Ghislaine Béhar

Llama single‐domain antibodies directed against nonconventional epitopes of tumor‐associated carcinoembryonic antigen absent from nonspecific cross‐reacting antigen

Single‐domain antibodies (sdAbs), which occur naturally in camelids, are endowed with many characteristics that make them attractive candidates as building blocks to create new antibody‐related therapeutic molecules. In this study, we isolated from an immunized llama several high‐affinity sdAbs directed against human carcinoembryonic antigen (CEA), a heavily glycosylated tumor‐associated molecule expressed in a variety of cancers. These llama sdAbs bind a different epitope from those defined by current murine mAbs, as shown by binding competition experiments using immunofluorescence and surface plasmon resonance. Flow cytometry analysis shows that they bind strongly to CEA‐positive tumor cells but show no cross‐reaction toward nonspecific cross‐reacting antigen, a highly CEA‐related molecule expressed on human granulocytes. When injected into mice xenografted with a human CEA‐positive tumor, up to 2% of the injected dose of one of these sdAbs was found in the tumor, despite rapid clearance of this 15 kDa protein, demonstrating its high potential as a targeting moiety. The single‐domain nature of these new anti‐CEA IgG fragments should facilitate the design of new molecules for immunotherapy or diagnosis of CEA‐positive tumors.

Single-Domain Antibody–Based and Linker-Free Bispecific Antibodies Targeting FcγRIII Induce Potent Antitumor Activity without Recruiting Regulatory T Cells

Antibody-dependent cell-mediated cytotoxicity, one of the most prominent modes of action of antitumor antibodies, suffers from important limitations due to the need for optimal interactions with Fcγ receptors. In this work, we report the design of a new bispecific antibody format, compact and linker-free, based on the use of llama single-domain antibodies that are capable of circumventing most of these limitations. This bispecific antibody format was created by fusing single-domain antibodies directed against the carcinoembryonic antigen and the activating FcγRIIIa receptor to human Cκ and CH1 immunoglobulin G1 domains, acting as a natural dimerization motif. In vitro and in vivo characterization of these Fab-like bispecific molecules revealed favorable features for further development as a therapeutic molecule. They are easy to produce in Escherichia coli, very stable, and elicit potent lysis of tumor cells by human natural killer cells at picomolar concentrations. Unlike conventional antibodies, they do not engage inhibitory FcγRIIb receptor, do not compete with serum immunoglobulins G for receptor binding, and their cytotoxic activity is independent of Fc glycosylation and FcγRIIIa polymorphism. As opposed to anti-CD3 bispecific antitumor antibodies, they do not engage regulatory T cells as these latter cells do not express FcγRIII. Studies in nonobese diabetic/severe combined immunodeficient gamma mice xenografted with carcinoembryonic antigen–positive tumor cells showed that Fab-like bispecific molecules in the presence of human peripheral blood mononuclear cells significantly slow down tumor growth. This new compact, linker-free bispecific antibody format offers a promising approach for optimizing antibody-based therapies. Mol Cancer Ther; 12(8); 1481–91. ©2013 AACR.

Potent and Specific Inhibition of Glycosidases by Small Artificial Binding Proteins (Affitins)

Glycosidases are associated with various human diseases. The development of efficient and specific inhibitors may provide powerful tools to modulate their activity. However, achieving high selectivity is a major challenge given that glycosidases with different functions can have similar enzymatic mechanisms and active-site architectures. As an alternative approach to small-chemical compounds, proteinaceous inhibitors might provide a better specificity by involving a larger surface area of interaction. We report here the design and characterization of proteinaceous inhibitors that specifically target endoglycosidases representative of the two major mechanistic classes; retaining and inverting glycosidases. These inhibitors consist of artificial affinity proteins, Affitins, selected against the thermophilic CelD from Clostridium thermocellum and lysozyme from hen egg. They were obtained from libraries of Sac7d variants, which involve either the randomization of a surface or the randomization of a surface and an artificially-extended loop. Glycosidase binders exhibited affinities in the nanomolar range with no cross-recognition, with efficient inhibition of lysozyme (Ki = 45 nM) and CelD (Ki = 95 and 111 nM), high expression yields in Escherichia coli, solubility, and thermal stabilities up to 81.1°C. The crystal structures of glycosidase-Affitin complexes validate our library designs. We observed that Affitins prevented substrate access by two modes of binding; covering or penetrating the catalytic site via the extended loop. In addition, Affitins formed salt-bridges with residues essential for enzymatic activity. These results lead us to propose the use of Affitins as versatile selective glycosidase inhibitors and, potentially, as enzymatic inhibitors in general.

Ribosome display for the selection of Sac7d scaffolds.

Combinatorial libraries of Sac7d have proved to be a valuable source of proteins with favorable biophysical properties and novel ligand specificities, so-called Nanofitins. Thus, Sac7d represents a promising scaffold alternative to antibodies for biotechnological and potentially clinical applications. We describe here the methodology for the construction of a library of Sac7d and its use for selection by ribosome display.

Characterization of the Pasteurella multocida skp and firA genes.

A 2.9-kb fragment of the Pasteurella multocida (Pm) genome encoding proteins p25 (25 kDa) and p28 (28 kDa) has previously been cloned and expressed in Escherichia coli (Ec). In the present paper, the nucleotide (nt) sequence of a 1.8-kb subfragment encoding the two proteins is described. The cloned fragment contains three open reading frames (ORFs). ORF1 is incomplete. ORF2 is homologous to the skp gene of Ec. ORF3 overlaps ORF2 and is highly homologous to the firA gene of Ec. The skp and firA genes are part of an operon governing the first steps of lipid A synthesis. Comparing the nt sequence with the N-terminal sequences of p25 and p28 revealed that the two proteins are encoded by ORF2 (skp). The preprotein p28 is converted into p25 by cleavage of a 23-amino-acid leader peptide. Though it serologically cross-reacts with porin H of Pm, p25 is not related to known bacterial porins.

