Making chemistry selectable by linking it to infectivity

Structure, Biology, and Applications of Filamentous Bacteriophages

The closely related Escherichia coli Ff filamentous phages (f1, fd, and M13) have taken a fantastic journey over the past 60 years, from the urban sewerage from which they were first isolated, to their use in high-end technologies in multiple fields. Their relatively small genome size, high titers, and the virions that tolerate fusion proteins make the Ffs an ideal system for phage display. Folding of the fusions in the oxidizing environment of the E. coli periplasm makes the Ff phages a platform that allows display of eukaryotic surface and secreted proteins, including antibodies. Resistance of the Ffs to a broad range of pH and detergents facilitates affinity screening in phage display, whereas the stability of the virions at ambient temperature makes them suitable for applications in material science and nanotechnology. Among filamentous phages, only the Ffs have been used in phage display technology, because of the most advanced state of knowledge about their biology and the various tools developed for E. coli as a cloning host for them. Filamentous phages have been thought to be a rather small group, infecting mostly Gram-negative bacteria. A recent discovery of more than 10 thousand diverse filamentous phages in bacteria and archaea, however, opens a fascinating prospect for novel applications. The main aim of this review is to give detailed biological and structural information to researchers embarking on phage display projects. The secondary aim is to discuss the yet-unresolved puzzles, as well as recent developments in filamentous phage biology, from a viewpoint of their impact on current and future applications.

Antibody selection using clonal cocultivation of Escherichia coli and eukaryotic cells in miniecosystems

We describe a method for the rapid selection of functional antibodies. The method depends on the cocultivation of Escherichia coli that produce phage with target eukaryotic cells in very small volumes. The antibodies on phage induce selectable phenotypes in the target cells, and the nature of the antibody is determined by gene sequencing of the phage genome. To select functional antibodies from the diverse antibody repertoire, we devised a selection platform that contains millions of picoliter-sized droplet ecosystems. In each miniecosystem, the bacteria produce phage displaying unique members of the antibody repertoire. These phage interact only with eukaryotic cells in the same miniecosystem, making phage available directly for activity-based antibody selection in biological systems.

Filamentous Phage: Structure and Biology

Ff filamentous phage (fd, M13 and f1) of Escherichia coli have been the workhorse of phage display technology for the past 30 years. Dominance of Ff over other bacteriophage in display technology stems from the titres that are about 100-fold higher than any other known phage, efficacious transformation ensuring large library size and superior stability of the virion at high temperatures, detergents and pH extremes, allowing broad range of biopanning conditions in screening phage display libraries. Due to the excellent understanding of infection and assembly requirements, Ff phage have also been at the core of phage-assisted continual protein evolution strategies (PACE). This chapter will give an overview of the Ff filamentous phage structure and biology, emphasizing those properties of the Ff phage life cycle and virion that are pertinent to phage display applications.

Phenotype-information-phenotype cycle for deconvolution of combinatorial antibody libraries selected against complex systems

Use of large combinatorial antibody libraries and next-generation sequencing of nucleic acids are two of the most powerful methods in modern molecular biology. The libraries are screened using the principles of evolutionary selection, albeit in real time, to enrich for members with a particular phenotype. This selective process necessarily results in the loss of information about less-fit molecules. On the other hand, sequencing of the library, by itself, gives information that is mostly unrelated to phenotype. If the two methods could be combined, the full potential of very large molecular libraries could be realized. Here we report the implementation of a phenotype-information-phenotype cycle that integrates information and gene recovery. After selection for phage-encoded antibodies that bind to targets expressed on the surface of Escherichia coli, the information content of the selected pool is obtained by pyrosequencing. Sequences that encode specific antibodies are identified by a bioinformatic analysis and recovered by a stringent affinity method that is uniquely suited for gene isolation from a highly degenerate collection of nucleic acids. This approach can be generalized for selection of antibodies against targets that are present as minor components of complex systems.

