Fully synthetic human combinatorial antibody libraries (HuCAL) based on modular consensus frameworks and CDRs randomized with trinucleotides

A novel strategy to design binding molecules harnessing the modular nature of repeat proteins

Repeat proteins, such as ankyrin or leucine-rich repeat proteins, are ubiquitous binding molecules, which occur, unlike antibodies, intra- and extracellularly. Their unique modular architecture features repeating structural units (repeats), which stack together to form elongated repeat domains displaying variable and modular target-binding surfaces. Based on this modularity, we developed a novel strategy to generate combinatorial libraries of polypeptides with highly diversified binding specificities. This strategy includes the consensus design of self-compatible repeats displaying variable surface residues and their random assembly into repeat domains. We envision that such repeat protein libraries will be highly valuable sources for novel binding molecules especially suitable for intracellular applications.

A new helper phage and phagemid vector system improves viral display of antibody Fab fragments and avoids propagation of insert-less virions

Phage display technology (PDT) is a powerful method for isolating functional gene products such as antigen-specific monoclonal antibodies (mAbs). To improve the effectiveness of PDT, we sought to optimize display of Fab-g3p (antibody fragment fused with viral gene 3 protein) on phagemid virions and to optimize the yield of such phage. To do so, we constructed a novel helper phage, Phaberge, having a conditional deficiency in g3p production. Unlike most other published g3p-deficient helper phage, Phaberge is produced at high levels, 10(11) PFU/ml. As compared to g3p-sufficient helper phage, Phaberge caused a 5-20-fold increase in display level. Another novel feature is that Phaberge only packages insert-containing, not insert-less, phagemid into infectious virions. This should prove useful in preserving quality of phagemid libraries during propagation. In addition, other parameters were also found to affect production of phagemid virions. In particular, the choice of bacterial host cell, phagemid construct and growth temperature had a substantial impact on display levels, but generally no effect on number of phagemid virions produced. In short, we have established a set of parameters that improve production and quality of phagemid virions which we expect to facilitate the isolation of mAbs or other gene products by PDT.

Designed to be stable: crystal structure of a consensus ankyrin repeat protein

Ankyrin repeat (AR) proteins mediate innumerable protein-protein interactions in virtually all phyla. This finding suggested the use of AR proteins as designed binding molecules. Based on sequence and structural analyses, we designed a consensus AR with fixed framework and randomized interacting residues. We generated several combinatorial libraries of AR proteins consisting of defined numbers of this repeat. Randomly chosen library members are expressed in soluble form in the cytoplasm of Escherichia coli constituting up to 30% of total cellular protein and show high thermodynamic stability. We determined the crystal structure of one of those library members to 2.0-A resolution, providing insight into the consensus AR fold. Besides the highly complementary hydrophobic repeat-repeat interfaces and the absence of structural irregularities in the consensus AR protein, the regular and extended hydrogen bond networks in the beta-turn and loop regions are noteworthy. Furthermore, all residues found in the turn region of the Ramachandran plot are glycines. Many of these features also occur in natural AR proteins, but not in this rigorous and standardized fashion. We conclude that the AR domain fold is an intrinsically very stable and well-expressed scaffold, able to display randomized interacting residues. This scaffold represents an excellent basis for the design of novel binding molecules.

Structure-based improvement of the biophysical properties of immunoglobulin VH domains with a generalizable approach

In a systematic study of V gene families carried out with consensus V(H) and V(L) domains alone and in combinations in the scFv format, we found comparatively low expression yields and lower cooperativity in equilibrium unfolding in antibody fragments containing V(H) domains of human germline families 2, 4, and 6. From an analysis of the packing of the hydrophobic core, the completeness of charge clusters, the occurrence of unsatisfied hydrogen bonds, and residues with low beta-sheet propensities, positive Phi angles, and exposed hydrophobic side chains, we pinpointed residues potentially responsible for the unsatisfactory properties of these germline-encoded sequences. Several of those are in common between the domains of the even-numbered subgroups, but do not occur in the odd-numbered ones. In this study, we have systematically exchanged those residues alone and in combination in two different scFvs using the V(H)6 framework, and we describe their effect on equilibrium stability and folding yield. We improved the stability by 20.9 kJ/mol and the expression yield by a factor of 4 and can now use these data to rationally engineer antibodies derived from this and similar germline families for better biophysical properties. Furthermore, we provide an improved design for libraries exploiting the significant additional diversity provided by these frameworks. Both antibodies studied here completely retain their binding affinity, demonstrating that the CDR conformations were not affected.

Deriving topological constraints from functional data for the design of reagentless fluorescent immunosensors

The possibility of obtaining, from any antibody, a fluorescent conjugate which responds to the binding of the antigen by a variation of fluorescence, would be of great interest in the micro- and nano-analytical sciences. This possibility was explored with antibody mAb4E11, which is directed against the dengue virus and for which no structural data is available. Three rules of design were developed to identify residues of the antibody to which a fluorophore could be chemically coupled, after changing them to cysteine by mutagenesis. (i) The target residue belonged to the hypervariable loops of the antibody. (ii) It was adjacent, along the amino acid sequence of the antibody, to a residue which was functionally important for the interaction with the antigen. (iii) It was not important in itself for the interaction with the antigen. Eight conjugates between a single chain variable fragment of mAb4E11 and an environment-sensitive fluorophore were constructed. Three of them showed an increase in their fluorescence intensity by 1.5-2.8-fold on antigen binding, without loss of affinity. This increase allowed the titration of the antigen in serum above a threshold concentration of 10nM. Experiments of quenching with potassium iodide suggested that the fluorescence variation was due to a shielding of the fluorescent group from the solvent by the binding of the antigen, and that therefore its mechanism is general.

