Identification of single chain antibodies to breast cancer stem cells using phage display

Recent evidence suggests that most malignancies are driven by “cancer stem cells” sharing the signature characteristics of adult stem cells: the ability to self renew and to differentiate. Furthermore these cells are thought to be quiescent, infrequently dividing cells with a natural resistance to chemotherapeutic agents. These studies theorize that therapies, which effectively treat the majority of tumor cells but ‘miss’ the stem cell population, will fail, while therapies directed at stern cells can potentially eradicate tumors. In breast cancer, researchers have isolated ‘breast cancer stem cells’ capable of recreating the tumor in vivo and in vitro. Generated new tumors contained both additional numbers of cancer stem cells and diverse mixed populations of cells present in the initial tumor, supporting the intriguing self‐renewal and differentiation characteristics. In the present study, an antibody phage library has been used to search for phage displayed‐single chain antibodies (scFv) with selective affinity to specific targets on breast cancer stem cells. We demonstrate evidence of two clones binding specifically to a cancer stem cell population isolated from the SUMl59 breast cancer cell line. These clones had selective affinity for cancer stem cells and they were able to select cancer stem cells among a large population of non‐stem cancer cells in paraffin‐embedded sections. The applicability of these clones to paraffin sections and frozen tissue specimens made them good candidates to be used as diagnostic and prognostic markers in breast cancer patient samples taking into consideration the cancer stern cell concept in tumor biology. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Discovery of human antibodies against the C5aR target using phage display technology

Phage display technologies have been increasingly utilized for the generation of therapeutic, imaging and purification reagents for a number of biological targets. Using a variety of different approaches, we have developed antibodies with high specificity and affinity for various targets ranging from small peptides to large proteins, soluble or membrane-associated as well as to activated forms of enzymes. We have applied this approach to G-protein coupled receptors (GPCRs), often considered difficult targets for antibody therapeutics and targeting. Here we demonstrate the use of this technology for the identification of human antibodies targeting C5aR, the chemoattractant GPCR receptor for anaphylatoxin C5a. The N-terminal region (residues 1-31) of C5aR, one of the ligand binding sites, was synthesized, biotinylated and used as the target for selection. Three rounds of selection with our proprietary human Fab phage display library were performed. Screening of 768 isolates by phage ELISA identified 374 positive clones. Based on sequence alignment analysis, the positive clones were divided into 22 groups. Representative Fab clones from each group were reformatted into IgGs and tested for binding to C5aR-expressing cells, the differentiated U-937 cells. Flow cytometric analysis demonstrated that nine out of 16 reformatted IgGs bound to cells. Competition with a C5aR monoclonal antibody S5/1 which recognizes the same N-terminal region showed that S5/1 blocked the binding of positive cell binders to the peptide used for selections, indicating that the identified cell binding IgGs were specific to C5aR. These antibody binders represent viable candidates as therapeutic or imaging agents, illustrating that phage display technology provides a rapid means for developing antibodies to a difficult class of targets such as GPCRs.     

Recognition of cell-specific binding of phage display derived peptides using an acoustic wave sensor

ASSLNIA, a peptide selected for murine myofibers using phage display technology, was immobilized onto an acoustic wave sensor. The sensor responded to murine and feline muscle homogenates indicating crosspieces interactions. Kidney, liver, and brain preparations produced insignificant responses.     

Identification of ligand-selective peptidic ActRIIB-antagonists using phage display technology

ActRIIB (activin receptor type-2B) is an activin receptor subtype constitutively expressed in the whole body, playing a role in cellular proliferation, differentiation, and metabolism. For its various physiological activities, ActRIIB interacts with activin and multiple other ligands including myostatin (MSTN), growth differentiation factor 11 (GDF11), and bone morphogenetic protein 9 (BMP9). Notably, the protein-protein interaction (PPI) between ActRIIB and MSTN negatively controls muscular development. Therefore, this PPI has been targeted for effective treatment of muscle degenerative diseases such as muscular dystrophy and sarcopenia. Here, we report the identification of ligand-selective peptidic ActRIIB-antagonists by phage display technology. Our peptides bound to the extracellular domain of ActRIIB, inhibited PPIs between ActRIIB expressed on the cell surface and its ligands, and subsequently suppressed activation of Smad that serves as the downstream signal of the ActRIIB pathway. Interestingly, these peptidic antagonists displayed different ligand selectivities; the AR2mini peptide inhibited multiple ligands (activin A, MSTN, GDF11, and BMP9), AR9 inhibited MSTN and GDF11, while AR8 selectively inhibited MSTN. This is the first report of artificial peptidic ActRIIB-antagonists possessing ligand-selectivity.     

