Construction of a Synthetic Human VL Phage Display Library and Isolation of Potential Neuropilin-1-specific VL Therapeutics from the Library

Keklikian, Artine

07 September 2011

Antibody phage display technology mimics the natural immune system, and has been widely used for rapid isolation of single-domain antibodies (sdAbs) with various binding specificities and affinities in the micromolar to low nanomolar range. SdAbs are the variable regions of immunoglobulins (e.g., VH, VL, VHH) and serve as potential probes with therapeutic value. The small size, high solubility, high expression and stability, and high specificity and affinity for the cognate antigen, make sdAbs ideal in improving drug delivery and the overall therapeutic value of antibodies. The main objective of this thesis was to construct a large VL phage display library (~1010 diversity); analyze it via sequence analysis, and to subtractively pan the library for isolation of Neuropilin-1 (NRP1)-specific VLs. Neuropilin-1 (NRP1), a cell-surface receptor for both vascular endothelial growth factor (VEGF) and class 3 Semaphorins (Sema3A), contributes to neuron cell death through its interaction with Sema3A in stroke patients. Disruption of this NRP1-Sema3A interaction would allow for axonal outgrowth and neuron regeneration in the area of the brain affected by stroke. Construction of the synthetic phage antibody library utilized a single VL framework with selected positions in the complementarity-determining regions (CDRs) targeted for randomization in vitro using synthetic oligonucleotides that introduced sequence degeneracy. Specific VLs were then selected from the repertoire through subtractive panning against a cell line endogenously expressing NRP1 (PC12) as well as a negative cell line that does not express NRP1 (HEK293) with competitive elution carried out using a synthetic Sema3A-derived peptide. Fifteen VL clones were isolated, cloned in E. coli, expressed and purified, and of these, nine were determined to be non-aggregating by size exclusion chromatography. Further studies will determine the potential therapeutic use of these VL sdAbs as agents in recovery from stroke and neuron degeneration.

Antibody phage display

Single domain antibody

VL

Generation and characterisation of a naive human antibody phage display library : a resource for clinically relevant reagents /

Hald, Rikke.

January 2004

Ph.D.

Construction of a Synthetic Human VL Phage Display Library and Isolation of Potential Neuropilin-1-specific VL Therapeutics from the Library

Keklikian, Artine

January 2011

Antibody phage display technology mimics the natural immune system, and has been widely used for rapid isolation of single-domain antibodies (sdAbs) with various binding specificities and affinities in the micromolar to low nanomolar range. SdAbs are the variable regions of immunoglobulins (e.g., VH, VL, VHH) and serve as potential probes with therapeutic value. The small size, high solubility, high expression and stability, and high specificity and affinity for the cognate antigen, make sdAbs ideal in improving drug delivery and the overall therapeutic value of antibodies. The main objective of this thesis was to construct a large VL phage display library (~1010 diversity); analyze it via sequence analysis, and to subtractively pan the library for isolation of Neuropilin-1 (NRP1)-specific VLs. Neuropilin-1 (NRP1), a cell-surface receptor for both vascular endothelial growth factor (VEGF) and class 3 Semaphorins (Sema3A), contributes to neuron cell death through its interaction with Sema3A in stroke patients. Disruption of this NRP1-Sema3A interaction would allow for axonal outgrowth and neuron regeneration in the area of the brain affected by stroke. Construction of the synthetic phage antibody library utilized a single VL framework with selected positions in the complementarity-determining regions (CDRs) targeted for randomization in vitro using synthetic oligonucleotides that introduced sequence degeneracy. Specific VLs were then selected from the repertoire through subtractive panning against a cell line endogenously expressing NRP1 (PC12) as well as a negative cell line that does not express NRP1 (HEK293) with competitive elution carried out using a synthetic Sema3A-derived peptide. Fifteen VL clones were isolated, cloned in E. coli, expressed and purified, and of these, nine were determined to be non-aggregating by size exclusion chromatography. Further studies will determine the potential therapeutic use of these VL sdAbs as agents in recovery from stroke and neuron degeneration.