Potent and selective inhibition of membrane-type serine protease 1 by human single-chain antibodies

Specific human antibodies targeting proteases expressed on cancer cells can be valuable reagents for diagnosis, prognosis, and therapy of cancer. To this end, a phage-displayed antibody library was screened against a cancer-associated serine protease, MT-SP1. A protein inhibitor of serine proteases that binds to a defined surface of MT-SP1 was used in an affinity-based washing procedure. Six antibodies were selected on the basis of their ELISA profiles and ability to serve as useful immunological reagents. The apparent K(i), indicative of the potency of the antibodies at inhibiting human MT-SP1 activity, ranged from 50 pM to 129 nM. Two of the antibodies had approximately 800-fold and 1500-fold selectivity when tested against the most homologous serine protease family member, mouse MT-SP1, that exhibits 86.6% sequence identity. Surface plasmon resonance was used as an independent means of determining the binding constants of the six antibodies. Association rates were as high as 1.15 x 10(7) s(-)(1) M(-)(1), and dissociation rates were as low as 3.8 x 10(-)(4) s(-)(1). One antibody was shown to detect denatured MT-SP1 with no cross reactivity to other family members in HeLa or PC3 cells. Another antibody recognized the enzyme in human prostate tissue samples for immunohistochemistry analysis. The mode of binding among the six antibodies and the protease was analyzed by competition ELISA using three distinctly different inhibitors that mapped the enzyme surface. These antibodies constitute a new class of highly selective protease inhibitors that can be used to dissect the biological roles of proteolytic enzymes as well as to develop diagnostic and therapeutic reagents.

Flow-cytometric isolation of human antibodies from a nonimmune Saccharomyces cerevisiae surface display library

A nonimmune library of 10(9) human antibody scFv fragments has been cloned and expressed on the surface of yeast, and nanomolar-affinity scFvs routinely obtained by magnetic bead screening and flow-cytometric sorting. The yeast library can be amplified 10(10)-fold without measurable loss of clonal diversity, allowing its effectively indefinite expansion. The expression, stability, and antigen-binding properties of >50 isolated scFv clones were assessed directly on the yeast cell surface by immunofluorescent labeling and flow cytometry, obviating separate subcloning, expression, and purification steps and thereby expediting the isolation of novel affinity reagents. The ability to use multiplex library screening demonstrates the usefulness of this approach for high-throughput antibody isolation for proteomics applications.

Optimization of protein therapeutics by directed evolution

Directed evolution is a broadly applicable technology platform that is ideally suited to address the need for protein optimization and to fully exploit the therapeutic potential of biologics. The approach takes advantage of the remarkable structural and functional plasticity of proteins and permits the rapid remodeling of biologics into new entities with improved functions. The ability to ameliorate virtually any characteristic of a protein can translate into significant clinical benefits, including decreased immunogenicity, higher potency, greater efficacy and improved safety profile, and can considerably increase the probability of successfully developing and commercializing biotherapeutics.

Biophysical properties of human antibody variable domains

There are great demands on the stability, expression yield and resistance to aggregation of antibody fragments. To untangle intrinsic domain effects from domain interactions, we present first a systematic evaluation of the isolated human immunoglobulin variable heavy (V(H)) and light (V(L)) germline family consensus domains and then a systematic series of V(H)-V(L) combinations in the scFv format. The constructs were evaluated in terms of their expression behavior, oligomeric state in solution and denaturant-induced unfolding equilibria under non-reducing conditions. The seven V(H) and seven V(L) domains represent the consensus sequences of the major human germline subclasses, derived from the Human Combinatorial Antibody Library (HuCAL). The isolated V(H) and V(L) domains with the highest thermodynamic stability and yield of soluble protein were V(H)3 and V(kappa)3, respectively. Similar measurements on all domain combinations in scFv fragments allowed the scFv fragments to be classified according to thermodynamic stability and in vivo folding yield. The scFv fragments containing the variable domain combinations H3kappa3, H1bkappa3, H5kappa3 and H3kappa1 show superior properties concerning yield and stability. Domain interactions diminish the intrinsic differences of the domains. ScFv fragments containing V(lambda) domains show high levels of stability, even though V(lambda) domains are surprisingly unstable by themselves. This is due to a strong interaction with the V(H) domain and depends on the amino acid sequence of the CDR-L3. On the basis of these analyses and model structures, we suggest possibilities for further improvement of the biophysical properties of individual frameworks and give recommendations for library design.

Colony lift assay using cell-coated filters: a fast and efficient method to screen phage libraries for cell-binding clones

For efficient screening of phage antibody libraries obtained by selection on whole cells, we have developed a modified colony lift assay using cell-coated filters. Both cells growing in suspension as well as adherent cells can be coated onto nitrocellulose filters and used to detect bacterial colonies responsible for the production of cell-binding (specific) single chain variable fragment (scFv) antibodies. We demonstrate, using a selected library developed in our laboratory (named "AB" library) as a model system, that the frequency of specific clones as detected by colony lift assay using cell-coated filter is comparable to the frequency of positive clones as detected by the "classical" method (i.e. random picking and flow cytometric analysis). However, the colony lift assay enables detection and isolation of a higher number of specific clones as compared to the random pick. This is due to screening of a much higher number of clones simultaneously (it is possible to screen at least 1000 clones plated on one 9-cm agar dish). Using this method, clones occurring at a low frequency (such as present in early selection rounds) can be detected and isolated efficiently. We clearly demonstrate the usefulness of the colony lift assay with cell-coated filter by applying it to screen the head-and-neck carcinoma (HN) library (a selected library generated in our laboratory). Using the assay, but not the random picking, we were able to isolate specific clones from 2nd to 3rd selection rounds of the HN library.