Construction and molecular characterization of mouse single-chain variable fragment antibodies against Burkholderia mallei and Burkholderia pseudomallei

We have selected two lipopolysaccharide (LPS) specific Burkholderia mallei mouse monoclonal antibodies (mAbs) and four anti-capsular B. pseudomallei-specific mAbs to generate mouse single-chain variable fragment (scFv) antibodies. This selection was made through extensive in vitro and in vivo assay from our library of mAbs against B. mallei and B. pseudomallei. We initially generated the mouse immunoglobulin variable heavy chain (VH) and light chain (VL) regions from each of these six selected mAbs using a phage display scFv technology. We determined the coding sequences of the VH and VL regions and successfully constructed two B. mallei-specific scFv phage antibodies consisting of two different VH (VH1 and VH2) and one Vλ1 families. Four scFvs constructed against B. pseudomallei had two VH (VH1 and VH6) and two VL (Vκ4/5 and Vκ21) families. All of six scFv antibodies constructed demonstrated good binding activity without any rounds of biopanning against B. mallei (M5D and M18F were 0.425 and 0.480 at OD405nm) and B. pseudomallei (P1E7, P2I67, P7C6, and P7F4 were 0.523, 0.859, 0.775, and 0.449 at OD405nm) by ELISA, respectively. A comparison of the immunoglobulin gene segments revealed that the gene sequences in complementarity-determining regions (CDRs) of three out of four B. pseudomallei-specific scFvs are highly conserved. We determined that the two B. mallei-specific scFvs have different CDRs in the VH, but the amino acid sequences of CDRs in the VL are conserved. This high sequence homology found in CDRs of VH or VL of these mAbs contributes to our better understanding and determination of binding to the specific antigenic epitope(s). The scFv phage display technology may be a valuable tool to develop and engineer mAbs with improved antigen-binding affinity.

Selection and characterization of human antibodies neutralizing Bacillus anthracis toxin

A less than adequate therapeutic plan for the treatment of anthrax in the 2001 bioterrorism attacks has highlighted the importance of developing alternative or complementary therapeutic approaches for biothreat agents. In these regards passive immunization possesses several important advantages over active vaccination and the use of antibiotics, as it can provide immediate protection against Bacillus anthracis. Herein, we report the selection and characterization of several human monoclonal neutralizing antibodies against the toxin of B. anthracis from a phage displayed human scFv library. In total 15 clones were selected with distinct sequences and high specificity to protective antigen and thus were the subject of a series of both biophysical and cell-based cytotoxicity assays. From this panel of antibodies a set of neutralizing antibodies were identified, of which clone A8 recognizes the lethal (and/or edema) factor binding domain, and clones F1, G11, and G12 recognize the cellular receptor binding domain found within the protective antigen. It was noted that all clones distinguish a conformational epitope existing on the protective antigen; this steric relationship was uncovered using a sequential epitope mapping approach. For each neutralizing antibody, the kinetic constants were determined by surface plasmon resonance, while the potency of protection was established using a two-tier macrophage cytotoxicity assay. Among the neutralizing antibodies identified, clone F1 possessed the highest affinity to protective antigen, and provided superior protection from lethal toxin in the cell cytotoxicity assay. The data presented provide the ever-growing arsenal of immunological and functional analysis of monoclonal antibodies to the exotoxins of anthrax. In addition it grants new candidates for the prophylaxis and therapeutic treatment against this toxin.

Selection of human antibodies against cell surface-associated oligomeric anthrax protective antigen

The protective antigen (PA(83)) of Bacillus anthracis is the dominant antigen in natural and vaccine-induced immunity to anthrax infection. Three human single-chain variable fragments (scFvs) against cell bound PA were isolated from an antibody phage display library. Specifically, the antibodies were evaluated for their ability to bind to cell bound heptameric PA and ultimately protect against the cytotoxicity of lethal toxin. In total, all three scFvs possessed neutralizing activity against the cytotoxic effects of lethal toxin in a macrophage lysis assay. The K(d) values of the Fabs were determined, interestingly their protective effects did not parallel their affinities; hence, a simple binding argument alone to PA(63) cannot be used as the distinguishing feature for the prediction of their neutralization abilities. Immunofluorescent microscopy experiments were conducted and provided strong evidence for Fab binding to oligomeric PA on the cell surface and thus a plausible mechanism for the toxin neutralization activity that was observed. The results of this study presented herein suggest that our antibodies compete with LF-PA cell surface interactions, and thus may provide potential application of human antibodies as passive immunization prophylactics in cases of B. anthracis exposure and infection.