Antibody phage display

Single domain antibody

VL

Selection of Phage Displaying Peptides Specific for Staphylococcus Aureus

Gadzekpo, Isaac Kwabena

06 May 2021

No description available.

Biology

Staphylococcus aureus

Phage display

peptide

Využití metody phage display při zkoumání povrchových antigenů Leishmania mexicana / The use of phage display to investigate Leishmania mexicana surface antigens

Krylová, Anna

January 2020

Leishmania is a protozoan parasite of vertebrates transmitted by the bite of infected phlebotomine sandflies. In humans, it causes a disease called leishmaniasis, which ranks as one of the most serious neglected tropical diseases. In the vectorial part of the life cycle, the crucial moment is when the flagellate forms (promastigotes) attach to the midgut epithelium of the sandfly. For most leishmania species, little is known about which types of phlebotomine receptors and leishmania surface antigens participate in the binding. Phage display was used to screen for Leishmania mexicana peptide ligands which may play a role in such binding. By affinity selection of phages incubated with promastigote cells, 16 unique peptides were identified. Fluorescent labelling of peptide-bearing phages indicated their putative binding sites on the leishmania surface. Based on the hypothesis that the identified peptides may be a part of receptors found in the phlebotomine midgut, experiments were performed where the sandflies were infected with promastigotes whose binding sites were blocked by two different peptide-bearing phages. The extent of the infection was different between the two cases. However, no statistically significant difference from the control group was observed. Despite unsuccessful attempts to identify a...

Selection and use of affinity proteins developed by combinatorial engineering

Sandström, Kristofer

January 2003

In affinity protein biotechnology the selective bindingbetween a chosen protein and an interacting biomolecule isutilized for a variety of applications including bioseparation,detection and therapy. Traditionally, affinity proteinsrecruited for such applications have been derived from naturalproteins or immunoglobulins generated via immunization routes.More recently, advances in the construction and handling oflarge collections of proteins(denoted libraries) generated invitro have opened up for new routes for the development ofaffinity proteins with desired properties. In this study, phage display selection technology was usedfor the isolation of novel human CD28 (hCD28)-specific affinityproteins from a protein library constructed by combinatorialprotein engineering of a 58 aa protein domain (Z) derived fromstaphylococcal protein A (SPA). From selections using hCD28 asa target molecule, several hCD28-specific affinity proteins(denoted affibodies) could be identified and analysis of theisolated affibody variants revealed a high degree of sequencehomology between the different clones. The biosensor analysisshowed that all variants bound to hCD28 with micromolardissociation constants (KD) and no significant cross-reactivitytowards the structurally related T-cell receptor hCTLA-4 couldbe observed. The apparent binding affinity for hCD28 of one ofthe isolated affibodies was further improved through fusion toa human Fc fragment fusion partner, resulting in a homodimericversion of the affibody ligand showing avidity effects uponhCD28 binding. Further, a co-culture experiment involvingJurkat T-cells and CHO cell lines tranfected to express eitherhuman CD80 or LFA-3 on the cell surface showed that apreincubation of Jurkat cells with one of the affibody variantsresulted in a specific concentration-dependent inhibition ofthe CD80 induced IL-2 production. This indicates that thisaffibody binds to hCD28 and specifically interferes with theco-stimulation signal mediated via hCD28 and hCD80. ACD28-specific binding protein could have potential as an agentfor various immunotherapy applications. In a second study, anaffinity protein-based strategy was investigated forsite-specific anchoring of proteins onto cellulose for woodfiber engineering purposes. Here, affinity proteins derivedfrom different sources were used for the assembly of acellulosome-like complex for specific and reversible anchoringof affinity domain-tagged reporter proteins to acellulose-anchored fusion protein. A fusion protein between acellulose binding module (Cel6A CBM1) derived from the fungalTrichoderma reesei and a five-domain staphylococcal protein A(SPA) moiety was constructed to serve as a platform for thedocking of reporter proteins produced as fusion to two copiesof a SPA-binding affibody affinity protein (denoted ZSPA-1),selected by phage display technology from a Z domain basedprotein library. In a series of experiments, involving repeatedwashing and low pH elutions, affinity tagged Enhanced GreenFluorescent Protein (EGFP) and Fusarium solani pisi lipasecutinase reporter proteins were both found to be specificallydirected from solution to a region of a cellulose-based filterpaper where the SPA-CBM fusion protein previously had beenpositioned. This showed that the cellulose-anchored SPA-Cel6ACBM1 fusion protein had been stably anchored to the surfacewith retained binding activity and that the interaction betweenSPA and the ZSPA-1 affibody domain was selective. phage display, combinatorial, selection, CD28, cellulosome,cellulose, affibody / NR 20140805