Analysis of the antigen combining site: correlations between length and sequence composition of the hypervariable loops and the nature of the antigen

It has long been suggested that the overall shape of the antigen combining site (ACS) of antibodies is correlated with the nature of the antigen. For example, deep pockets are characteristic of antibodies that bind haptens, grooves indicate peptide binders, while antibodies that bind to proteins have relatively flat combining sites. In 1996, MacCallum, Martin and Thornton used a fractal shape descriptor and showed a strong correlation of the shape of the binding region with the general nature of the antigen.However, the shape of the ACS is determined primarily by the lengths of the six complementarity-determining regions (CDRs). Here, we make a direct correlation between the lengths of the CDRs and the nature of the antigen. In addition, we show significant differences in the residue composition of the CDRs of antibodies that bind to different antigen classes. As well as helping us to understand the process of antigen recognition, autoimmune disease and cross-reactivity, these results are of direct application in the design of antibody phage libraries and modification of affinity.

The role of somatic mutation in determining the affinity of anti-DNA antibodies

Combinatorial antibody libraries were constructed from the spleen of a patient with concomitant systemic lupus erythematosus and idiopathic thrombocytopenia. Following selection of the libraries with DNA, a panel of 15 anti-DNA Fabs was isolated. Sequence analysis of these antibodies coupled with measurements of their affinities for ss- and dsDNA were used to investigate the role of somatic mutation in affinity maturation of the anti-DNA response. Examination of the germline genes used by these Fabs supports previous studies that suggest there is no restriction of the gene usage in the anti-DNA response. However, data are presented indicating that VH3 genes and the A27 V(kappa) paired with the J(kappa)1 may be over-expressed in the anti-DNA repertoire. Analysis of the role of somatic mutation in increasing affinity for DNA indicates that affinity maturation has occurred and suggests that the CDR1 and CDR2 of the heavy chain are of importance in this process.

Biochips beyond DNA: technologies and applications

Technological advances in miniaturization have found a niche in biology and signal the beginning of a new revolution. Most of the attention and advances have been made with DNA chips yet a lot of progress is being made in the use of other biomolecules and cells. A variety of reviews have covered only different aspects and technologies but leading to the shared terminology of "biochips." This review provides a basic introduction and an in-depth survey of the different technologies and applications involving the use of non-DNA molecules such as proteins and cells. The review focuses on microarrays and microfluidics, but also describes some cellular systems (studies involving patterning and sensor chips) and nanotechnology. The principles of each technology including parameters involved in biochip design and operation are outlined. A discussion of the different biological and biomedical applications illustrates the significance of biochips in biotechnology.

Modifying specificity of antidigoxin antibodies using insertional mutagenesis

Certain antibodies (Abs) elicited using the cardiac glycoside digoxin (digoxigenin tridigitoxoside) bind preferentially to analogs that differ from digoxin by substitutions on the cardenolide rings, the lactone, or by the presence or absence of attached sugars. Antibody 26-10 binds equally well to digoxin and digitoxin, which differ only by the presence in the former and the absence in the latter of an hydroxyl group at C12. Other antidigoxin Abs, however, can distinguish between these ligands by three orders of magnitude in binding. Inspection of the structure of Fab 26-10 complexed with digoxin shows a gap in complementarity in the region between the digoxin O12 and LCDR3. We proposed that insertions in LCDR3 might result in Abs that bind digitoxin preferentially. We produced libraries of mutants displayed on bacteriophage which were randomized at LCDR3 and contained LCDR3 insertions. Mutants were selected by panning against digoxin and analogs. The mutants bound digitoxin preferentially up to 47-fold greater than digoxin. The mutants that bound well to digitoxin demonstrated a consensus sequence including the substitution of Trp at position L:94. Using site-directed mutagenesis, the binding to digitoxin was shown to be maximized by the combination of an insertion and L:Trp94 mutation, moving the L 94 side chain closer to digoxin. We also selected mutants that bound preferentially to gitoxin, which, like digitoxin, lacks the 12-hydroxyl, increasing relative binding to gitoxin up to 600-fold compared to the unmutated Ab 26-10.

Antibody discovery: phage display

Phage display has proven to be a robust and convenient technology for the selection of high-quality human antibodies from diverse libraries. Besides enabling the identification of antibodies in a fast, high-throughput mode, which allows comprehensive protein expression analyses, phage display has been used to identify a fully human therapeutic antibody presently undergoing the regulatory process for market approval.

Functional improvement of antibody fragments using a novel phage coat protein III fusion system

Functional expressions of proteins often depend on the presence of host specific factors. Frequently recombinant expression strategies of proteins in foreign hosts, such as bacteria, have been associated with poor yields or significant loss of functionality. Improvements in the performance of heterologous expression systems will benefit present-day quests in structural and functional genomics where high amounts of active protein are required. One example, which has been the subject of considerable interest, is recombinant antibodies or fragments thereof as expressions of these in bacteria constitute an easy and inexpensive method compared to hybridoma cultures. Such approaches have, however, often suffered from low yields and poor functionality. A general method is described here which enables expressions of functional antibody fragments when fused to the amino-terminal domain(s) of the filamentous phage coat protein III. Furthermore, it will be shown that the observed effect is neither due to improved stability nor increased avidity.

Applications of recombinant antibodies in plant pathology

Summary Advances in molecular biology have made it possible to produce antibody fragments comprising the binding domains of antibody molecules in diverse heterologous systems, such as Escherichia coli, insect cells, or plants. Antibody fragments specific for a wide range of antigens, including plant pathogens, have been obtained by cloning V-genes from lymphoid tissue, or by selection from large naive phage display libraries, thus avoiding the need for immunization. The antibody fragments have been expressed as fusion proteins to create different functional molecules, and fully recombinant assays have been devised to detect plant viruses. The defined binding properties and unlimited cheap supply of antibody fusion proteins make them useful components of standardized immunoassays. The expression of antibody fragments in plants was shown to confer resistance to several plant pathogens. However, the antibodies usually only slowed the progress of infection and durable 'plantibody' resistance has yet to be demonstrated. In future, it is anticipated that antibody fragments from large libraries will be essential tools in high-throughput approaches to post-genomics research, such as the assignment of gene function, characterization of spatio-temporal patterns of protein expression, and elucidation of protein-protein interactions.

