Multivalent Fcγ-receptor engagement by a hexameric Fc-fusion protein triggers Fcγ-receptor internalisation and modulation of Fcγ-receptor functions.

Engagement of Fcγ-receptors triggers a range of downstream signalling events resulting in a diverse array of immune functions. As a result, blockade of Fc-mediated function is an important strategy for the control of several autoimmune and inflammatory conditions. We have generated a hexameric-Fc fusion protein (hexameric-Fc) and tested the consequences of multi-valent Fcγ-receptor engagement in in vitro and in vivo systems. In vitro engagement of hexameric-Fc with FcγRs showed complex binding interactions that altered with receptor density and triggered the internalisation and degradation of Fcγ-receptors. This caused a disruption of Fc-binding and phagocytosis. In vivo, in a mouse ITP model we observed a short half-life of hexameric-Fc but were nevertheless able to observe inhibition of platelet phagocytosis several days after hexameric-Fc dosing. In cynomolgus monkeys, we again observed a short half-life, but were able to demonstrate effective FcγR blockade. These findings demonstrate the ability of multi-valent Fc-based therapeutics to interfere with FcγR function and a potential mechanism through which they could have a sustained effect; the internalisation and degradation of FcγRs.

Predicting the kinetics of peptide-antibody interactions using a multivariate experimental design of sequence and chemical space.

A multivariate approach involving modifications in peptide sequence and chemical buffer medium was used as an attempt to predict the kinetics of peptide-antibody interactions. Using a BIACORE system the kinetic parameters of the interaction of Fab 57P with 18 peptide analogues of an epitope of tobacco mosaic virus protein were characterized in 20 buffers of various pH values and containing different chemical additives (NaCl, urea, EDTA, KSCN and DMSO). For multivariate peptide design, three amino acid positions were selected because their modification was known to moderately affect binding, without abolishing it entirely. Predictive mathematical models were developed which related kinetic parameters (k(a) or k(d)) measured in standard buffer to the amino acid sequence of the antigen. ZZ-scales and a helix-forming-tendency (HFT) scale were used as descriptors of the physico-chemical properties of amino acids in the peptide antigen. These mathematical models had good predictive power (Q(2) = 0.49 for k(a), Q(2) = 0.73 for k(d)). For the non-essential residues under study, HFT and charge were found to be the most important factors that influenced the activity. Experiments in 19 buffers were performed to assess the sensitivity of the interactions to buffer composition. The presence of urea, DMSO and NaCl in the buffer influenced binding properties, while change in pH and the presence of EDTA and KSCN had no effect. The chemical sensitivity fingerprints were different for the various peptides. The results indicate that multivariate experimental design and mathematical modeling can be applied to the prediction of interaction kinetics.

Kinetic characterization of the interaction of the Z-fragment of protein A with mouse-IgG3 in a volume in chemical space.

The kinetic rate parameters for the interaction between a single domain analogue of staphylococcal protein A (Z) and a mouse-IgG3 monoclonal antibody (MAb) were measured in Hepes buffer with different chemical additives. Five buffer ingredients (pH, NaCl, DMSO, EDTA, and KSCN) were varied simultaneously in 16 experiments following a statistical experimental plan. The 16 buffers thus spanned a volume in chemical space. A mathematical model, using data from the buffer composition, was developed and used to predict apparent kinetic parameters in five new buffers within the spanned volume. Association and dissociation parameters were measured in the new buffers, and these agreed with the predicted values, indicating that the model was valid within the spanned volume. The pattern of variation of the kinetic parameters in relation to buffer composition was different for association and dissociation, such that pH influenced both association and dissociation and NaCl influenced only dissociation. This indicated that the recognition mechanism (association) and the stability of the formed complex (dissociation) involve different binding forces, which can be further investigated by kinetic studies in systematically varied buffers.

Initiation of Escherichia coli ribosomes on matrix coupled mRNAs studied by optical biosensor technique.

The optical biosensor technique, based on the surface plasmon resonance (SPR) phenomenon, has been used to study the initiation of protein synthesis by E. coli ribosomes on surface coupled mRNA. mRNA was first periodate oxidized and then hydrazide coupled to the surface of a CM5 sensor chip. The formation of initiation complexes on the surface coupled mRNA was monitored in real-time with a BIACORE 2000 instrument. Mature 70S*mRNA*fMet-tRNA(Met) initiation complexes were assembled on mRNA by sequential introduction of the 30S and 50S subunits supplemented with appropriate initiation factors and fMet-tRNA(Met). We show that the formation of 70S*mRNA complexes on the surface coupled mRNA proceeds efficiently only in the presence of tRNA. Moreover, 70S*mRNA*fMet-tRNA(Met) complexes formed with fMet-tRNA(Met) are more stable than similar complexes formed with deacylated tRNAs. The efficient formation and slow dissociation of mature 70S*mRNA*fMet-tRNA(Met) initiation complexes are most easily explained by the stabilization of the interaction of the ribosomal subunits by fMet-tRNA(Met). This work demonstrates the feasibility of the BIACORE technique for studying the initiation of protein synthesis.

