acids found in the CDR3 loops. Except for some contamination with the original scFv13R4 sequence, no CDR3 sequence was found twice in the library.
Expression of scFvs in the Cell
Because of the novel use of the CAM selection step, the VH and VL libraries were independently optimized for expression in the cell. Because of this optimization of the VH and VL libraries the result should be only expressed scFv proteins. Furthermore, since only the CDR3 loops are modified between the original scFv13R4 antibody framework and the resulting scFv libraries, most of the interface residues between the two domains are conserved between clones. It is thus likely that any VH will assemble correctly with any VL and that the expression level of the resulting scFv will be close to that of both clones from the VH and VL libraries selected on CAM. In other words, if a VH, with a modified H3 loop, is well expressed when fused to the VL13R4, it will be also well expressed when coupled with a VL with a modified CDR3 loop and selected as a fusion with the VH1 3R4. This hypothesis was tested by picking random clones from the final library and expressing them in E. coli cytoplasm and in mammalian cytosol.
DNA was prepared from the final library and the scFv genes cloned in a plasmid for cytoplasmic expression under the control of the strong T7 promoter. It must be noted that the very high expression levels obtained under such a strong promoter favor aggregation over soluble expression because of the high kinetics order of the aggregation process. The stringency of this test is thus high and it could be possible to increase the soluble versus insoluble ratio by using a weaker promoter. Twenty clones were tested in E. coli and 19 of them showed at least some soluble expression in the cytoplasm (
Next, the expression of the library in mammalian cells was tested. Fifteen scFvs were cloned in a mammalian expression vector as fusions with the EGFP gene and under the control of the SV40 early promoter, then transfected in HeLa cells. Typical results are shown in
Together, these results showed that more than 85% of the clones from the final library expressed soluble scFv in E. coli (16/20) and mammalian cytoplasm (13/15), while about 20% of them expressed scFv at a very high level (5/20 in E. coli and 3/15 in eukaryotic cells). Overall, most of the clones were well expressed under the reducing conditions of the bacterial and eukaryotic cytoplasm. This is a great improvement over results previously obtained with non-optimized scFv libraries.
Selection of BindersAs shown above, the library contains a very high proportion of expressed clones. The next step was selecting antibodies from the library against particular proteins. Thus, the phage display library was used to select for binders against five different antigens using purified proteins adsorbed on microtiter plates. Three rounds of selection were performed, and the eluted phages were tested by ELISA against the immobilized antigens. In all the cases a positive signal was obtained after a single round of selection. This signal increased strongly after two rounds and did not increase further during the third round of selection. This very fast selection process was presumably due both to the focused library itself, which contains only expressed scFvs resulting in a low background, and to the use of a trypsin sensitive helper phage that further decreased the background level.
To characterize the selection process, 60 clones were selected from the three selection rounds against GST:Syk fusion. These clones were used to prepare monoclonal phages, which were then tested for binding to the antigen by ELISA.
Next tested was whether the library contained clones expressing soluble scFvs in the periplasm. The non-suppressive HB2151 strain was infected with the phages eluted after the third round of selection against tubulin, GST:Syk and the core histones. Periplasmic extracts were prepared and tested for binding activity by ELISA. In the three cases, 12-20% of the clones gave a strong signal with absorbance values higher than 0.5 (10 times the background), and about 30% were clearly positive with an absorbance value higher than 0.1 (twice the background). These results compared favorably with those reported with other scFv libraries, underlining again the high proportion of well-expressed clones present in the library. In addition, this showed that the CAM-selection approach selected efficiently for constructs without stop codons present in the oligonucleotides. This is indeed of premium importance to isolate soluble scFvs from phage-displayed libraries since amber stop codons in CDRs are frequently selected during panning of synthetic and semi-synthetic libraries.
In both the previous characterizations, the scFvs were expressed under oxidizing conditions in E. coli periplasm, either as scFv-pIII fusion or as soluble protein. In addition, panning was done on phage, again under oxidizing conditions. To test whether the scFvs were indeed also expressed in the cytoplasm, the same pool of clones (Round 3) was subcloned in a cytoplasmic expression vector under the control of the strong T7 promoter. For each antigen, ninety-five clones were tested by ELISA for binding to their respective antigen. In each case, the number of positive clones was comparable or even better than in the periplasmic screen. For instance, in the case of GST: Syk, 80% of the tested clones were positive after three rounds of selection. This demonstrated that the periplasmic selection step did not decrease the proportion of soluble scFvs in the cytoplasm. Furthermore, when using the optimized library as described above it is not necessary to directly select within the cytoplasm to avoid introducing a bias during the selection.
Individual clones from the 2nd and the 3rd round of selection against tubulin were sequenced. Sequences are shown in Table 3.
In all cases, the clones sequenced were those giving the best signal in the ELISA performed with cytoplasmically expressed scFvs. Most of the clones were different since only one clone from the 2nd round and one from the 3rd round were found twice. This demonstrated that a high diversity is still present after 3 rounds of selection. Eight of the anti-tubulin scFvs were purified by affinity chromatography from the cytoplasm. In all cases, more than 8 mg of scFv was purified from one liter of cells grown in a flask (OD600=5), and some scFvs were expressed at a level per cell comparable to the exceptionally high expression level reported for an anti-HER2 in E. coli periplasm.