Protein microarray technology

Microarray technology allows the simultaneous analysis of thousands of parameters within a single experiment. Microspots of capture molecules are immobilised in rows and columns onto a solid support and exposed to samples containing the corresponding binding molecules. Readout systems based on fluorescence, chemiluminescence, mass spectrometry, radioactivity or electrochemistry can be used to detect complex formation within each microspot. Such miniaturised and parallelised binding assays can be highly sensitive, and the extraordinary power of the method is exemplified by array-based gene expression analysis. In these systems, arrays containing immobilised DNA probes are exposed to complementary targets and the degree of hybridisation is measured. Recent developments in the field of protein microarrays show applications for enzyme-substrate, DNA-protein and different types of protein-protein interactions. This article discusses theoretical advantages and limitations of any miniaturised capture-molecule-ligand assay system and discusses how the use of protein microarrays will change diagnostic methods and genome and proteome research.

Fully human, HLA-DR-specific monoclonal antibodies efficiently induce programmed death of malignant lymphoid cells

The Human Combinatorial Antibody Library (HuCAL) was screened for antibodies specific to human leukocyte antigen-DR (HLA-DR) that induce programmed death of lymphoma/leukemia cells expressing the target antigen. The active Fab fragments were affinity-matured, and engineered to IgG(4) antibodies of sub-nanomolar affinity. The antibodies exhibited potent in vitro tumoricidal activity on several lymphoma and leukemia cell lines and on chronic lymphocytic leukemia patient samples. They were also active in vivo in xenograft models of non-Hodgkin lymphoma. Cell death occurred rapidly, without the need for exogenous immunological effector mechanisms, and was selective to activated/tumor-transformed cells. Although the expression of HLA-DR on normal hematopoietic cells is a potential safety concern, the antibodies caused no long-lasting hematological toxicity in primates, in vivo. Such monoclonal antibodies offer the potential for a novel therapeutic approach to lymphoid malignancies.

Improving broad specificity hapten recognition with protein engineering

Sulfa antibiotics (sulfonamides) are derivatives of p-aminobenzenesulfonamide that are widely used in veterinary medicine. Foods derived from treated animals may be contaminated with these drugs. However, current immunobased sulfonamide detection methods are unfit for screening of products because they are either too insensitive or specific for a few compounds only. An immunoassay capable of detecting all sulfas in a single reaction would be ideal for screening. For development of a binder capable of binding all sulfas, a protein engineering approach was chosen and the properties of monoclonal antibody 27G3 were improved with mutagenesis followed by selection with phage display. Several different mutant antibodies were isolated. The cross-reaction profile of the best mutant antibody was significantly improved over that of the wild-type antibody: it was capable of binding 9 of the tested 13 sulfonamides within a narrow concentration range and also bound the rest of the sulfas, albeit within a wider concentration range.

Selection of human antibody fragments on the basis of stabilization of the variable domain in the presence of target antigens

Here we report a novel method for selecting human antibody fragments from nonimmunized variable domain libraries. The antibody fragments are selected on the basis of stabilization of the variable domain fragment (F(v)) in the presence of target antigens ("open sandwich selection"). One variable domain is displayed on phages and another is prepared as soluble molecules. These two reagents are mixed with the biotinylated target molecule and ternary complexes are captured by using streptavidin-conjugated magnet beads. After extensive washing, enriched clones are eluted by using target antigen. Some of the clones selected after 3 rounds are prepared as soluble domains, which then undergo another selection process. We obtained several human antibody fragments specific for human soluble erythropoietin receptor by using this method. Our method minimizes several of the disadvantages associated with human antibody selection through a phage-display system, such as construction of a large-scale library, deletion of genes during selection, and nonspecific binding.

In vitro selection as a powerful tool for the applied evolution of proteins and peptides

New in vitro methods for the applied evolution of protein structure and function complement conventional cellular and phage-based methods. Strategies employing the direct physical linkage of genotype and phenotype, and the compartmental association of gene and product to select desired properties are discussed, and recent useful applications are described. Engineering of antibodies and other proteins, selection from cDNA libraries, and the creation of functional protein domains from completely random starting sequences illustrate the value of the in vitro approaches. Also discussed is an emerging new direction for in vitro display technology: the self-assembly of protein arrays.

Optimized production of the Diels-Alderase antibody 1E9 as a chimeric Fab

Monoclonal antibody 1E9, which catalyzes the [4+2] cycloaddition between tetrachlorothiophene dioxide and N-ethylmaleimide, has been re-engineered for production as a chimeric human–murine Fab fragment in Escherichia coli. Stabilizing point mutations in the variable regions of the antibody were identified by replacing residues that rarely occur at individual positions in aligned immunoglobulin sequences with their consensus counterparts. By combining favorable substitutions, double (MetH87Thr–GlyL63Ser) and triple (MetH87Thr–GlyL63Ser–PheL95Pro) mutants were created, which can be produced in good yield (4 and 17 mg L–1cell culture, respectively). The triple mutant exhibits a modest fourfold drop in the apparent kcatvalue for the cycloaddition reaction, but the kinetic properties of the double mutant are indistinguishable from those of the parent murine IgG. The availability of recombinant versions of this catalytic antibody will facilitate efforts to determine the origins of its selectivity and catalytic efficiency through mutagenesis.Key words: catalytic antibody, Fab fragment, bacterial production.

