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Mapping Specificity Profiles and Protein Interaction Networks for Peptide Recognition ModulesTonikian, Raffi 03 March 2010 (has links)
Protein-protein interactions are of vital importance to the cell as they mediate the assembly of protein complexes that carry out diverse biological functions. Many proteins involved in cellular signaling are built by the combinatorial use of peptide recognition modules (PRMs), which are small protein domains that bind to their cognate ligands by recognizing short linear peptide motifs. Thousands of PRMs are found in nature, requiring improved methods to better elucidate their molecular determinants of binding and to allow accurate mapping of their interaction networks. In this thesis, I describe the development and application of phage-displayed peptide libraries to map the binding specificities of two common PRMs. First, I generated specificity profiles for 82 C. elegans and human PDZ domains that could be organized into a specificity map. The map revealed that PDZ domains have far greater substrate sequence specificity than previously believed, providing significant insights into the relationships between PDZ structure and specificity, and allowing specificity prediction for uncharacterized domains. My results were used to predict both endogenous and pathogenic PDZ interactions. This analysis revealed that viruses have evolved ligands that specifically mimic PDZ domains to subvert host cell immunity.
Second, I analyzed the binding specificity for the SH3 domain family in S. cerevisae. I found that, like PDZ domains, SH3 domains have binding specificities that are more detailed than the conventional classification system. The phage-derived specificity profiles were combined with data from oriented peptide and yeast two-hybrid screening to generate a highly accurate SH3 domain interaction network. Given the prominent role of SH3 domains in endocytosis, the SH3 domain interaction data was used to predict the dynamic localization of several uncharacterized endocytosis proteins, which was subsequently confirmed by cell-based assays.
The application of the techniques described here to other PRM families will significantly improve protein interaction maps for signaling pathways, which will illuminate our understanding of the cell circuitry, allow the use of PRMs as general affinity reagent and detection tools, and guide the development of small molecule inhibitors that mimic their peptide ligands for therapeutic intervention.
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Assessment of the immunogenicity of porcine <i>Circovirus</i> 2 (PCV2) vaccines : a prototype vaccine and a lambda display vaccineAngunna Gamage, Lakshman Nihal 30 March 2010 (has links)
Porcine <i>Circovirus</i> 2 (PCV2) associated diseases (PCVAD) cause economic loss to the global swine industry. Control measures for PCVAD largely depend on the use of PCV2 vaccines. The available commercial PCV2 vaccines contain either inactivated whole virus particles or recombinant PCV2 capsid protein. These preparations most likely contain varying amounts of immune-irrelevant proteins that can cause adverse injection site reactions, with compromised efficacy due to alteration of protective immune epitopes arising during the viral inactivation process. Other constraints include high production cost attributed to propagation of slow growing virus and expression and extraction of recombinant proteins, a requirement for adjuvants, and the induction of a Th2-biased immune response. Hence, development of new PCV2 vaccines is necessary.<p>
There are two recommended PCV2 vaccination strategies. They are i. vaccinating sows, which relies on the passive transfer of maternal immunity to offspring, and ii. immunizing young piglets to induce an active immune response. The piglet vaccination has been shown to confer better protection from mortality. Maternal antibody interference to the induction of an active immune response is an obstacle when piglets are vaccinated at an early age. Can we sidestep this maternal antibody interference? To address this issue, I investigated whether a prototypical PCV2 vaccine, parenterally administered, could override maternally-derived PCV2 antibodies in seropositive piglets. The results of this study were not conclusive. However, they laid the foundation for future studies based upon using varying levels of vaccine antigen with different adjuvants, and administered to piglets with defined maternally derived PCV2 antibodies.<p>
Subsequently, I examined if a new PCV2 vaccine candidate comprised of bacteriophage lambda particles displaying part of the PCV2 capsid protein could induce anti-PCV2 immunity. Initial experiments showed that pigs do not have pre-existing anti-lambda antibodies and thus will not neutralize display particles used as a vaccine at primary vaccination. I produced and characterized lambda phage particles displaying four immunodominant regions of porcine circovirus 2 (PCV2) capsid protein fused to the lambda capsid protein D i.e., D-CAP, phage display particles. Expression of D-CAP in <i>Escherichia coli</i> (<i>E. coli</i>) and its presence in the vaccine preparation was shown by ELISA and Western blots using anti-PCV2 polyclonal antiserum from a gnotobiotic pig. The vaccine, lambda particles displaying PCV2 capsid protein immunogenic epitopes fused to lambda D protein (LDP-D-CAP), administered without an adjuvant induced both humoral and cellular immunity to PCV2 in conventional pigs, as shown by ELISA, Western blots, virus neutralization assay and delayed type hypersensitivity (DTH) reactions. This work produced the first potential phage vaccine to PCV2. In order to further investigate the feasibility of using the lambda display technology. I produced and characterized two additional lambda display particle preparations, LDP-D-FLAG and LDP-D-GFP, displaying a FLAG tag and the green fluorescent proteins, respectively.