Functionality of scFvs as Intrabodies
To determine if the isolated scFvs were able to bind to their target in vivo, the anti-histone scFvs expressed in human cells was characterized. The third round of selection was cloned in vector p513-EGFP and ten randomly chosen clones were transfected in HeLa cells. Typical results of the cells expressing the scFv-EGFP fusions and observed by fluorescence microscopy are shown in
In Vitro Characterization of Anti-Tubulin scFvs
To demonstrate the activity of the anti-tubulin scFv under the reducing conditions in the cell cytoplasm, the scFvs were extracted in the presence of a reducing agent and compared the ELISA signal with that obtained with the scFvs extracted under oxidizing conditions. As shown in
Altogether our results show that the library described in this report is highly diverse and functional and allows fast and easy isolation of in vivo active fully human intrabodies.
All patents, publications and abstracts cited above are incorporated herein by reference in their entirety. Although only a few embodiments of the present invention have been described herein, it should be understood that the present invention can be embodied in many other specific forms without departing from the spirit or scope of the invention as claimed herein. Accordingly, the present examples and embodiments are to be considered as illustrative and not restrictive, and the invention is not to be limited to the details given herein.
Claims
1. An antibody library that comprises at least about 106 unique scFv clones, wherein at least about 20% of the scFv clones encode an antibody that can detectably specifically bind a target antigen within a cell when the antibody encoded by the scFv clone is expressed within the cell.
2. An antibody library, wherein the antibody library comprises at least about 106 unique scFv antibody clones, wherein at least about 20% of the scFv antibody clones can be expressed within an E. coli cell to produce soluble antibody at a level of at least about 5 mgs per liter of E. coli cells, wherein the E coli cells have been grown to an OD600nm nm of about 5.
3. The antibody library comprising at least about 106 unique scFv antibody clones, wherein each unique scFv antibody clone encodes a unique scFv antibody comprising at least one of a unique CDR3 VH sequence and a unique CDR3 VL sequence, and wherein the unique scFv antibody clones encode a framework sequence substantially identical to a framework sequence encoded by scFv13R4.
4. The antibody library of claim 3, wherein the unique scFv antibody clones encode scFv antibodies comprising a unique CDR3 VH sequence.
5. The antibody library of claim 3, wherein the unique scFv antibody clones encode scFv antibodies comprising a unique CDR3 VL sequence.
6. The antibody library of claim 3, wherein the unique scFv antibody clones encode scFv antibodies comprising a unique CDR3 VH sequence and a unique CDR3 VL sequence.
7. An scFv antibody that can be expressed as substantially soluble protein under reducing conditions, wherein the scFv antibody is isolated from the library of claim 3.
8. The scFv antibody of claim 7, wherein the scFv antibody can specifically bind to a target antigen under reducing conditions.
9. A method for preparing an scFv antibody library enriched for scFv antibody clones that can be expressed within a cell, comprising: thereby preparing the scFv antibody library enriched for scFv antibody clones that can be expressed within a cell.
- a) providing a first collection of scFv antibody clones, wherein the first collection comprises clones comprising a unique sequence within a CDR3 loop of VH, wherein the first collection has been enriched for scFv antibody clones that can be detectably expressed when introduced into a cell;
- b) providing a second collection of scFv antibody clones, wherein the second collection comprises clones comprising a unique sequence within a CDR3 loop of VL, wherein the second collection has been enriched for scFv antibody clones that can be detectably expressed when introduced into a cell;
- c) joining VH domains from scFv antibody clones of the first collection with VL domains from scFv antibody clones of the second collection to obtain a third collection of scFv antibody clones, wherein the third collection contains scFv antibody clones comprising a unique sequence within the CDR3 loop of VH and a unique sequence within the CDR3 loop of VL,
10. The method of claim 9, wherein the first collection comprises scFv antibody clones that contain a substantially identical VL sequence relative to other scFv antibody clones in the first collection, and wherein the second collection comprises scFv antibody clones that contain a substantially identical VH sequence relative to other scFv antibody clones in the second collection.
11. The method of claim 9, wherein the first collection comprises scFv antibody clones that contain a VL sequence substantially identical to an scFv13R4 VL sequence and wherein the second collection comprises scFv antibody clones that contain a VH sequence substantially identical to an scFv13R4 VH sequence.
12. The method of claim 9, wherein the first collection comprises scFv antibody clones that comprise identical CDR1 and CDR2 sequences in the VH domain and wherein the second collection comprises scFv antibody clones that comprise identical CDR1 and CDR2 sequences in the VL domain.
13. An antibody library produced by the method of claim 9.
14. An antibody selected from an antibody library produced by the method of claim 9.
Type: Application
Filed: Mar 17, 2008
Publication Date: Jun 4, 2009
Inventors: Pierre Emile Ulysse Martineau (Saint Gely du Fesc), Etienne Weiss (Fegersheim)
Application Number: 12/049,683
International Classification: C40B 40/10 (20060101); C40B 50/06 (20060101); C07K 16/00 (20060101);