In vitro affinity maturation of human IgM antibodies reactive with tumor-associated antigens

Human lymphocytes secreting tumor cell-specific IgM antibodies were enriched in vitro following the stimulation of allogeneic human splenocytes from nontumor-bearing donors with cytostatic tumor cells or tumor cell plasma membrane fractions. The antibodies were generally of the IgM class and displayed low intrinsic affinity (K(d) > 100 nM). Nonetheless, the avidity arising from multivalent binding sites permitted the identification of multiple monoclonal antibodies (MAbs) displaying specificity for cultured tumor cells. Five antibodies were cloned from the B cells and two of these were expressed as human Fabs with IgG(1) constant regions. Although the avidity of the human IgM antibodies was sufficient to permit detection in the original screening, the monovalent Fabs displayed low binding activities, consistent with their low intrinsic affinity. Thus, in vitro affinity maturation was used to rapidly generate multiple variants of both antibodies displaying greater than 100-fold higher affinity. Two of the antibodies were characterized further and shown to have distinct specificities. One of the targets, LH11238, is associated both with the plasma membrane and with lysosomes and is rapidly internalized following incubation of the antibody with intact live cell monolayers. The second antigen, designated LH13, is a secreted antigen that has been enriched 200-fold from conditioned media and consists of two reactive bands at 42 and 45 kDa on denaturing Western blots. The stimulation and enrichment of human lymphocytes in culture coupled with rapid in vitro affinity maturation of low affinity antibodies potentially enables the discovery of human antibodies to a broader range of epitopes, including those that might be of greater therapeutic relevance.

Protein microarray technology

Microarray technology allows the simultaneous analysis of thousands of parameters within a single experiment. Microspots of capture molecules are immobilized in rows and columns onto a solid support and exposed to samples containing the corresponding binding molecules. Readout systems based on fluorescence, chemiluminescence, mass spectrometry, radioactivity or electrochemistry can be used to detect complex formation within each microspot. Such miniaturized and parallelized binding assays can be highly sensitive, and the extraordinary power of the method is exemplified by array-based gene expression analysis. In these systems, arrays containing immobilized DNA probes are exposed to complementary targets and the degree of hybridization is measured. Recent developments in the field of protein microarrays show applications for enzyme-substrate, DNA-protein and different types of protein-protein interactions. Here, we discuss theoretical advantages and limitations of any miniaturized capture-molecule-ligand assay system and discusses how the use of protein microarrays will change diagnostic methods and genome and proteome research.

Biophysical properties of camelid V(HH) domains compared to those of human V(H)3 domains

Camelidae possess an unusual form of antibodies lacking the light chains. The variable domain of these heavy chain antibodies (V(HH)) is not paired, while the V(H) domain of all other antibodies forms a heterodimer with the variable domain of the light chain (V(L)), held together by a hydrophobic interface. Here, we analyzed the biophysical properties of four camelid V(HH) fragments (H14, AMD9, RN05, and CA05) and two human consensus V(H)3 domains with different CDR3 loops to gain insight into factors determining stability and aggregation of immunoglobulin domains. We show by denaturant-induced unfolding equilibria that the free energies of unfolding of V(HH) fragments are characterized by Delta G(N-U) values between 21.1 and 35.0 kJ/mol and thus lie in the upper range of values for V(H) fragments from murine and human antibodies. Nevertheless, the V(HH) fragments studied here did not reach the high values between 39.7 and 52.7 kJ/mol of the human consensus V(H)3 domains with which they share the highest degree of sequence similarity. Temperature-induced unfolding of the V(HH) fragments that were studied proved to be reversible, and the binding affinity after cooling was fully retained. The melting temperatures were determined to be between 60.1 and 66.7 degrees C. In contrast, the studied V(H)3 domains aggregated during temperature-induced denaturation at 63-65 degrees C. In summary, the camelid V(HH) fragments are characterized by a favorable but not unusually high stability. Their hallmark is the ability to reversibly melt without aggregation, probably mediated by the surface mutations characterizing the V(HH) domains, which allow them to regain binding activity after heat renaturation.

Self-immobilizing recombinant antibody fragments for immunoaffinity chromatography: generic, parallel, and scalable protein purification

We present the directed immobilization of recombinant antibody fragments as ligands for general immunoaffinity chromatography methods. It is based on fusion proteins of scFv fragments with several chitin-binding domains which can be immobilized directly from a crude bacterial lysate on inexpensive chitin beads for the purification of proteins without any gradient or detector. It has been used with a positive pressure manifold, allowing the parallel processing of 24 different samples on a milligram scale, as convenient as plasmid isolation. The method is demonstrated with several anti-protein antibodies. In addition, methods are presented of using an anti-His tag antibody either alone or directly coupled to IMAC to obtain very pure protein. As those methods are scalable, they should prove very useful in the parallel purification of natural and recombinant proteins on small scales (for proteomics), medium scales (for crystallography and NMR), and very large scales (for therapeutic proteins).

Miniaturised multiplexed immunoassays

Miniaturised immunoassays are of general interest for applications that require the simultaneous determination of different parameters from a minute sample of material. Apart from planar microarray-based systems, bead-based flow cytometric approaches are well suited for the multiplexed detection of target molecules, especially when the number of parameters that have to be determined in parallel is limited.

Antibody engineering

Antibodies are unique in their high affinity and specificity for a binding partner, a quality that has made them one of the most useful molecules for biotechnology and biomedical applications. The field of antibody engineering has changed rapidly in the past 10 years, fueled by novel technologies for the in vitro isolation of antibodies from combinatorial libraries and their functional expression in bacteria. This review presents an overview of the methods available for the de novo generation of human antibodies, for engineering antibodies with increased antigen affinity, and for the production of antibody fragments. Select applications of recombinant antibodies are also presented.

High-throughput antibody isolation

To define the proteome of an organism, there is a need for robust and reproducible methods for the quantitative detection of all the polypeptides in a cell. High-density arrays of receptors specific for each of the polypeptides in a complex sample hold great promise for the analysis of complex protein mixtures. Because of their high affinity, specificity and their ability to bind to virtually any protein, antibodies appear particularly promising as the receptor element in protein-detection arrays. For proteomic-scale analyses, the ability to isolate and produce antibodies en masse to large numbers of target molecules is critical. A variety of systems for the high-throughput isolation of antibodies from combinatorial libraries are being developed and are outlined in this review. However, there are several other important considerations to be borne in mind before such systems can realistically be applied on a large scale.