Localization of melanin in conidia of Alternaria alternata using phage display antibodies

Melanins derived from 1,8-dihydroxynaphthalene (DHN) are important for the pathogenicity and survival of fungi causing disease in both plants and animals. However, precise information on their location within fungal cell walls is lacking. To obtain antibodies for the immunocytochemical localization of melanin, 83 phage antibodies binding to 1,8-DHN were selected from a naive semisynthetic single-chain Fv (scFv) phage display library. Sequence analysis of the heavy chain binding domains of 17 antibodies showed a high frequency of positively charged amino acids. One antibody, designated M1, was characterized in detail. M1 bound specifically to 1,8-DHN in competitive inhibition enzyme-linked immunosorbent assays, showing no cross-reaction with nine structurally related phenolic compounds. Epitope recognition required two hydroxyl groups in a 1,8 configuration. M1 also bound to naturally occurring melanin isolated from mycelia of Alternaria alternata, suggesting that epitopes remain accessible in polymerized melanin. Transmission electron microscopy-immunogold labeling, using M1 in the form of soluble scFv fragments, showed that melanin was located in the septa and outer (primary) walls of wild-type A. alternata conidia, but not those of an albino mutant, AKT88-1. The M1 antibody provides a new tool for detecting melanized pathogens in plant and animal tissues and for precisely mapping the distribution of the polymer within spores, appressoria, and hyphae.     

Methodology for optimizing functional miniature proteins based on avian pancreatic polypeptide using phage display.

Synthetic genes for avian pancreatic polypeptide (aPP) and for the miniature DNA binding protein PPBR4 were cloned and expressed on the surface of M13 bacteriophage. We anticipate that these constructs will have utility optimizing the properties of miniature proteins based on aPP that result from our previously described protein grafting procedure.     

Acoustic microfluidic chip technology to facilitate automation of phage display selection

Modern tools in proteomics require access to large arrays of specific binders for use in multiplex array formats, such as microarrays, to decipher complex biological processes. Combinatorial protein libraries offer a solution to the generation of collections of specific binders, but unit operations in the process to isolate binders from such libraries must be automatable to ensure an efficient procedure. In the present study, we show how a microfluidic concept that utilizes particle separation in an acoustic force field can be used to efficiently separate antigen-bound from unbound members of such libraries in a continuous flow format. Such a technology has the hallmarks for incorporation in a fully automated selection system for the isolation of specific binders.     

Developing strategies to enhance and focus humoral immune responses using filamentous phage as a model antigen

Filamentous bacteriophage are commonly used as immunogenic carriers for peptides and proteins displayed on the phage surface. Previously, we showed that immunization with phage to which peptides had been chemically conjugated can elicit a focused anti-peptide antibody response compared with traditional carrier molecules bearing the same peptide, perhaps due to the low surface complexity of the phage. The regularity of its surface also gives the phage other advantages as a carrier, including immunological simplicity and thousands of well-defined sites for chemical conjugation. More recently, we showed that focusing of antibody responses against 'target' peptides was enhanced when the phage's molecular surface was simplified by removal of immunodominant B-cell epitopes present on the minor coat protein, pIII. The pIII-truncated variant elicits an antibody response that is largely restricted to the exposed N-terminus of the major coat protein, pVIII, and to phage-associated bacterial lipopolysaccharide, and a significant fraction of this response cross-reacts with a 12-residue peptide covering the surface-exposed region of pVIII. This allows one to track antibody responses against the phage (and any associated haptens) as they develop over time, and characterize them using a combination of serological, flow cytometric, cellular and immunogenetic assays. The filamentous phage thus provides an excellent model system for studying various aspects of the antibody response, all with the goal of targeting antibody production against weakly immunogenic peptides, proteins and carbohydrates.     