phage display

combinatorial

selection

cd28

cllulosome

cellulose

Developing Peptide Probes for Membrane Lipids via Phage Display:

Kelly, Michael A.

January 2020

Thesis advisor: Jianmin Gao / Lipid reporters are key signaling molecules in a number of biological processes ranging from apoptosis in mammalian cells to novel resistance mechanisms in pathogenic bacteria. Developing probes to target these lipids is a worthy endeavor, especially when better reporters could mean lives saved. This is particularly true considering new antibiotic resistant pathogens emerge every year with evolving lipid compositions. To combat these pathogens and prevent a potential global pandemic, it is imperative to continue the development of novel and innovative probes/drugs to meet this daunting challenge. To fulfill this demand, we must continue to establish new strategies, enhance current technologies and advance scientific understanding. Only by pushing the boundaries of what is currently possible will we remain one step ahead of these diseases. Diseases like mcr-1 positive bacteria, first documented in 2016, remain largely uncontested. Herein, we seek to expand the available probes specific to key lipid reporters for phosphatidylserine, lysyl-phosphatidylglycerol, and phosphoethanolamine lipid A. Cyclic phage libraries were first utilized to target phosphatidylserine, ultimately producing weak binders. Refining our phage display libraries to include reversible covalent warheads allowed for the identification of more potent lipid reporters. In doing so, we have created the tools necessary to interrogate the unique resistance mechanisms expressed by these drug-resistant pathogens. A strong correlation was observed between peptides binding mcr-1 positive strains, LPS modification on the surface of these bacteria, and level of colistin resistance. To our knowledge, these peptides are the only probes capable of demonstrating this correlation. We surmise that the methods discussed here will pave the way for better diagnostic tools for these resistant pathogens. A recurring method of resistance among gram-positive and gram-negative bacteria has been to decorate their surface with positive amines to repel cationic antimicrobial peptides. As such, our current APBA library and the libraries in development in the Gao lab would be ideally suited to target these and other undiscovered resistance mechanisms. / Thesis (PhD) — Boston College, 2020. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

Lipids

mcr-1

Peptides

Phage Display

Phage Display to Identify Peptides Binding to or Penetrating the Mouse Zona Pellucida

Lowe, Jeanette

11 July 1999

The objective of this study was to identify peptide ligands, using phage display techniques, which bind sites on mouse embryos, ovaries, cytoplasmic membranes and/or intracytoplasmic components. Specifically, M13 coliphage 7-mer, 12-mer and 15-mer random peptide libraries were used separately for biopanning. Peptides derived from the amplified pools were sequenced and studied. The phage display for in vivo ovary experiments yielded no pool of peptides after two cycles of biopanning and re-amplification. With the same initial concentration of a random 7-mer or 12-mer library, there were repeating sequences derived after three and four biopanning cycles on mouse embryos and unfertilized ova. The sequences were not distinguishable from a control group. Subsequent experimentation using a random 15-mer library to select for internalized phage-peptides yielded two apparent consensus sequences, RNVPPIFNDVYWIAF (9/32 or 28%) and HGRFILPWWYAFSPS (11/32 or 34%). The 15-mer control group yielded no clones. The deduced peptide sequences were compared to known sequences to ascertain their uniqueness. No significant similarities were found, yielding two possible novel motifs. Through this adapted process of phage display and further research, the phage display technology may be used as a tool in the recognition of specific mouse gamete sites. By identifying binding sites of mouse gametes, the peptides might be exploited as a means of studying the embryo cell surface or cytoplasmic components and mouse sperm-egg interactions. Such peptides may also be used for macromolecule delivery in transfection or transgenesis. / Master of Science