T7 displayed peptides as targets for selecting peptide specific scFvs from M13 scFv display libraries

M13 scFv display libraries are frontline research tools due to the rapidity in which target binding scFv can be obtained. Simple modifications of the standard affinity selection and amplification protocol allow for multiple targets to be panned simultaneously. Target peptide or protein production can become the rate-limiting step in a high throughput approach to antibody selection. To overcome this obstacle and to save both time and money, we have displayed the target peptides on T7 phage particles. In this paper we demonstrate that these particles can be used directly to select peptide specific scFv. We have discovered that the selection is most efficient when a linker separates the display from the T7 coat protein and when a continuous subtraction is employed. We have used antibodies selected in this fashion to characterize target proteins in cell lysates, immuno-precipitations and immuno-histochemistry.

Improving the efficacy of antibody-based cancer therapies

A quarter of a century after their advent, monoclonal antibodies have become the most rapidly expanding class of pharmaceuticals for treating a wide variety of human diseases, including cancer. Although antibodies have yet to achieve the ultimate goal of curing cancer, many innovative approaches stand poised to improve the efficacy of antibody-based therapies.

Human therapeutic antibodies

The development of genetic engineering technologies has today advanced to the point where the generation of high-affinity human antibodies against therapeutic targets is not a major hurdle. Rather, it is the selection of target molecules in, for example, cancer therapy that poses a challenge. Targets that are not merely passive acceptors but those that signal into the cell are preferred. Recent advances in the clinical use of antibody-based therapy--such as anti-CD20 (rituximab) for the treatment of non-Hodgkin's lymphoma and anti-tumour-necrosis-factor-alpha for Crohn's disease--as well as novel antibody designs and improved understanding of the mode of action of current antibodies lend great hope to the future of this therapeutic approach.

Selection and characterisation of recombinant single-chain antibodies to the hapten Aflatoxin-B1 from naive recombinant antibody libraries

Selection of antibodies from large repertoire phage display libraries has become a common technique for isolation of specific antibodies to antigens. Many of these libraries are shown to contain antibodies specific to haptens, but only when these haptens are derivatised or conjugated to an immobilising molecule, such as bovine serum albumin (BSA). There has been little demonstration of the suitability of naive recombinant antibody libraries for isolating antibodies that bind low molecular weight haptens in the absence of a carrier molecule and few have addressed the problems associated with selecting antibodies that only recognize the combination of hapten and the carrier molecule. We have panned two-phage antibody libraries against AflatoxinB1-BSA and screened single-chain antibody fragments for binding to AflatoxinB1-BSA and Aflatoxin-B1. Many of the antibodies isolated specifically bound AflatoxinB1-BSA, but not soluble Aflatoxin-B1 or BSA. Modification of the protocol led to isolation of single-chain fragment variable antibody domain (scFv) antibodies that specifically bound soluble Aflatoxin-B1 with an affinity of 6x10(-9) M.

High-throughput generation and engineering of recombinant human antibodies

The first version of the Human Combinatorial Antibody Library (HuCAL) is a single-chain Fv-based phage display library (HuCAL-scFv) with 2x10(9) members optimised for high-throughput generation and targeted engineering of human antibodies. 61% of the library genes code for functional scFv as judged by sequencing. We show here that since HuCAL-scFv antibodies are expressed in high levels in Escherichia coli, automated panning and screening in miniaturised settings (96- and 384-well format) have now become feasible. Additionally, the unique modular design of HuCAL-genes and -vectors allows the distinctly facilitated conversion of scFv into Fab, miniantibody and immunoglobulin formats, and the fusion with a variety of effector functions and tags not only convenient for therapeutic applications but also for high-throughput purification and detection. Thus, the HuCAL principle enables the rapid and high-throughput development of human antibodies by optimisation strategies proven useful in classical low molecular weight drug development. We demonstrate in this report that HuCAL is a very convenient source of human antibodies for various applications.

In vitro generated antibodies specific for telomeric guanine-quadruplex DNA react with Stylonychia lemnae macronuclei

Most eukaryotic telomeres contain a repeating motif with stretches of guanine residues that form a 3'-terminal overhang extending beyond the telomeric duplex region. The telomeric repeat of hypotrichous ciliates, d(T(4)G(4)), forms a 16-nucleotide 3'-overhang. Such sequences can adopt parallel-stranded as well as antiparallel-stranded quadruplex conformations in vitro. Although it has been proposed that guanine-quadruplex conformations may have important cellular roles including telomere function, recombination, and transcription, evidence for the existence of this DNA structure in vivo has been elusive to date. We have generated high-affinity single-chain antibody fragment (scFv) probes for the guanine-quadruplex formed by the Stylonychia telomeric repeat, by ribosome display from the Human Combinatorial Antibody Library. Of the scFvs selected, one (Sty3) had an affinity of K(d) = 125 pM for the parallel-stranded guanine-quadruplex and could discriminate with at least 1,000-fold specificity between parallel or antiparallel quadruplex conformations formed by the same sequence motif. A second scFv (Sty49) bound both the parallel and antiparallel quadruplex with similar (K(d) = 3--5 nM) affinity. Indirect immunofluorescence studies show that Sty49 reacts specifically with the macronucleus but not the micronucleus of Stylonychia lemnae. The replication band, the region where replication and telomere elongation take place, was also not stained, suggesting that the guanine-quadruplex is resolved during replication. Our results provide experimental evidence that the telomeres of Stylonychia macronuclei adopt in vivo a guanine-quadruplex structure, indicating that this structure may have an important role for telomere functioning.