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Recombinant Human Growth Hormone Production By Pichia Pastoris And Determination Of Its Interaction With Peptide LigandsInankur, Bahar 01 July 2010 (has links) (PDF)
In this study, the aim was to achieve high concentration of recombinant human growth hormone (rhGH) production by recombinant Pichia pastoris by investigating the effects of various operation parameters and to determine the suitable peptide ligand sequence that shows affinity and specificity to hGH. In this context, firstly the effect of temperature and Tween-20/80 addition on production and cell growth were investigated. While at T=30 and 32° / C, there was no difference, at 27 and 25° / C cell growth slowed down and production decreased significantly. The addition of Tween-20/80 in existence of co-substrate sorbitol did not affect the bioprocess while in absence of sorbitol Tween alone did not show the same positive effect on product formation and cell growth.
Thereafter at T=30° / C, without addition of Tween, three sets of pilot scale bioreactor experiments were performed. In the first set, the effect of methanol feeding rate on bioprocess characteristics were investigated at the specific growth rates of &mu / =0.02, 0.03 and 0.04 h-1. While the highest cell concentration was achieved at &mu / =0.04 h-1, the highest rhGH concentration was achieved at &mu / =0.03 h-1. Secondly, conducting methanol feeding at &mu / =0.03 h-1, pH=5.5 experiment was conducted. The highest cell concentration, 45 g L-1 and maximum rhGH concentration 0.25 g L-1 were achieved at t=18 h of the process. Finally, the effect of batch sorbitol feeding on bioprocess was observed by the addition of 50 g L-1 sorbitol at t=0, 14 and 31 h of the production phase. It was shown that sorbitol addition to the medium increased process duration / hence cells enter stationary phase after a longer production phase. However, the protease concentration continued increasing with respect to time and at the end of the process reached twice the concentration it was obtained with single sorbitol addition case decreasing the rhGH concentration.
In selection of the peptide sequence that shows affinity towards hGH, phage display method was conducted. Additionally the sequences from literature and computational design were used as alternatives. The interaction between these peptides and hGH was investigated by isothermal titration calorimetry and surface plasmon resonance.
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Epitopes mapping and vaccine development of Mycoplasma hyopneumoniae through phage display technologyYang, Wen-Jen 27 January 2003 (has links)
Mycoplasma hyopneumoniae is the etiologic agent causing chronic pneumonia of swine. The lung lesions of swine produce the slower growth rate and lower feed conversion ratio and finally cause economic loss. Although four genome projects of mycoplasma species had been completed, the genome-sequencing project of M. hyopneumoniae also closed to the finished stage. However, only a few genes and proteins of M. hyopneumoniae have been studied, the molecular pathogenic mechanism remains elusive. The research of molecular vaccine is still preliminary.