phage display

zona pellucida

mouse embryology

transgenesis

Identifying Peptides that Bind to Human Serum Albumin Using Phage Display for the Development of Sensors that Detect Injury in Military Personnel

Rees, William D.

07 September 2016

No description available.

Biology

Nanotechnology

Phage Display

Albumin

Nanotechnology

Peptide

Développement d' outils innovants pour le diagnostic et la découverte de cibles dans le cancer du sein

Even, Klervi

25 May 2012

Au cours de sa vie, 1 femme sur 9 sera atteinte du cancer du sein, 1 sur 27 sera emportée par cette maladie et 10 à 15 % des patientes développeront des métastases dans les trois années suivant le diagnostic. Le diagnostic précis et personnalisé du cancer du sein ainsi que l'évaluation de son potentiel métastatique est donc un enjeu majeur. Une analyse plus précise des caractéristiques moléculaires d'une tumeur primaire devrait conduire à une médecine personnalisée, un traitement et un suivi plus efficace. La détection de biomarqueurs sériques serait un moyen de diagnostiquer un cancer métastatique. Dans le but de découvrir de nouveaux marqueurs, l'analyse protéomique d'échantillons de patient a un fort potentiel mais souffre de limitations techniques, incluant le manque d'anticorps stables reconnaissant des marqueurs tumoraux d'intérêt. Par l'utilisation de fragments d'anticorps aux propriétés remarquables nommé single domain antibody (sdAb), et grâce à la mise au point d'une stratégie innovante de phages display, ce travail apporte d'importantes réponses en termes de disponibilité d'anticorps, d'analyse spécifique d'échantillon et de découverte de nouvelles cibles. Nous avons élaboré une stratégie permettant la découverte de biomarqueurs et l'isolement des anticorps correspondants. Après la construction de banques de sdAb à partir de lamas immunisés par des biopsies, une nouvelles stratégie de sélection in vitro par phage display, la sélection masquée, nous a permis d'isoler des anticorps spécifiques du cancer du sein. / In a lifetime, 1 in 9 women will develop breast cancer, 1 of 27 will be swept away by the disease and from 10 to 15% of patients will develop metastases within three years of diagnosis. Accurate and personalized diagnosis of breast cancer and the detection of its metastatic potential is a major challenge. It is essential to develop new analytical methods allowing an effective monitoring of breast cancer. A closer analysis of the molecular characteristics of a primary tumor should lead to more effective personalized medicine, treatment and monitoring. The efficient detection of serum biomarkers would be a way to diagnose metastatic cancer and to modify treatment based on these results. Toward this goal, the proteomic analysis of patient samples has great potential but suffers from technical limitations, including the lack of a wide variety of antibodies and tumor marker. By the use of innovative antibody fragments with remarkable properties named single domain antibody (sdAb), and through the development of a new innovative strategy of phage display, this work provides important answers in terms of availability of antibody, specific proteomic analysis of sample and new target discovery. We have developed a strategy allowing the simultaneous discovery of new biomarkers and the isolation of corresponding antibodies. After the construction of sdAb libraries from llamas immunized with biopsies, and using a new in vitro selection strategy by phage display named masked selection, we have isolated breast cancer-specific antibodies.

Anticorps simple domaine

Phage display

Marqueur

Cancer

Diagnostic

Single domain antibody

Phage display

Marker

Cancer

Diagnosis