A semi-synthetic repertoire of intrinsically stable antibody fragments derived from a single-framework scaffold

We report the design, construction and use of an antibody bacteriophage display library built on the scaffold of a single-chain variable fragment (scFv) previously proven to be functionally expressed in the reducing environment of both bacterial and plant cytoplasm and endowed with intrinsic high thermodynamic stability. Four amino acid residues of the third hypervariable loop (CDR3) of both VH and VL were combinatorially mutated, generating a repertoire of approximately 5x10(7) independent scFvs, cloned in a phagemid vector. The ability of the antibody phage library to yield specific binders was tested by biopanning against several antigens. Successful selection of fully active scFvs was obtained, confirming the notion that combinatorial mutagenesis of few amino acid residues centrally located in the antigen-binding site is sufficient to provide binding specificities against virtually any target. High yields of both soluble and phage antibodies were obtained in Escherichia coli. Maintenance of the cognate scFv antibody stability in the newly selected scFv fragments was demonstrated by guanidinium chloride denaturation/renaturation studies and by soluble antibody expression in the bacterial cytoplasm. The antibody library described here allows the isolation of new stable binding specificities, potentially exploitable as immunochemical reagents for intracellular applications.

Selection, characterization and x-ray structure of anti-ampicillin single-chain Fv fragments from phage-displayed murine antibody libraries

Single-chain Fv (scFv) antibody libraries were constructed from mice immunized with an ampicillin-bovine serum albumin conjugate. Several antibodies with specificity for intact ampicillin were selected by phage display and characterized. The antibody scFv fragment aL2 binds to intact ampicillin and shows no detectable cross-reactivity with hydrolyzed ampicillin. We determined the X-ray structures of two crystal forms of w.t. aL2, which differ mainly in the side-chain conformation of Trp H109 (according to a new consensus nomenclature Kabat residue number H95) in the extremely short (three residues) CDR H3 and the presence or absence of a well-resolved molecule of 2-methyl-pentane-2,4-diol in the bottom of the binding pocket. Attempts to co-crystallize aL2 with its antigen or to diffuse ampicillin into the wild-type aL2 crystals were unsuccessful, since crystal contacts obstruct the binding pocket. However, a mutant with two point mutations near the N terminus (Gln H6 replaced by Glu and Ala H10 (Kabat H9) replaced by Gly) crystallized in a form compatible with antigen-binding. Although the mutations affect the conformation of framework I, the conformations of the binding pocket of the uncomplexed wild-type aL2 and of the mutant complex were almost identical. The structure explains the specificity of the antibody for intact ampicillin and the degree of cross-reactivity of aL2 with a wide variety of ampicillin analogs. This antibody system will be very useful as a diagnostic reagent for antibiotics use and abuse, as a model for the effect of expression of antibiotic binding molecules in Escherichia coli, and for directed evolution towards high antibiotic resistance.

The importance of framework residues H6, H7 and H10 in antibody heavy chains: experimental evidence for a new structural subclassification of antibody V(H) domains

The N-terminal segment (FR-H1) of the heavy chain (V(H)) of antibodies shows significant conformational variability correlating with the nature of the amino acids H6, H7 and H10 (Kabat H9). In this study, we have established a causal relationship between the local sequence and the structure of this framework region and linked this relationship to important biophysical properties such as affinity, folding yield and stability. We have generated six mutants of the scFv fragment aL2, covering some of the most abundant amino acid combinations in positions H6, H7 and H10 (according to a new consensus nomenclature, Kabat H9). For the aL2 wild-type (w.t.) with the sequence 6(Q)7(P)10(A) and for two of the mutants, the X-ray structures have been determined. The structure of the triple mutant aL2-6(E)7(S)10(G) shows the FR-H1 backbone conformations predicted for this amino acid combination, which is distinctly different from the structure of the w.t, thus supporting our hypothesis that these residues determine the conformation of this segment. The mutant aL2-6(E)7(P)10(G) represents a residue combination not occurring in natural antibody sequences. It shows a completely different, unique structure in the first beta-strand of V(H), not observed in natural Fv fragments and forms a novel type of diabody. Two V(H) domains of the mutant associate by swapping the first beta-strand. Concentration-dependent changes in Trp fluorescence indicate that this dimerization also occurs in solution. The mutations in amino acids H6, H7 and H10 (Kabat H9) influence the dimerization behavior of the scFv and its thermodynamic stability. All the observations reported here have practical implications for the cloning of Fv fragments with degenerate primers, as well as for the design of new antibodies by CDR grafting or synthetic libraries.

The influence of the buried glutamine or glutamate residue in position 6 on the structure of immunoglobulin variable domains

Immunoglobulin V(H) domain frameworks can be grouped into four distinct types, depending on the main-chain conformation of framework 1. Based on the analysis of over 200 X-ray structures representing more than 100 non-redundant V(H) domain sequences, we have come to the conclusion that the marked structural variability of the V(H) framework 1 region is caused by three residues: the buried side-chain of H6, which can be either a glutamate or a glutamine residue, the residue in position H7, which may be proline only if H6 is glutamine, and by H9 (H10 according to a new consensus nomenclature), which has to be either glycine or proline if H6 is a glutamate residue. In natural antibodies, these three residues are encoded in combinations that are compatible with each other and with the rest of the structure and therefore will yield functional molecules. However, the degenerate primer mixtures commonly used for PCR cloning of antibody fragments can and frequently do introduce out-of-context mutations to combinations that can lead to severe reduction of stability, production yield and antigen affinity.

Yet another numbering scheme for immunoglobulin variable domains: an automatic modeling and analysis tool

A common residue numbering scheme for all immunoglobulin variable domains (immunoglobulin light chain lambda (V(lambda)) and kappa (V(kappa)) variable domains, heavy chain variable domains (V(H)) and T-cell receptor alpha (V(alpha)), beta (V(beta)), gamma (V(gamma)) and delta (V(delta)) variable domains) has been devised. Based on the spatial alignment of known three-dimensional structures of immunoglobulin domains, it places the alignment gaps in a way that minimizes the average deviation from the averaged structure of the aligned domains. This residue numbering scheme was applied to the immunoglobulin variable domain structures in the PDB database to automate the extraction of information on structural variations in homologous positions of the different molecules. A number of methods are presented that allow the automated projection of information derived from individual structures or from the comparison of multi-structure alignments onto a graphical representation of the sequence alignment.