In order to obtain more information about epitope structures as the basis to develop molecular vaccine against this pathogen, two phage-displayed random heptapeptides libraries were used to identify epitopes recognized by purified IgG of rabbit anti-M. hyopneumoniae hyperimmune serum in this study. Individual phage clones were isolated and verified the binding specificity to the purified IgG by Western blot analysis and competitive ELISA after three rounds of biopanning. The selected clones were further characterized by DNA sequencing analysis and deduced to amino acid sequences. There are six consensus sequences contained tri- to hepta-peptide existing among the selected phage clones by aligning the sequences of foreign amino acids displaying on pIII protein. The consensus sequences may be serving as crucial epitopes of M. hyopneumoniae. By searching the protein database of M. hyopneumoniae deposited in NCBI, some surface proteins were matched by the selected mimotopes. Like P97, the essential protein for attaching to cilia of swine, the deduced epitopes mainly located at a.a. from 365 to 382, 395 to 403 and 436 to 452, the R1 and R2 repeated sequences also matched by the mimotopes.
To evaluate the potential of these mimotopes as effective vaccine, several phage clones were chosen to immunize mice by intraperitoneal and intranasal administration. There are specific antibody responses to these mimotopes existing in serum IgG, fecal extracts and bronchoalveolar lavage fluids IgA. The serum IgG subclass profiles analysis reveals that these are mainly existed in IgG1 subclass. Base on the results of IgG subclass profiles analysis in sera, the results suggest that the phage-derived vaccines mainly activate Th2 cellular immunity pathway with the strategy used in this study. The similar results were found in the inactivated vaccine. The Th2 activation will promote the elimination of extracellular microorganism. Western blotting analysis showed that each serum raised by the phage clones could recognize 2 to 5 mycoplasma proteins. With the results of growth inhibition assay, we found that the selected phage clones CS4 and 58 are better vaccine candidates and some proteins (97 kDa¡B56 kDa and 30 kDa) may play crucial roles in block the bacteria growth.
The advantage was taken of the natural property of M13 phage to infect E. coli, which is initiated by the N terminal of pIII coat protein binding with the F pili of E. coli. Plaque reduction tests were proposed to demonstrate the humoral immunity responses induced by phage-derived vaccine containing the antibodies specifically against the foreign peptide displayed on pIII coat protein.
The present results provide more epitope information of M. hyopneumoniae. The mice immunization results reveal that the phage-displayed mimotopes can be used as potential vaccine candidates. The strategy presented in this study can shorten the time course for vaccine development and provide an alternative pathway for searching vaccine candidates against M. hyopneumoniae.
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Combinatorial protein engineering applied to enzyme catalysis and molecular recognitionEklund, Malin January 2004 (has links)
<p>The recent development of methods for constructing andhandling large collections (libraries) of proteins, from whichvariants with desired traits can be isolated, hasrevolutionized the field of protein engineering. Key elementsof such methods are the various ways in which the genotypes(the genes) and the phenotypes (the encoded proteins) arephysically linked during the process. In one section of thework underlying this thesis, one such technique (phagedisplay), was used to isolateand identify protein librarymembers based on their catalytic or target molecule-bindingproperties.</p><p>In a first study, phage display libraries of the lipolyticenzyme Lipolase from Thermomyces lanuginosa were constructed,the objective being to identify variants with improvedcatalytic efficiency in the presence of detergents. Toconstruct the libraries, nine positions were targeted for codonrandomization, all of which are thought to be involved in theconformational change-dependent enzyme activation that occursat water-lipid interfaces. The aim was to introduce two tothree amino acid mutations at these positions per lipase gene.After confirming that the wt enzyme could be functionallydisplayed on phage, selections with the library were performedutilizing a mechanism-based biotinylated inhibitor in thepresence of a detergent formulation. According to rhodamineB-based activity assays, the fraction of active clonesincreased from 0.2 to 90 % over three rounds of selection.Although none of the variants selected using this approachshowed increased activity, in either the presence or absence ofdetergent compared to the wild type enzyme, the resultsdemonstrated the possibility of selecting variants of theenzyme based on catalytic activity.