Using phage display to select antibodies recognizing post-translational modifications independently of sequence context

Many cellular activities are controlled by post-translational modifications, the study of which is hampered by the lack of specific reagents due in large part to their ubiquitous and non-immunogenic nature. Although antibodies against specifically modified sequences are relatively easy to obtain, it is extremely difficult to derive reagents recognizing post-translational modifications independently of the sequence context surrounding the modification. In this study, we examined the possibility of selecting such antibodies from large phage antibody libraries using sulfotyrosine as a test case. Sulfotyrosine is a post-translational modification important in many extracellular protein-protein interactions, including human immunodeficiency virus infection. After screening almost 8000 selected clones, we were able to isolate a single specific single chain Fv using two different selection strategies, one of which included elution with tyrosine sulfate. This antibody was able to recognize sulfotyrosine independently of its sequence context in test peptides and a number of different natural proteins. Antibody reactivity was lost by antigen treatment with sulfatase or preincubation with soluble tyrosine sulfate, indicating its specificity. The isolation of this antibody signals the potential of phage antibody libraries in the derivation of reagents specific for post-translational modifications, although the extensive screening required indicates that such antibodies are extremely rare.     

A review: Cloning of human antibodies by phage display

Antibodies play a pivotal role in human health and disease. The application of phage display technology represents another milestone in the attempt to gain a better understanding of human antibodies. Immunoglobulin phage display permits human monoclonal antibodies for the first time to be readily available for analysis and for therapeutic use. Recent developments in molecular biology, in particular the polymerase chain reaction, have made it possible to amplify, clone, and express human antibody fragments in prokaryotic organisms. Phagemid display vectors have a distinct advantage over conventional cell culture technology used to immortalize human antibodies, in that one may quickly survey huge immunoglobulin repertoires for an antibody of desired specificity. Dual expression of immunoglobulin variable region light and heavy chain fragments permits combinatorial shuffling and thus an increase in diversity.The development of sophisticated computer algorithms, such as LINUS,⁵⁷ that can predict the three-dimensional structure of proteins from DNA sequences will have an enormous influence on the characterization and design of human antibodies. Future advances in computer software will be needed to aid in the identification of unique antibody sequence motifs expressed during disease and in the design of antibodies with defined functional epitopes.     

Selection of staphylococcal enterotoxin B (SEB)-binding peptide using phage display technology

In this study, peptides were selected to recognize staphylococcal enterotoxin B (SEB) which cause food intoxication and can be used as a biological war agent. By using commercial M13 phage library, single plaque isolation of 38 phages was done and binding affinities were investigated with phage-ELISA. The specificities of the selected phage clones showing high affinity to SEB were checked by using different protein molecules which can be found in food samples. Furthermore, the affinities of three selected phage clones were determined by using surface plasmon resonance (SPR) sensors. Sequence analysis was realized for three peptides showing high binding affinity to SEB and WWRPLTPESPPA, MNLHDYHRLFWY, and QHPQINQTLYRM amino acid sequences were obtained. The peptide sequence with highest affinity to SEB was synthesized with solid phase peptide synthesis technique and thermodynamic constants of the peptide-SEB interaction were determined by using isothermal titration calorimetry (ITC) and compared with those of antibody-SEB interaction. The binding constant of the peptide was determined as 4.2 ± 0.7 × 10⁵ M⁻¹ which indicates a strong binding close to that of antibody.     

Peptides identified through phage display direct immunogenic antigen to dendritic cells

Dendritic cells (DC) play a critical role in adaptive immunity by presenting Ag, thereby priming naive T cells. Specific DC-binding peptides were identified using a phage display peptide library. DC-peptides were fused to hepatitis C virus nonstructural protein 3 (NS3) while preserving DC targeting selectivity and Ag immunogenicity. The NS3-DC-peptide fusion protein was efficiently presented to CD4+ and CD8+ T cells derived from hepatitis C virus-positive blood cells, inducing their activation and proliferation. This immunogenic fusion protein was significantly more potent than NS3 control fusion protein or NS3 alone. In chimeric NOD-SCID mice transplanted with human cells, DC-targeted NS3 primed naive CD4+ and CD8+ T cells for potent NS3-specific proliferation and cytokine secretion. The capacity of peptides to specifically target immunogenic Ags to DC may establish a novel strategy for vaccine development.     