Affitins as robust tailored reagents for affinity chromatography purification of antibodies and non-immunoglobulin proteins.

Affinity chromatography is a convenient way of purifying proteins, as a high degree of purity can be reached in one step. The use of tags has greatly contributed to the popularity of this technique. However, the addition of tags may not be desirable or possible for the production of biopharmaceuticals. There is thus a need for tailored artificial affinity ligands. We have developed the use of archaeal extremophilic proteins as scaffolds to generate affinity proteins (Affitins). Here, we explored the potential of Affitins as ligand to design affinity columns. Affitins specific for human immunoglobulin G (hIgG), bacterial PulD protein, and chicken egg lysozyme were immobilized on an agarose matrix. The columns obtained were functional and highly selective for their cognate target, even in the presence of exogenous proteins as found in cell culture media, ascites and bacterial lysates, which result in a high degree of purity (∼95%) and recovery (∼100%) in a single step. Anti-hIgG Affitin columns withstand repetitive cycles of purification and cleaning-in-place treatments with 0.25 M NaOH as well as Protein A does. High levels of Affitin productions in Escherichia coli makes it possible to produce these affinity columns at low cost. Our results validate Affitins as a new class of tailored ligands for the affinity chromatography purification of potentially any proteins of interest including biopharmaceuticals.

Artificial Affinity Proteins as Ligands of Immunoglobulins

A number of natural proteins are known to have affinity and specificity for immunoglobulins. Some of them are widely used as reagents for detection or capture applications, such as Protein G and Protein A. However, these natural proteins have a defined spectrum of recognition that may not fit specific needs. With the development of combinatorial protein engineering and selection techniques, it has become possible to design artificial affinity proteins with the desired properties. These proteins, termed alternative scaffold proteins, are most often chosen for their stability, ease of engineering and cost-efficient recombinant production in bacteria. In this review, we focus on alternative scaffold proteins for which immunoglobulin binders have been identified and characterized.

Affinity transfer to the archaeal extremophilic Sac7d protein by insertion of a CDR.

Artificially transforming a scaffold protein into binders often consists of introducing diversity into its natural binding region by directed mutagenesis. We have previously developed the archaeal extremophilic Sac7d protein as a scaffold to derive affinity reagents (Affitins) by randomization of only a flat surface, or a flat surface and two short loops with natural lengths. Short loops are believed to contribute to stability of extremophilic proteins, and loop extension has been reported detrimental for the thermal and chemical stabilities of mesophilic proteins. In this work, we wanted to evaluate the possibility of designing target-binding proteins based on Sac7d by using a complementary determining region (CDR). To this aim, we inserted into three different loops a 10 residues CDR from the cAb-Lys3 anti-lysozyme camel antibody. The chimeras obtained were as stable as wild-type (WT) Sac7d at extreme pH and their structural integrity was supported. Chimeras were thermally stable, but with T(m)s from 60.9 to 66.3°C (cf. 91°C for Sac7d) which shows that loop extension is detrimental for thermal stability of Sac7d. The loop 3 enabled anti-lysozyme activity. These results pave the way for the use of CDR(s) from antibodies and/or extended randomized loop(s) to increase the potential of binding of Affitins.

The archaeal "7 kDa DNA-binding" proteins: extended characterization of an old gifted family.

The “7 kDa DNA-binding” family, also known as the Sul7d family, is composed of chromatin proteins from the Sulfolobales archaeal order. Among them, Sac7d and Sso7d have been the focus of several studies with some characterization of their properties. Here, we studied eleven other proteins alongside Sac7d and Sso7d under the same conditions. The dissociation constants of the purified proteins for binding to double-stranded DNA (dsDNA) were determined in phosphate-buffered saline at 25 °C and were in the range from 11 μM to 22 μM with a preference for G/C rich sequences. In accordance with the extremophilic origin of their hosts, the proteins were found highly stable from pH 0 to pH 12 and at temperatures from 85.5 °C to 100 °C. Thus, these results validate eight putative “7 kDa DNA-binding” family proteins and show that they behave similarly regarding both their function and their stability among various genera and species. As Sac7d and Sso7d have found numerous uses as molecular biology reagents and artificial affinity proteins, this study also sheds light on even more attractive proteins that will facilitate engineering of novel highly robust reagents.

Evolution of interleukin-15 for higher E. coli expression and solubility

Directed evolution was used to generate IL-15 mutants with increased solubility and cytoplasmic over-expression in Escherichia coli. A protein solubility selection method was used in which the IL-15 gene was expressed as an N-terminal fusion to chloramphenicol acetyltransferase (CAT) as reporter protein. Clones that grew in the presence of high concentrations of chloramphenicol were then screened by ELISA to assay the binding activity of the IL-15-CAT fusion to the IL-15Rα Sushi domain. Two variants of IL-15, M38 and M253, containing five mutations and one mutation respectively, were selected with a dramatic improvement in solubility; the soluble concentration in cell culture was 12- to 18-fold higher, respectively, than for WT IL-15. Characterization of their binding to IL-15Rα and their ability to stimulate the T-cell growth response showed that M38 binds as strongly as native IL-15 to IL-15Rα and acts as an effective agonist of IL-15.