</p><p>In the following work, phage libraries of the StaphylococcalProtein A (SPA)-derived Z-domain, constructed by randomizationof 13 surface-located positions, were used to isolate Z domainvariants (affibodies) with novel binding specificities. Astargets for selections, the parental SPA domains as well as twopreviously selected affibodies directed against two unrelatedtarget proteins were used. Binders of all three targets wereisolated with affinities (KD) in the range of 2-0.5 µM.One SPA binding affibody (Z<sub>SPA-1</sub>) was shown to bind to each of the fivehomologous native IgG-binding domains of SPA, as well as theZdomain used as the scaffold for library constructions.Furthermore, the Z<sub>SPA-1</sub>affibody was shown to compete with one of thenative domains of SPA for binding to the Fc part of humanantibodies, suggesting that the Z<sub>SPA-1</sub>affibody bound to the Fc-binding surface ofthe Z domain. The majority of the affibodies isolated in theother two selections using two different affibodies as targets,showed very little or no binding to unrelated affibodies,indicating that the binding was directed to the randomizedsurface of their respective targets, analogously toanti-idiotypic antibodies.</p><p>The structure of the wild type Z domain/Z<sub>SPA-1</sub>affibody co-complex was determined by x-raycrystallography, which confirmed the earlier findings in thatthe affibody Z<sub>SPA-1</sub>affibody was shown to bind to the Fc bindingsurface of the Z domain. Further, both the Z domain and the Z<sub>SPA-1</sub>affibody had very similar three helix-bundletopologies, and the interaction surface involved ten out of thethirteen randomized residues, with a central hydrophobic patchsurrounded by polar residues. In addition, the interactionsurface showed a surprisingly high shape complementarity, giventhe limited size of the library used for selections. The Z<sub>SPA-1</sub>affibody was further investigated for use invarious biotechnological applications. In one study, the Z<sub>SPA-1</sub>affibody was successfully recruited as a novelaffinity gene fusion partner for production, purification anddetection of cDNA-encoded recombinant proteins using anSPA-based medium for affinity chromatography. Further, the SPAbinding capability of the Z<sub>SPA-1</sub>affibody was employed for site-specific andreversible docking of Z<sub>SPA-1</sub>affibody-tagged reporter proteins onto an SPAfusion protein anchored to a cellulose surface via acellulose-binding moiety. These generated protein complexesresembles the architecture of so-called cellulosomes observedin cellulolytic bacteria. The results suggest it may bepossible to use anti-idiotypic affibody-binding protein pairsas modules to build other self-assembling types of proteinnetworks.</p><p><b>Keywords:</b>phage display, selection, mechanism-basedinhibitor, affinity domains, crystal structure, Staphylococcusaureus protein A, affinity chromatography, anti-idiotypicbinding pairs, affibody, combinatorial, protein engineering,lipase, cellulosome, assembly.</p>
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Engineering antibody and T cell receptor fragments : from specificity design to optimization of stability and affinityEntzminger, Kevin Clifford 03 February 2015 (has links)
B and T cells comprise the two major arms of the adaptive immune response tasked with clearing and preventing infection; molecular recognition in these cells occurs through antibodies and T cell receptors (TCRs), respectively. Highly successful therapeutics, clinical diagnostics and laboratory tools have been engineered from fragments of these parent molecules. The binding specificity, affinity and biophysical characteristics of these fragments determine their potential applications and resulting efficacies. Thus engineering desired properties into antibody and TCR fragments is a major concern of the multi-billion dollar biopharmaceutical industry. Toward this goal, we (1) designed antibody specificity using a novel computational method, (2) engineered thermoresistant Fabs by phage-based selection and (3) modulated binding kinetics for a single-chain TCR. In the first study, de novo modeling was used to generate libraries of FLAG peptide-binding single-chain antibodies. Phage-based screening identified a dominant design, and activity was confirmed after conversion to soluble Fab format. Bioinformatics analysis revealed potential areas for design process improvement. We present the first experimental validation of this in silico design method, which can be used to guide future antibody specificity engineering efforts. In the second study, the variable heavy chain of a moderately stable EE