Identification and characterization of single chain anti-cocaine catalytic antibodies

Cocaine is a powerful and addictive stimulant whose abuse remains a prevalent health and societal crisis. Unfortunately, no pharmacological therapies exist and therefore alternative protein-based therapies have been examined. One such approach is immunopharmacotherapy, wherein antibodies are utilized to either bind or hydrolyze cocaine thereby blocking it from exerting its euphoric effect. Towards this end, antibodies capable of binding and hydrolyzing cocaine were identified by phage display from a biased single chain antibody library generated from the spleens of mice previously immunized with a cocaine phosphonate transition state analog hapten. Two classes of antibodies emerged based on sequence homology and mode of action. Alanine scanning mutagenesis and kinetic analysis revealed that residues H97, H99, and L96 are crucial for antibodies 3F5 and 3H9 to accelerate the hydrolysis of cocaine. Antibodies 3F1 through 3F4, which are similar to our previously identified 3A6 class of antibodies, catalyze hydrolysis through transition state stabilization by tyrosine or histidine residues H50 and L94. Mutation of either one or both tyrosine residues to histidine conferred hydrolytic activity on previously inactive antibody 3F4. Mutational analysis of residue H50 of antibody 3F3 resulted in a glutamine mutant with a rate enhancement three times greater than wild-type. A double mutant, containing glutamineH50 and lysineH52, showed a tenfold rate enhancement over wild-type. These results indicate the power of initial selection of catalytic antibodies from a biased antibody library in both rapid generation and screening of mutants for improved catalysis.

Modulation of the effector functions of a human IgG1 through engineering of its hinge region

We report here the engineering of a humanized anti-human EphA2 mAb (mAb 12G3H11) in an effort to explore the relationship between the hinge of a human IgG1 and its effector functions. mAb 12G3H11, used here as a model, is directed against the human receptor tyrosine kinase EphA2, which is an actively investigated target for cancer therapy due to its up-regulation in many cancer cells. Various rational modifications were introduced into the hinge region of mAb 12G3H11. These mutations were predicted to modulate the hinge's length, flexibility, and/or biochemical properties. We show that the upper and middle hinge both play important, although functionally distinct roles. In particular, middle hinge modifications predicted to decrease its rigidity or length as well as eliminating either one of its two cysteine residues had a strong negative impact on C1q binding and complement-dependent cytotoxicity. Disruption of covalent bonds between both H chains may account in part for these effects. We also describe middle hinge mutants with a significantly decreased ability to bind FcgammaRIIIA and trigger Ab-dependent cell-mediated cytotoxicity. Conversely, we also generated upper hinge mutants exhibiting an increase in C1q binding and complement-dependent cytotoxicity activity. Therefore, this approach represents a novel strategy to fine-tune the biological activity of a given human IgG1. We also define, for the first time in such a systematic fashion, the relationship between various characteristics of the middle and upper hinge and the corresponding effector functions.

Catalytic autoantibodies in clinical autoimmunity and modern medicine

Abzymes (catalytic autoantibodies) belong to an absolutely new group of physiologically active substances with dual characteristics: they represent a pool of canonical autoantibodies and possess catalytic activity. Among them, proteolytic and DNA-hydrolyzing autoantibodies are of special value. Abzymes are an important pathogenic factor in the progression of clinical autoimmunity syndrome. The presence of autoantibodies against various autoantigens is accompanied by their high catalytic potential. The increase in this activity correlates with serum levels of the autoantibodies, clinical manifestations of autoimmune disorders, disease severity and the rate of progressing disability. Abzymes are crucial for immune homeostasis regulation. They can be of practical value in the development of modern immunodiagnostic tools and schedules of immunotherapy.