Identification and optimization of regeneration conditions for affinity-based biosensor assays. A multivariate cocktail approach.

A general regeneration, identification, and optimization (RO) protocol for Biacore systems was developed. The RO protocol uses six multi-ingredient stock solutions that represent the six most common chemical properties employed as regeneration agents. The regeneration effect of different regeneration cocktails of these six stock solutions were tested iteratively until a satisfactory result was obtained. The RO protocol was designed with an ease-of-use and multivariate approach. The RO protocol was tested on 13 different antibody-antigen systems. For 10 of these, only the first screening session was tested. For 9 of the 13 systems, the RO-protocol screening session identified cocktails that removed more than 90% of the bound analyte in a 30 s pulse. For 5 systems, the RO protocol identified cocktails that regenerated the surface completely and that were more gentle than previously used regeneration conditions. Furthermore, the regeneration optimization results can be interpreted as a characterization of the interacting molecules. The relevance of testing cocktails was justified by the fact that at least one cocktail was significantly better than all diluted stock solutions for all tested model systems. By using the multivariate approach, the risk of missing relevant combinations of stock solutions was minimized. This resulted in an unexpected discovery of excellent properties of EDTA as an additive in regeneration cocktails containing chaotropic agents and ions in high concentration.

Combining MALDI mass spectrometry and biomolecular interaction analysis using a biomolecular interaction analysis instrument.

Matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) has been combined with biomolecular interaction analysis (BIA) in a Biacore instrument. A method has been developed for the recovery of the affinity-bound molecules from the sensor chip in a few microliters ready for mass spectrometric analysis. The procedure is illustrated with two molecular systems which exemplify antibody-antigen and DNA-protein interactions. In both cases, femtomole quantities of the affinity-bound proteins were eluted and subsequently detected by MALDI-MS. Whereas the Biacore analysis yields the surface concentration of protein bound to the sensor chip, identity of the bound compounds is revealed in the second step by accurate molecular mass determination. Combining the information of the two analyses allows calculation of the total surface molar concentration of affinity-bound molecules.

Biomolecular interaction analysis: affinity biosensor technologies for functional analysis of proteins.

The introduction of affinity-based biosensors has permitted label-free functional analysis of biomolecular interactions in real time. A variety of methods are now based on BIACORE and IAsys technology and have mainly been used to determine kinetics and affinity constants.

Epitope Mapping by Label-Free Biomolecular Interaction Analysis

The diversity of B-cell response to a large immunogen gives rise to a series of antibodies that can be used for epitope mapping of an antigen. This is based on the relative reaction pattern for all antibodies in relation to each other and other ligands to the studied protein. With the introduction of an instrument system, BIAcore, label-free real-time biomolecular interaction analysis (BIA) was made possible. It is based on biosensor technology, with a carboxymethyl-dextran-coated gold surface and an integrated fluidics for transport of liquid. The basic idea is to measure label-free binding of an analyte from a continuous flow to an immobilized ligand in real time. With an automatic approach, quantitative analysis and sequential injection characteristic biospecific binding parameters such as affinity and kinetic constants can be measured. The instrument system was adopted at an early stage for epitope mapping. With label-free detection, antibodies from tissue culture media can be analyzed without purification. Binding of both antigen and a series of antibodies can be individually determined in molar ratio by sequential injections. The quantitative aspects of BIA offer the possibility of further refined epitope mapping. The relative binding pattern for 30 monoclonal antibodies against HIV-1 p24 core protein has been analyzed. Multideterminant analysis and peptide identification of binding sites were performed. Verification of the binding pattern has also been performed in relation to mapping with ELISA as well as the binding to peptides derived from the antigen sequence. Functional domains of proteins in relation to an epitope map have been identified for Taq polymerase.

Isolation of high-affinity monomeric human anti-c-erbB-2 single chain Fv using affinity-driven selection.