peptide-binding Fab was subjected to random mutagenesis, and variants were selected for resistance to heat inactivation. Thermoresistant clones where biophysically characterized, and structural analysis of selected mutations suggested general mechanisms of stabilization. Framework mutations conferring thermoresistance can be grafted to other antibodies in future Fab stabilization work. In the third study, TCR fragment binding kinetics for a clonotypic antibody were modulated by varying valence during phage-based selection. Binding affinity and kinetics for representative variants depended on the display format used during selection, and all TCR fragments retained binding to native pMHC antigen. This work demonstrates a general engineering platform for tuning protein-protein interactions. Using a combination of computational design and phage-based screening, we have identified antibodies and TCR fragments with improved binding properties or biophysical characteristics. The optimized variants possess a wider range of potential applications compared to their parent molecules, and we detail engineering methods likely to be useful in the engineering of many other protein-based therapeutics. / text
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Directed Evolution of Peptide Inhibitors of HIV-1 EntryQuinlan, Brian Donald 25 February 2014 (has links)
The conflict between HIV-1 and the host immune system plays out over a time-scale of months and years, and on a grander scale in the co-evolution of lentiviruses and the immune systems of their host species. Directed evolution of HIV-1 entry inhibitors using controlled randomization together with a display system offers a means of recapitulating one side of this conflict in vitro on an accelerated time-scale. To address limitations in existing display systems, we constructed a vector (pDQ1) integrating phage-display and mammalian-expression systems. This vector displays on phage when expressed in bacteria, and as an Fc-fusion when expressed in tissue culture, thus accelerating the iterative process of randomization, display, and characterization. We demonstrated the utility of this vector in the evolution of a CD4-mimetic peptide.
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Haematopoietic Serine Proteases : A Cleavage Specificity AnalysisThorpe, Michael January 2014 (has links)
Mast cells are innate immune cells, historically involved in allergy responses involving IgE. Through this, they have earned a reputation as a fairly detrimental cell type. Their beneficial roles remain somewhat enigmatic although they clearly have the ability to modulate the immune system. This is due to their ability to synthesise many cytokines and chemokines as well as immediately release potent granule-stored mediators. One such mediator is a serine protease, chymase, which has been targeted by pharmaceutical companies developing inhibitors for use in inflammatory conditions. In order to address roles of the proteases, information regarding their cleavage specificity using substrate phage display can help find potential in vivo substrates. The human chymase cleaves substrates with aromatic amino acids in the P1 position and has a preference for negatively charged amino acids in the P2’ position. The molecular interactions mediating this P2’ preference was investigated by site-directed mutagenesis, where Arg143 and Lys192 had a clear effect in this selectivity. As humans express one chymase and rodents express multiple chymases, extrapolating data between species is difficult. Here, the crab-eating macaque was characterised, which showed many similarities to the human chymase including a near identical extended cleavage specificity and effects of human chymase inhibitors. Appropriate models are needed when developing human inhibitors for therapeutic use in inflammatory conditions. The effects of five specific chymase inhibitors in development were also tested. The selectivity of inhibitors was dependent on both Arg143 and Lys192, with a greater effect of Lys192. Identification of residues involved in specific inhibitor interactions is important for selective inhibitor development. Another innate cell type, the NK cell, is important in virus and tumour defence. In the channel catfish, a serine protease from an NK-like cell, granzyme-like I, was characterised. A strict preference for Met in the P1 position was seen, and caspase 6 was identified as a potential in vivo target. This may highlight a novel apoptosis-inducing mechanism from a similar cell type has been conserved for approximately 400 myr. Here, important residues mediating chymases’ specificity and interactions with inhibitors has been addressed, as well as finding a new animal model for providing ways to combat their roles in pathological settings.