Complete reaction cycle of a cocaine catalytic antibody at atomic resolution

Antibody 7A1 hydrolyzes cocaine to produce nonpsychoactive metabolites ecgonine methyl ester and benzoic acid. Crystal structures of 7A1 Fab' and six complexes with substrate cocaine, the transition state analog, products ecgonine methyl ester and benzoic acid together and individually, as well as heptaethylene glycol have been analyzed at 1.5-2.3 angstroms resolution. Here, we present snapshots of the complete cycle of the cocaine hydrolytic reaction at atomic resolution. Significant structural rearrangements occur along the reaction pathway, but they are generally limited to the binding site, including the ligands themselves. Several interacting side chains either change their rotamers or alter their mobility to accommodate the different reaction steps. CDR loop movements (up to 2.3 angstroms) and substantial side chain rearrangements (up to 9 angstroms) alter the shape and size (approximately 320-500 angstroms3) of the antibody active site from "open" to "closed" to "open" for the substrate, transition state, and product states, respectively.

Display of aggregation-prone ligand binding domain of human PPAR gamma on surface of bacteriophage lambda

AIM

To display the aggregation-prone ligand binding domain (LBD) of the human peroxisome proliferator-activated receptor gamma (PPARgamma) on the surface of bacteriophages to establish an easy screening assay for the identification of PPARgamma ligands.

METHODS

Plasmids were constructed for the expression of the PPARgamma LBD as a fusion to the N-terminus of the g3p protein of filamentous phage or the C-terminus of the capsid protein D (pD) of phage lambda. The fusion proteins were expressed in E coli and solubility characteristics were compared. Polyclonal antibodies against the LBD as well as the pD protein were prepared for Western blot analysis and phage capture assay.

RESULTS

The pD-LBD fusion protein was partially soluble, whereas the LBD-g3p fusion protein was detected only in the insoluble fraction. The pD-LBD fusion protein was efficiently incorporated in phage particles. Furthermore, the LBD was shown to be displayed on the surface of bacteriophage lambda. On average, the pD-LBD fusion protein accounted for 28% of the total pD protein in the lambda head capsid.

CONCLUSION

The hydrophobic PPARgamma LBD was expressed as a soluble form of fusion protein in E coli and displayed on the surface of bacteriophage lambda when it was fused to the lambda pD protein. The lambda pD fusion system could be used for improving the solubility of proteins that tend to form inclusion bodies when expressed in E coli. The lambda phage particles displaying the LBD of PPARgamma may be of great value for the identification of novel PPARgamma ligands.

Toward cocaine esterase therapeutics

Cocaine is among the most reinforcing of all drugs of abuse, yet no effective pharmacotherapy is available. Herein, we report the development and characterization of phage-displayed cocaine esterases with pharmacologically relevant kinetic parameters (kcat/Km approximately 104 M-1 s-1).

Treating cocaine addiction with viruses

Cocaine addiction continues to be a major health and social problem in the United States and other countries. Currently used pharmacological agents for treating cocaine abuse have proved inadequate, leaving few treatment options. An alternative is to use protein-based therapeutics that can eliminate the load of cocaine, thereby attenuating its effects. This approach is especially attractive because the therapeutic agents exert no pharmacodynamic action of their own and therefore have little potential for side effects. The effectiveness of these agents, however, is limited by their inability to act directly within the CNS. Bacteriophage have the capacity to penetrate the CNS when administered intranasally. Here, a method is presented for engineering filamentous bacteriophage to display cocaine-binding proteins on its surface that sequester cocaine in the brain. These antibody-displaying constructs were examined by using a locomotor activity rodent model to assess the ability of the phage-displayed proteins to block the psychoactive effects of cocaine. Results presented demonstrate a strategy in the continuing efforts to find effective treatments for cocaine addiction and suggest the application of this protein-based treatment for other drug abuse syndromes.

In vitro selection for enzymatic activity: a model study using adenylate cyclase

An in vitro enzyme selection that can, in principle, be generalised to most chemical reactions, is described. It makes use of filamentous phage display and of a tailor-made antibody fragment directed against the reaction product. The conversion of ATP into 3',5'-cyclic AMP catalysed by Bordetella pertussis adenylate cyclase is taken as an example.