Protein III-based single-chain antibody phage display using bacterial cells bearing an additional genome of a gene-III-lacking helper phage

We present herein a novel method of pIII-based antibody phage display using Hpd3cells--bacterial cells bearing the genome of a gene-III-lacking helper phage (VCSM13d3). A high level of single-chain variable fragments (scFvs) was displayed in the consequent phagemid particles using Hpd3cells to rescue the phagemid encoding scFv-pIII. Hpd3cells considerably improved the specific enrichment factor when used for constructing an immunized antibody library. In addition, using Hpd3cells could overcome pill resistance and can contribute to the efficient enrichment of specific binding antibodies from a phage display library, thereby increasing the chance of obtaining more diverse antibodies specific for target antigens.     

Selection of cell‐type specific antibodies on tissue‐sections using phage display

With the advent of modern technologies enabling single cell analysis, it has become clear that small sub‐populations of cells or even single cells can drive the phenotypic appearance of tissue, both diseased and normal. Nucleic acid based technologies allowing single cell analysis has been faster to mature, while technologies aimed at analysing the proteome at a single cell level is still lacking behind, especially technologies which allow single cell analysis in tissue. Introducing methods, that allows such analysis, will pave the way for discovering new biomarkers with more clinical relevance, as these may be unique for microenvironments only present in tissue and will avoid artifacts introduced by in vitro studies. Here, we introduce a technology enabling biomarker identification on small sub‐populations of cells within a tissue section. Phage antibody libraries are applied to the tissue sections, followed by washing to remove non‐bound phage particles. To eliminate phage antibodies binding to antigens ubiquitously expressed and retrieve phage antibodies binding specifically to antigens expressed by the sub‐population of cells, the area of interest is protected by a ‘shadow stick’. The phage antibodies on the remaining areas on the slide are exposed to UV light, which introduces cross‐links in the phage genome, thus rendering them non‐replicable. In this work we applied the technology, guided by CD31 expressing endothelial cells, to isolate recombinant antibodies specifically binding biomarkers expressed either by the cell or in the microenvironment surrounding the endothelial cell.     

Selection of antibodies against a single rare cell present in a heterogeneous population using phage display

Here we describe a new method applying phage-displayed antibody libraries to the selection of antibodies against a single identified cell on a glass slide. This is the only described method that has successfully achieved selection of antibodies against a single rare cell in a heterogeneous population of cells. The phage library is incubated with the slide containing the identified rare cell of interest; incubation is followed by UV irradiation while protecting the target cell with a minute disc. The UV light inactivates all phages outside the shielded area by cross-linking the DNA constituting their genomes. The expected yield is between one and ten phage particles from a single cell selection. The encoded antibodies are subsequently produced monoclonally and tested for specificity. This method can be applied within a week to carry out ten or more individual cell selections. Including subsequent testing of antibody specificity, a specific antibody can be identified within 2 months.     

Mapping of hiv-1 Gag epitopes recognized by polyclonal antibodies using gene-fragment phage display system.

Phage display has emerged as a powerful technique for mapping epitopes recognised by monoclonal and polyclonal antibodies. We have recently developed a simple gene-fragment phage display system and have shown its utility in mapping epitope recognised by a monoclonal antibody. In the present study, we have employed this system in mapping epitopes recognised by polyclonal antibodies raised against HIV-1 capsid protein, p24 which is derived from proteolytic cleavage of Gag polyprotein. HIV-1 gag DNA was fragmented by DNase I and the fragments (50-250 bp) were cloned into gene-fragment phage display vector to construct a library of phages displaying peptides. This phage library was used for affinity selection of phages displaying epitopes recognised by rabbit anti-p24 polyclonal antibodies. Selected phages contained sequences from two discrete regions of p24, demonstrating the presence of two antigenic regions. The DNA sequences encoding these regions were also cloned and expressed as GST fusion proteins. The immunoreactivity of these epitopes as GST fusion proteins, or as phage-displayed peptides, was comparable in ELISA system using same anti-p24 polyclonal antibodies. The results indicate that the gene-fragment based phage display system can be used efficiently to identify epitopes recognised by polyclonal antibodies, and phage displayed epitopes can be directly employed in ELISA to detect antibodies.