In vivo recombination as a tool to generate molecular diversity in phage antibody libraries

The creation of diversity in populations of polypeptides has become an important tool in the derivation of polypeptides with useful characteristics. This requires efficient methods to create diversity coupled with methods to select polypeptides with desired properties. In this review we describe the use of in vivo recombination as a powerful way to generate diversity. The novel principles for the recombination process and several applications of this process for the creation of phage antibody libraries are described. The advantage and disadvantages are discussed and possible future exploitation presented.

'Anticalins': a new class of engineered ligand-binding proteins with antibody-like properties

The development of soluble receptor proteins that recognise given target molecules--ranging from small chemical compounds to macromolecular structures at a cell surface, for example--is of ever increasing importance in the life sciences and biotechnology. For the past century this area of application was dominated by antibodies, which were traditionally generated via immunisation of animals but have recently also become available by means of protein engineering methods. The so-called 'anticalins' offer an alternative type of ligand-binding proteins, which has been constructed on the basis of lipocalins as a scaffold. The central element of this protein architecture is a beta-barrel structure of eight antiparallel strands, which supports four loops at its open end. These loops form the natural binding site of the lipocalins and can be reshaped in vitro by extensive amino acid replacement, thus creating novel binding specificities. The bilin-binding protein (BBP) was employed as a model system for the preparation of a random library with 16 selectively mutagenized residues. Using bacterial phagemid display and colony screening techniques, several lipocalin variants--termed anticalins--have been selected from this library, exhibiting binding activity for compounds like fluorescein or digoxigenin. Anticalins possess high affinity and specificity for their prescribed ligands as well as fast binding kinetics, so that their functional properties are similar to those of antibodies. Compared with them, they exhibit however several advantages, including a smaller size, composition of a single polypeptide chain, and a simple set of four hypervariable loops that can be easily manipulated at the genetic level. Apart from haptenic compounds as targets, anticalins should also be able to recognise macromolecular antigens, provided that the random library is accordingly designed. Hence, they should not only serve as valuable reagents for bioanalytical purposes, but may also have a potential in replacing antibodies for medical therapy.

Single domain camel antibodies: current status

The antigen-binding capacity of the paired variable domains of an antibody is well established. The observation that the isolated heavy chains of anti-hapten antibodies retain some antigen-binding capacity in the absence of light chains led to attempts to obtain an even smaller antigen-binding unit in a VH format. Unfortunately, the poor solubility, the reduced affinity for the antigen and the irreproducible outcome showed that additional protein engineering would be required to successfully generate single-domain antibody fragments. By serendipity, it was discovered that this engineering is already performed continuously in nature. Part of the humoral immune response of camels and llamas is based largely on heavy-chain antibodies where the light chain is totally absent. These unique antibody isotypes interact with the antigen by virtue of only one single variable domain, referred to as VHH. Despite the absence of the VH-VL combinatorial diversity, these heavy-chain antibodies exhibit a broad antigen-binding repertoire by enlarging their hypervariable regions. Methods are described to tap the VHH repertoire of an immunised dromedary or llama. These VHH libraries contain a high titre of intact antigen-specific binders that were matured in vivo. Synthetic libraries of a 'camelised' human VH, a mouse VH or a camelid VHH scaffold with a randomised CDR3 could constitute a valid alternative to immune libraries to retrieve useful single-domain antigen binders. The recombinant VHH that are selected from such libraries are well expressed, highly soluble in aqueous environments and very robust. Some in vivo matured VHH were also shown to be potent enzyme inhibitors, and the low complexity of the antigen-binding site is an asset in the design of peptide mimetics. Because of their smaller size and the above properties, the VHH clearly offer added-value over conventional antibody fragments. They are expected to open perspectives as enzyme inhibitors and intrabodies, as modular building units for multivalent or multifunctional constructs, or as immuno-adsorbents and detection units in biosensors.

An improved procedure for the generation of recombinant single-chain Fv antibody fragments reacting with human CD13 on intact cells

A procedure was developed to generate recombinant single chain Fv (scFv) antibody fragments reacting with the extracellular domain of human cell surface antigen CD13 (hCD13; aminopeptidase N) on intact cells. Membrane fractions prepared from a stably transfected hCD13-positive murine NIH/3T3 cell line were used to immunize BALB/c mice, with the intention that hCD13 would be the major immunogenic molecule recognized by the immune system. Spleen RNA from the immunized mice served to generate a combinatorial scFv phage display library. The library was adsorbed against non-transfected NIH/3T3 or Sf21 insect cells to eliminate nonrelevant binders. The supernatant was then used for panning with either hCD13-transfected Sf21 insect cells or a hCD13-expressing human leukemia-derived cell line. Therefore, the key concepts of the procedure were the presentation of hCD13 as the sole human antigen on murine NIH/3T3 cells and a screening strategy where hCD13 was the major common antigen of the material used for immunization and panning. Two different hCD13-reactive phages were isolated and the soluble scFvs were expressed in E. coli and purified. The two scFvs, anti-hCD13-1 and anti-hCD13-3, differed at four amino acid positions in their V(H) regions and both had high affinities for hCD13 as determined by surface plasmon resonance (K(D)=7 and 33x10(-10) M, respectively). Both efficiently recognized hCD13 on intact cells. Therefore, the procedure allowed the production of high affinity scFvs reacting with a desired antigen in its native conformation without requiring extensive purification of the antigen and should be useful for the preparation of scFvs against other conformation-sensitive cell-surface antigens.