Turnover-based in vitro selection and evolution of biocatalysts from a fully synthetic antibody library

This report describes the selection of highly efficient antibody catalysts by combining chemical selection from a synthetic library with directed in vitro protein evolution. Evolution started from a naive antibody library displayed on phage made from fully synthetic, antibody-encoding genes (the Human Combinatorial Antibody Library; HuCAL-scFv). HuCAL-scFv was screened by direct selection for catalytic antibodies exhibiting phosphatase turnover. The substrate used was an aryl phosphate, which is spontaneously transformed into an electrophilic trapping reagent after cleavage. Chemical selection identified an efficient biocatalyst that then served as a template for error-prone PCR (epPCR) to generate randomized repertoires that were subjected to further selection cycles. The resulting superior catalysts displayed cumulative mutations throughout the protein sequence; the ten-fold improvement of their catalytic proficiencies (>10(10) M(-1)) resulted from increased kcat values, thus demonstrating direct selection for turnover. The strategy described here makes the search for new catalysts independent of the immune system and the antibody framework.

De novo identification of tumor-specific internalizing human antibody-receptor pairs by phage-display methods

Three tumor-specific, internalizing human single-chain Fvs (scFvs) were obtained by direct selection against tumor cells from a large, nonimmune scFv-phage library pre-subtracted with various normal human cells. After scFv selection and characterization for cell binding and internalization, the scFvs were also employed in immunoprecipitations to identify putative receptors. In the case of a prostate tumor-cell specific scFv PR5, the receptor that mediated endocytosis was shown to be the transferrin receptor. For two pancreatic adenocarcinoma specific scFvs SW1 and PAN10, the alpha(3)beta(1) integrin was identified. The scFv SW1 was studied in further detail and found to induce functional effects as a ligand-mimetic by mediating cell adhesion and migration. The results demonstrated the feasibility of utilizing enhanced phage-display methods as a rapid and general approach for not only direct isolation of human internalizing scFvs, but also for identifying tumor cell-surface receptors from various classes. The use of scFv constructs that target tumor cells and undergo internalization could have significant impact on the future of cancer and gene therapy.

A cell-penetrating peptide from a novel pVII-pIX phage-displayed random peptide library

A novel random peptide library was constructed using a phage-display format on the coat proteins pVII and pIX of filamentous bacteriophage. Panning against B-lymphocyte WI-L2 cells yielded one unique peptide-phage, denoted CHL8, that specifically bound to and penetrated the cells. Studies of each peptide derived from CHL8, denoted pep7 and pep9, established that only pep7 mediated the observed activity and only as a homodimer. Peptide libraries displayed on pVII-pIX should serve as a novel source of bioactive ligands for a variety of applications.

A method for the generation of combinatorial antibody libraries using pIX phage display

For more than a decade, phage displayed combinatorial antibody libraries have been used to generate and select a wide variety of antibodies. We previously reported that the phage coat proteins pVII and pIX could be used to display the heterodimeric structure of the antibody Fv region. Herein, aspects of this technology were invoked and extended to construct a large, human single-chain Fv (scFv) library of 4.5 x 10(9) members displayed on pIX of filamentous bacteriophage. Furthermore, the diversity, quality, and utility of the library were demonstrated by the selection of scFv clones against six different protein antigens. Notably, more than 90% of the selected clones showed positive binding for their respective antigens after as few as three rounds of panning. Analyzed scFvs were also found to be of high affinity. For example, kinetic analysis (BIAcore) revealed that scFvs against staphylococcal enterotoxin B and cholera toxin B subunit had a nanomolar and subnanomolar dissociation constant, respectively, affording affinities comparable to, or exceeding that, of mAbs obtained from immunization. High specificity was also attained, not only between very distinct proteins, but also in the case of the Ricinus communis ("ricin") agglutinins (RCA(60) and RCA(120)), despite >80% sequence homology between the two. The results suggested that the performance of pIX-display libraries can potentially exceed that of the pIII-display format and make it ideally suited for panning a wide variety of target antigens.