The use of antibodies to target tumor antigens has had limited success, partially due to the large size of IgG molecules, difficulties in constructing smaller single chain Fv (scFv) antibody fragments, and immunogenicity of murine antibodies. These limitations can be overcome by selecting human scFv directly from non-immune or semi-synthetic phage antibody libraries; however, the affinities are typically too low for therapeutic application. For hapten antigens, higher-affinity scFv can be isolated from phage antibody libraries where the VH and VL genes of a binding scFv are replaced with repertoires of V genes (chain shuffling). The applicability of this approach to protein binding scFv is unknown. For this work, chain shuffling was used to increase the affinity of a non-immune human scFv, which binds the glycoprotein tumor antigen c-erbB-2 with an affinity of 1.6 x 10(-8) M. The affinity of the parental scFv was increased sixfold (Kd = 2.5 x 10(-9) M) by light-chain shuffling and fivefold (Kd = 3.1 x 10(-9) M) by heavy-chain shuffling, values comparable to those for antibodies against the same antigen produced by hybridomas. When selections were performed on antigen immobilized on polystyrene, spontaneously dimerizing scFv were isolated, the best of which had only a slightly lower Kd than wild type (Kd = 1.1 x 10(-8) M). These scFv dimerize on phage and are preferentially selected as a result of increased avidity. Compared to scFv which formed only monomer, dimerizing scFv had mutations located at the VH-VL interface, suggesting that VH-VL complementarity determines the extent of dimerization. Higher-affinity monomeric scFv were only obtained by selecting in solution using limiting concentrations of biotinylated antigen, followed by screening mutant scFv from bacterial periplasm by koff in a BIAcore. Using the proper selection and screening conditions, protein binding human scFv with affinities comparable to murine hybridomas can be produced without immunization.

Identification of the causative agent of granulocytic ehrlichiosis in Swedish dogs and horses by direct solid phase sequencing of PCR products from the 16S rRNA gene.

Seven Swedish isolates of Ehrlichia species from the blood of four dogs and three horses with clinical granulocytic ehrlichiosis, were identified by direct solid phase DNA sequencing of polymerase chain reaction (PCR) products from the 16S rRNA gene. The amplified DNA fragments were produced with primers complementary to the universal regions, U1, U2, U5 and U8 of the 16S rRNA molecule. Identical sequences were obtained from all seven isolates. This nucleotide sequence was similar to the sequences deposited in GenBank for Ehrlichia phagocytophila and E equi. The sequence of the Swedish ehrlichiae differed in two nucleotide positions from the E phagocytophila sequence and in three positions from the E equi sequence, and it is tentatively proposed that it is a subspecies of one of these two. The alignment of the sequence of the Swedish isolates with a recently deposited sequence from human cases of ehrlichiosis in the USA revealed 100 per cent identity in a segment of about 1400 bp.

Salmonella isolated from animals and feedstuffs in Sweden during 1988-1992.

The present paper surveys the number of Salmonella isolations in animals and feedstuffs in Sweden during 1988-1992. It is the eighth in a series of reports published by the National Veterinary Institute (NVI) since 1949. During the period referred to, 602 outbreaks of Salmonella were reported in animals, both domestic and wild. Compared with the previous 5-year period there was a 20% reduction in the number of outbreaks (760). Fifty-six different serotypes were reported, 19 of which had never been isolated in any animal in Sweden previously. A temporary increase in the number of outbreaks in poultry was seen in 1991 following an extended sampling before slaughter of layers. A remarkably high prevalence (38%) of Salmonella was observed in snakes in the wild. In 1990, the end-point testing of feeds was replaced by an approach based on HACCP (Hazard Analysis Critical Control Point) principles for the monitoring of feed mills. Significantly higher number of Salmonella positive samples were found by using this technique compared with the previous analysis of finished feed. It is concluded that the adopted Salmonella control program has contributed to a reduced number of Salmonella outbreaks in animals in Sweden.

Kinetic analysis of engineered antibody-antigen interactions.

Molecular engineering of antibodies has made it possible to produce specific domains of the antibody molecule and combine them with other protein domains to achieve new properties. Using site directed mutagenesis, amino acid residues can be exchanged within the binding site; and, by analysis of crystal structures, the positions of these amino acids can be determined in three dimensions at atomic resolution. In addition, gene libraries and phage selection technology can be used to generate new antibody fragments directly from a gene pool. Both mutagenesis and selection from libraries offer opportunities to identify antibody-derived molecules with altered and useful antigen recognition properties. The detailed analysis of both kinetic and equilibrium binding affinity are therefore essential to understand the activity of the molecules resulting from antibody engineering and to guide the progress of their further design. This paper reviews recently evolving techniques for the binding analysis of antibodies, their functional domains and antibody chimerae.

Surface plasmon resonance for detection and measurement of antibody-antigen affinity and kinetics.

Kinetic and affinity information on biospecific interaction can be generated by analysis of adsorption of analyte to immobilized ligand on a sensor based analytical system. The analysis can be performed free of label and directly using culture supernatants. It was found to be particularly valuable for analysis of antibody-antigen interactions.

Human anti-self antibodies with high specificity from phage display libraries.