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Nanoparticles for Cancer Detection and Therapy: Towards Diagnostic Applications of Quantum Dots and Rational Design of Drug Delivery VehiclesMardyani, Sawitri 31 August 2011 (has links)
This thesis describes observations, techniques and strategies, which contribute towards the development of nanoparticle based detection and treatment of cancer. Quantum dots and biorecognition molecules were studied towards applications in detection and microgels were used in the rational design of a targeted drug delivery vehicle. The fluorescence intensity of quantum dots was examined in buffers commonly used in molecular biology. The fluorescence intensity of ZnS-capped CdSe quantum dots (QDs) was found to vary significantly, depending on the amount of ZnS capping on the QDs or the concentration, pH and type of buffer the QDs were in. Since fluorescence cannot reliably be used to quantify QDs, an alternative quantification method was developed, which does not rely on their fluorescence. This method employs phage display to identify nanoparticle-specific bacteriophage which were then applied in an assay to quantify QDs in environments where absorbance or fluorescence spectroscopy are ineffective. Biorecognition molecules, which can direct nanoparticles to a molecular target, were also identified through phage display. Phage display on whole cells was used to identify a peptide, which was conjugated with QDs to stain HeLa (cervical cancer) cells. A high-throughput phage display screening strategy was also developed, which could enable the simultaneous identification of multiple biorecognition molecules from a single library. QD-encoded microbead barcodes were conjugated to protein targets and then used to screen a phage display library. The beads and the binding phage were then separated using flow cytometry and fluorescence assisted cell sorting. Finally, biorecognition molecules were combined with nanoparticles to create drug delivery vehicles, which were designed to protect, deliver and then release chemotherapeutic drugs through an intracellular pH trigger. PolyNIPAAm and chitosan hydrogels, under 200 nm in diameter, were loaded with chemotherapeutic drugs, conjugated to transferrin and tested in vitro on HeLa cells. These projects demonstrate the great potential in this growing field as well as some of the many challenges that have yet to be overcome.
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Nanoparticles for Cancer Detection and Therapy: Towards Diagnostic Applications of Quantum Dots and Rational Design of Drug Delivery VehiclesMardyani, Sawitri 31 August 2011 (has links)
This thesis describes observations, techniques and strategies, which contribute towards the development of nanoparticle based detection and treatment of cancer. Quantum dots and biorecognition molecules were studied towards applications in detection and microgels were used in the rational design of a targeted drug delivery vehicle. The fluorescence intensity of quantum dots was examined in buffers commonly used in molecular biology. The fluorescence intensity of ZnS-capped CdSe quantum dots (QDs) was found to vary significantly, depending on the amount of ZnS capping on the QDs or the concentration, pH and type of buffer the QDs were in. Since fluorescence cannot reliably be used to quantify QDs, an alternative quantification method was developed, which does not rely on their fluorescence. This method employs phage display to identify nanoparticle-specific bacteriophage which were then applied in an assay to quantify QDs in environments where absorbance or fluorescence spectroscopy are ineffective. Biorecognition molecules, which can direct nanoparticles to a molecular target, were also identified through phage display. Phage display on whole cells was used to identify a peptide, which was conjugated with QDs to stain HeLa (cervical cancer) cells. A high-throughput phage display screening strategy was also developed, which could enable the simultaneous identification of multiple biorecognition molecules from a single library. QD-encoded microbead barcodes were conjugated to protein targets and then used to screen a phage display library. The beads and the binding phage were then separated using flow cytometry and fluorescence assisted cell sorting. Finally, biorecognition molecules were combined with nanoparticles to create drug delivery vehicles, which were designed to protect, deliver and then release chemotherapeutic drugs through an intracellular pH trigger. PolyNIPAAm and chitosan hydrogels, under 200 nm in diameter, were loaded with chemotherapeutic drugs, conjugated to transferrin and tested in vitro on HeLa cells. These projects demonstrate the great potential in this growing field as well as some of the many challenges that have yet to be overcome.
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