Human antibodies against spores of the genus Bacillus: a model study for detection of and protection against anthrax and the bioterrorist threat

A naive, human single-chain Fv (scFv) phage-display library was used in bio-panning against live, native spores of Bacillus subtilis IFO 3336 suspended in solution. A direct in vitro panning and enzyme-linked immunosorbent assay-based selection afforded a panel of nine scFv-phage clones of which two, 5B and 7E, were chosen for further study. These two clones differed in their relative specificity and affinity for spores of B. subtilis IFO 3336 vs. a panel of spores from 11 other Bacillus species/strains. A variety of enzyme-linked immunosorbent assay protocols indicated these scFv-phage clones recognized different spore epitopes. Notably, some spore epitopes markedly changed between the free and microtiter-plate immobilized state as revealed by antibody-phage binding. An additional library selection procedure also was examined by constructing a Fab chain-shuffled sublibrary from the nine positive clones and by using a subtractive panning strategy to remove crossreactivity with B. licheniformis 5A24. The Fab-phage clone 52 was improved compared with 5B and was comparable to 7E in binding B. subtilis IFO 3336 vs. B. licheniformis 5A24, yet showed a distinctive crossreactivity pattern with other spores. We also developed a method to directly detect individual spores by using fluorescently labeled antibody-phage. Finally, a variety of "powders" that might be used in deploying spores of B. anthracis were examined for antibody-phage binding. The strategies described provide a foundation to discover human antibodies specific for native spores of B. anthracis that can be developed as diagnostic and therapeutic reagents.

In vivo selectively infective phage as a tool to detect protein interactions: evaluation of a novel vector system with yeast Ste7p-Fus3p interacting proteins

The selectively infective phage (SIP) approach allows rapid identification of interacting proteins by linking protein-protein interaction to phage infectivity. Infection of E. coli by filamentous phage depends on viral g3p. This protein consists of three domains, N1, N2 and CT. Phages lacking the N1 domain are non-infective unless a bait (X)-prey (Y) interaction links it to phage anchored N2-CT domains. We have developed all the vectors required for an in vivo selectively infective phage strategy (SIP). This includes a bait vector, pG3N1, a prey vector, pHOS41, and a gene III deletion helper phage, HPd3. The bait vector pG3N1 allows expression of a bait protein (X) fused to the C-terminus of the N1 domain. The prey vector pHOS41 allows expression of prey (Y) proteins, fused to the N-terminus of the N2-CT domains. The gene III deletion helper phage delivers all phage proteins necessary for phage production, except g3p. Escherichia coli transformed with these three vectors produces non-infective phages unless a bait-prey interaction links the g3p domains. Fus3p and Ste7p, two proteins from the Saccharomyces cerevisiae pheromone-responsive pathway have been cloned to evaluate the SIP strategy. The presence of the interacting N1-Fus3p adapter increased the infectivity of Ste7p-N2-CT phages approximately 1400-fold, which makes SIP a promising technology for the detection and further investigation of interacting proteins.

In vitro selection of enzymatically active lipase variants from phage libraries using a mechanism-based inhibitor

The 'detergent lipase' Lipolase, from Thermomyces lanuginosa was subjected to a combinatorial protein engineering/phage display approach with the aim of identifying new enzyme variants with improved characteristics in the presence of detergents. First it was demonstrated that wild-type Lipolase could be produced in Escherichia coli retaining full activity and be displayed as an active enzyme fused to coat protein 3 on E. coli phage M13. A phagemid library designed to result in approximately two to three mutations per lipase gene was then constructed. Nine amino acids located in two regions close to the active site were targeted for randomization. Selections using a mechanism-based biotinylated inhibitor showed that phages displaying Lipolase could be specifically enriched from a population of control phages. Selections on a library phage stock in the presence of inhibitor and a commercial powder detergent resulted in a step-wise increase in the proportion of active clones. Analysis of 84 active clones revealed that they all expressed lipase activity, but with lower activities than that of a wild-type Lipolase-producing clone. In six of the seven most active clones a wild-type serine at position 83 had been replaced by threonine, a substitution known to alter the substrate chain length preference of Lipolase variants. Furthermore, the selection had enriched enzyme variants with a high degree of conservatism in one of the variegated regions, suggesting that this region is important for enzymatic activity and that the designed selection procedure was relevant. The selected variants contained primarily basic amino acid residues within the other variegated region. Taken together, the described results show that selection protocols based on enzymatic activity can be designed for this enzyme class which should be of importance for future protein engineering attempts.