Recently we demonstrated that human antibody fragments with binding activities against foreign antigens can be isolated from repertoires of rearranged V-genes derived from the mRNA of peripheral blood lymphocytes (PBLs) from unimmunized humans. The heavy and light chain V-genes were shuffled at random and cloned for display as single-chain Fv (scFv) fragments on the surface of filamentous phage, and the fragments selected by binding of the phage to antigen. Here we show that from the same phage library we can make scFv fragments encoded by both unmutated and mutated V-genes, with high specificities of binding to human self-antigens. Several of the affinity purified scFv fragments were shown to be a mixture of monomers and dimers in solution by FPLC gel filtration and the binding kinetics of the dimers were determined using surface plasmon resonance (k(on) = 10(5)-10(6) M-1s-1, k(off) = 10(-2)s-1 and Ka = 10(7) M-1). The kinetics of association are typical of known Ab-protein interactions, but the kinetics of dissociation are relatively fast. For therapeutic application, the binding affinities of such antibodies could be improved in vitro by mutation and selection for slower dissociation kinetics.

Biospecific interaction analysis using biosensor technology.

Fundamental information that enhances our understanding of biospecific interactions can be obtained using a new analytical system based on biosensor technology. The functional characteristics of biospecific interaction, such as kinetics, affinity and binding position, are examined by label-free analysis of proteins in free solution binding to an immobilized ligand at a hydrophilic sensor surface.

By-passing immunization: building high affinity human antibodies by chain shuffling.

Diverse antibody libraries can be displayed on the surface of filamentous bacteriophage, and selected by panning of the phage with antigen. This allows human antibodies to be made directly in vitro without prior immunization, thus mimicking the primary immune response. Here we have improved the affinity of one such "primary" antibody by sequentially replacing the heavy and light chain variable (V) region genes with repertoires of V-genes (chain shuffling) obtained from unimmunized donors. For a human phage antibody for the hapten 2-phenyloxazol-5-one (phOx) (Kd = 3.2 x 10(-7) M), we shuffled the light chains and isolated an antibody with a 20 fold improved affinity. By shuffling the first two hypervariable loops of the heavy chain, we isolated an antibody with a further 15-fold improved affinity. The reshuffled antibody differed in five of the six hypervariable loops from the original antibody and the affinity for phOx (Kd = 1.1 x 10(-9) M) was comparable to that of mouse hybridomas from the tertiary immune response. Reshuffling offers an alternative to random point mutation for affinity maturation of human antibodies in vitro.

Detection of antigen-antibody interactions by surface plasmon resonance. Application to epitope mapping.

Surface plasmon resonance (SPR) detection requires no labeling of antigen or antibodies and allows quantification of two or more interacting molecular species. The automated SPR instrument used here consists of an optical detection unit, an integrated liquid handling unit, and an autosampler. A first molecule is immobilized to the dextran modified surface of the sensor chip. By sequential introduction, the stepwise formation of multimolecular complexes can then be monitored. A two-site binding assay which allows characterization of MoAb epitope specificities is described. A polyclonal rabbit anti-mouse IgG1 (RAMG1) immobilized to the dextran surface is used to capture the first MoAb from unprocessed hybridoma culture supernatants. After introducing the antigen, the ability of a second MoAb to bind to the antigen is tested. The analysis cycle which is fully automated can be performed more than 100 times using the same RAMG1 surface. Since the detection principle allows monitoring of each reactant in the consecutive formation of a multimolecular complex, multi-site binding experiments can be performed. Five MoAbs recognizing different epitopes on an antigen were shown to bind sequentially, forming a hexamolecular complex. MoAbs were further characterized by inhibition analysis using synthetic peptides derived from the primary structure of their antigen. As a model system MoAbs against recombinant HIV-1 core protein p24 were used in all experiments.

Characterization of monoclonal anti-DNA antibodies and visualization of binding to chromosomes and cell nuclei.

Monoclonal antibodies against DNA from two hybridoma cell lines were produced and characterized. One had specificity for single stranded (ss) DNA with some cross-reactivity to RNA, while the other was specific for both single (ss) and double stranded (ds) DNA. The latter ds and ss DNA-binding antibody was used as a model for analysing the distribution of the epitope in chromosomes and cell nuclei. A linear correlation between antibody binding and propidium iodide counterstaining was found on flow cytometric analysis of suspended chromosomes. Immunofluorescence of rat myoblast cells showed a speckled distribution of the antibody in the nucleus with a variability between the cells. Using electron microscopy to visualize antibody binding with gold particles, codistribution with uranyl acetate staining of leucocytes was found. These results suggested that the antibody preferentially binds to condensed chromatin in cells and chromosomes.