Novel methods for biocatalyst screening

There have been a number of recent advances in catalysis assays applicable for screening biocatalyst libraries in high-throughput format. These include instrumental assays such as high-performance liquid chromatography, mass spectrometry, capillary electrophoresis and IR-thermography, reagent-based assays producing spectroscopic signals (UV/VIS or fluorescence) in response to reaction progress, and assays based on fluorogenic or chromogenic substrates. These fluorogenic substrates enable the assaying of a variety of enzymes in enantioselective and stereoselective manner, including alcohol dehydrogenases, aldolases, lipases, amidases, epoxide hydrolases and phosphatases.

Critical analysis of antibody catalysis

Antibody molecules elicited with rationally designed transition-state analogs catalyze numerous reactions, including many that cannot be achieved by standard chemical methods. Although relatively primitive when compared with natural enzymes, these catalysts are valuable tools for probing the origins and evolution of biological catalysis. Mechanistic and structural analyses of representative antibody catalysts, generated with a variety of strategies for several different reaction types, suggest that their modest efficiency is a consequence of imperfect hapten design and indirect selection. Development of improved transition-state analogs, refinements in immunization and screening protocols, and elaboration of general strategies for augmenting the efficiency of first-generation catalytic antibodies are identified as evident, but difficult, challenges for this field. Rising to these challenges and more successfully integrating programmable design with the selective forces of biology will enhance our understanding of enzymatic catalysis. Further, it should yield useful protein catalysts for an enhanced range of practical applications in chemistry and biology.

Interdomain interactions within the gene 3 protein of filamentous phage

Infection of Escherichia coli by filamentous phage fd is mediated by the phage gene 3 protein (g3p). The g3p consists of three domains (g3p-D1, D2 and D3) linked by flexible glycine-rich linkers. All three domains are indispensable for phage infectivity; the g3p-D1 domain binds to the TolA receptor presumably at the inner face of the outer membrane, the g3p-D2 domain to the F-pilus and the g3p-D3 domain anchors g3p to the phage coat. The N-terminal domains g3p-D1 and D2 interact with each other; this interaction is abrogated by binding of g3p-D2 to the F-pilus leading to the release of g3p-D1 to bind to TolA. Here, using phages with deletions in g3p, we have discovered a specific interaction between the two N-terminal domains and g3p-D3, the C-terminal domain of g3p. We propose that these interdomain interactions within g3p lead to a compact and stable organisation when displayed on the phage tip, but that during infection, this compact state must be unraveled.

Selectively infective phage (SIP) technology: scope and limitations

We review here the selectively infective phage (SIP) technology, a powerful tool for the rapid selection of protein-ligand and peptide-ligand pairs with very high affinities. SIP is highly suitable for discriminating between molecules with subtle stability and folding differences. We discuss the preferred types of applications for this technology and some pitfalls inherent in the in vivo SIP method that have become apparent in its application with highly randomized libraries, as well as some precautions that should be taken in successfully applying this technology.

Investigation of a tetracycline-regulated phage display system

A new vector (pGZ1) was developed for bacterial phage display of antibody fragments using a transcriptional regulation element with tight control. The tet(p/) degrees -based phasmid exhibits fully suppressed scFv background synthesis in the absence of inducer and is independent of glucose as a catabolite repressor. The vector is shown to be a useful alternative to commonly used lac(p/) degrees -regulated systems.

Phage-display library selection of high-affinity human single-chain antibodies to tumor-associated carbohydrate antigens sialyl Lewisx and Lewisx

mAbs against tumor-associated carbohydrate antigens have the potential to play a prominent role in cancer immunotherapy. However, it has not been possible to fully exploit the clinical utility of such antibodies primarily, because those of adequate affinity could be derived only from murine sources. To address this problem, we prepared a single-chain Fv (scFv) antibody library from the peripheral blood lymphocytes of 20 patients with various cancer diseases. Completely human high-affinity scFv antibodies were then selected by using synthetic sialyl Lewisx and Lewisx BSA conjugates. These human scFv antibodies were specific for sialyl Lewisx and Lewisx, as demonstrated by ELISA, BIAcore, and flow cytometry binding to the cell surface of pancreatic adenocarcinoma cells. Nucleotide sequencing revealed that at least four unique scFv genes were obtained. The Kd values ranged from 1.1 to 6.2 x 10(-7) M that were comparable to the affinities of mAbs derived from the secondary immune response. These antibodies could be valuable reagents for probing the structure and function of carbohydrate antigens and in the treatment of human tumor diseases.

Making artificial antibodies: a format for phage display of combinatorial heterodimeric arrays

The gene VII protein (pVII) and gene IX protein (pIX) are associated closely on the surface of filamentous bacteriophage that is opposite of the end harboring the widely exploited pIII protein. We developed a phagemid format wherein antibody heavy- and light-chain variable regions were fused to the amino termini of pVII and pIX, respectively. Significantly, the fusion proteins interacted to form a functional Fv-binding domain on the phage surface. Our approach will be applicable to the display of generic peptide and protein libraries that can form combinatorial heterodimeric arrays. Consequently, it represents a first step toward artificial antibodies and the selection of novel biological activities.

A combined parallel synthesis and screening of macrocyclic lanthanide complexes for the cleavage of phospho di- and triesters and double-stranded DNA

A parallel synthesis of macrocyclic lanthanide-ligand complexes 4Ln has been developed in conjunction with a parallel screening of these ligands for catalysis of phosphate ester hydrolysis. Complexes 4Ln were screened on a 96-well plate reader for their ability to catalyze the hydrolysis of a variety of phosphate esters efficiently. The hydrolysis of bis(4-nitrophenyl) phosphate (BNPP) 5 and p-nitrophenylethyl phosphate 6 was accelerated by up to 150-fold in the presence of the complex 4cGd. The cleavage of a double-stranded DNA plasmid with this same complex obeyed saturation kinetics following a Michaelian model (K(m) = 7.4 microM, kcat = 4.5 x 10(-3) min-1). Our findings demonstrate how a combination of parallel synthesis and screening can expedite compound access, accelerate catalyst identification, and thereby dramatically increase the speed of finding good ligand-metal combinations.

A method for directed evolution and functional cloning of enzymes

A general scheme is described for the in vitro evolution of protein catalysts in a biologically amplifiable system. Substrate is covalently and site specifically attached by a flexible tether to the pIII coat protein of a filamentous phage that also displays the catalyst. Intramolecular conversion of substrate to product provides a basis for selecting active catalysts from a library of mutants, either by release from or attachment to a solid support. This methodology has been developed with the enzyme staphylococcal nuclease as a model. An analysis of factors influencing the selection efficiency is presented, and it is shown that phage displaying staphylococcal nuclease can be enriched 100-fold in a single step from a library-like ensemble of phage displaying noncatalytic proteins. Additionally, this approach should allow one to functionally clone natural enzymes, based on their ability to catalyze specific reactions (e.g., glycosyl transfer, sequence-specific proteolysis or phosphorylation, polymerization, etc.) rather than their sequence- or structural homology to known enzymes.

Antibody engineering

Among the most important advances in antibody engineering of this past year is the advent of new tools to study the relationship between protein (including antibody) structure and function. Very rapid large-scale mutational analysis of antibodies is now possible by using in vitro transcription and translation. Ribosome display is a rapidly evolving technology for modifying antibody function that offers several potential advantages over phage display.

An evolutionary approach to the design of glutathione-linked enzymes

Studies of protein structure provide information about principles of protein design that have come into play in natural evolution. This information can be exploited in the redesign of enzymes for novel functions. The glutathione-binding domain of glutathione transferases has similarities with structures in other glutathione-linked proteins, such as glutathione peroxidases and thioredoxin (glutaredoxin), suggesting divergent evolution from a common ancestral protein fold. In contrast, the binding site for glutathione in human glyoxalase I is located at the interface between the two identical subunits of the protein. Comparison with the homologous, but monomeric, yeast glyoxalase I suggests that new domains have originated through gene duplications, and that the oligomeric structure of the mammalian glyoxalase I has arisen by 'domain swapping'. Recombinant DNA techniques are being used for the redesign of glutathione-linked proteins in attempts to create binding proteins with novel functions and catalysts with tailored specificities. Enzymes with desired properties are selected from libraries of variant structures by use of phage display and functional assays.