Global ETD Search

41	Two Dimensional Genetic Approach to the Development of a Controllable Lytic Phage Display System Sheldon, Katlyn 20 February 2013 (has links) Bacteriophage Lambda (λ) has played a historical role as an essential model contributing to our current understanding of molecular genetics. Lambda’s major capsid protein “gpD” occurs on each capsid at 405 to 420 copies per phage in homotrimeric form and functions to stabilize the head and likely to compact the genomic DNA. The interesting conformation of this protein allows for its exploitation through the genetic fusion of peptides or proteins to either the amino or carboxy terminal end of gpD, while retaining phage assembly functionality and viability. The lytic nature of λ and the conformation of gpD in capsid assembly makes this display system superior to other display options. Despite previous reports of λ as a phage display candidate, decorative control of the phage remains an elusive concept. The primary goal of this study was to design and construct a highly controllable head decoration system governed by two genetic conditional regulation systems; plasmid-mediated temperature sensitive repressor expression and bacterial conditional amber mutation suppression. The historical λ Dam15 conditional allele results in a truncated gpD fragment when translated in nonsuppressor, wild-type E. coli cells, resulting in unassembled, nonviable progeny. I sequenced the Dam15 allele, identifying an amber (UAG) translational stop at the 68th codon. Employing this mutant in combination with a newly created isogenic cellular background utilizing the amber suppressors SupD (Serine), SupE (Glutamine), SupF (Tyrosine) and Sup— (wild type), we sought to control the level of incorporation of undecorated gpD products. As a second dimension, I constructed two separate temperature-inducile plasmids whereby expression of either D or D::eGFP was governed by the λ strong λ CI[Ts]857 temperature-sensitive repressor and expressed from the λ PL strong promoter. Our aim was to measure the decoration of the λ capsid by a D::gfp fusion under varying conditions regulated by both temperature and presence of suppression. This was achieved utilizing this controllable system, enabling the measurement of a variable number of fusions per phage based on diverse genetic and physical environments without significantly compromising phage viability. Surprisingly, both SupE and SupF showed similar levels of Dam15 suppression, even though sequencing data indicated that only SupE could restore the native gpD sequence at amino acid 68 (Q). In contrast, SupD (S), conferred very weak levels of suppression, but imparted an environment for very high decoration of gpD::eGFP per capsid, even at lower (repressed) temperatures. The presence of albeit few wild-type gpD molecules allowed for an even greater display than that of the perceived “100%” decoration scenario provided by the nonsuppressor strain. It appears that the lack of wild-type gpD does not allow for the space required to display the maximum number of fusions and in turn creates an environment that affects both phage assembly and therefore phage viability. Finally, the use of Western blotting, confirmed the presence of gpD::eGFP fusion decoration by employing a polyclonal anti-eGFP antibody. The significance of this work relates to the unique structure of λ’s capsid and its ability to exploit gpD in the design of controlled expression, which is guiding future research examining the fusion of different therapeutic peptides and proteins. Furthermore this approach has important implications specifically for the design of novel vaccines and delivery vehicles for targeted gene therapy in which steric hindrance and avidity are important concerns. The execution of this project employed basic bacterial genetics, phage biology and molecular biology techniques in the construction of bacterial strains and plasmids and the characterization of the phage display system. bacteriophage lambda capsid phage display amber suppression temperature-inducible fusion temperate gpD eGFP Biology
42	Polyelectrolyte Building Blocks for Nanotechnology: Atomic Force Microscopy Investigations of Polyelectrolyte-Lipid Interactions, Polyelectrolyte Brushes and Viral Cages Cuéllar Camacho, José Luis 26 July 2013 (has links) (PDF) The work presented here has a multidisciplinary character, having as a common factor the characterization of self-assembled nanostructures through force spectroscopy. Exploring AFM as a tool for characterizing self-assembly and interaction forces in soft matter nanostructures, three different Bio and nonbiological systems where investigated, all of them share the common characteristic of being soft matter molecular structures at the nanoscale. The studied systems in question are: a) Polyelectrolyte – lipid nanocomposites. Single polyelectrolyte adsorption-desorption from supported lipid bilayers, b) Polyelectrolyte brushes and c) Virus-Like particles (VLPs). The scientific interest and industrial applications for each of these different nanostructures is broad, and their potential uses in the near future ranges from smart nanocontainers for drug and gene delivery, surface platforms for molecular recognition to the development of new nanodevices with ultrasensitive external stimuli responsiveness. These nano-structures are constructed following assembly of smaller subunits and belong to representative examples of soft matter in modern nanotechnology. The stability, behavior, properties and long term durability of these self-organized structures depends strongly on the environmental conditions to which they are exposed since their building mechanism is a balance between attractive noncovalent interactions and momentum transmitted collisions due Brownian motion of the solvent molecules. For example a set of long chain molecules firmly attached to one end to a surface will alter their conformation as the space between them is reduced or the environmental conditions are modified (i.e. ionic strength, pH or temperature). For a highly packed condition, this fuzzy surface known as a polyelectrolyte brush will then behave as a responsive material with tunable responsiveness. Thus the objective in the present case was to investigate the change in morphology and the mechanical response of a polyelectrolyte brush to external forces by application of AFM nanoindentations under different ionic strength conditions. The degree of penetration of the AFM tip through the brush will provide insights into the forces exerted by the brush against the tip. Compressions on the brush should aid to characterize its changes in compressibility for different salt concentrations. For the second chosen system, the interaction between two assembled interfaces was investigated at the single molecular level. A multilayered film formed by the consecutive assembly of oppositely charged polyelectrolytes and subsequently coated with a lipid membrane represents a fascinating soft composite material resembling more than a few structural components emerging in living organisms. The fluid bilayer, thus provide a biocompatible interface where additional functionalities can further be integrated (fusion peptides for instance). The smooth polymer cushion confers not only structural flexibility but also adaptability of the chosen substrate properties to be coated. This type of interface could be useful in the development of novel molecular biosensors with single molecule recognition capacities or in the fabrication of assays against pathogenic agents. The aim of this project was to study the molecular binding mechanism between the last polyelectrolyte layer and the lipid head group of the lower lipid leaflet. Understanding this adsorption mechanism between both interfaces, should likewise contribute to improve the fabrication of lipid coated polymeric nano/micro capsules with targeting properties. For example this could be critical in the field of nonviral gene therapy, where the improvement in the design of condensates of nucleic acids and other polymers with lipids (lipoplexes) are of main interest for its posterior use as delivery vectors. Finally, viral capsids were investigated. These naturally occurring assembled nanocontainers within living organisms stand for a remarkable example of nature’s morphological designs. These structures self-assemble from a small number of different proteins occurring in identical copies. The capsid as a self-assembled structure carries multiple functions: compaction of the genome, protection against external chemical threats, target recognition, structural support and finally facilitating the release of the genome into the host cell. It is highly interesting how these different functions are organized within the capsid which consists, for example, in the case of the norovirus of 180 identical copies of one single protein. Therefore, the mechanical stability and elastic properties of virus-like particles of Rubella and Norovirus were investigated by external application of loading forces with an AFM tip. The measurements were performed under conditions relevant for the virus infection mechanism. The applied compressions on these protein shells at pH values mimicking the virus life cycle will aid to learn about possible internal transitions among proteins which may be important for switching between the various functions of the capsid. The choice of two unrelated viral systems with different entry pathways into the cell and with different morphological architectures is expected to reveal crucial information about the stability and mechanical resistance to deformation of these empty membrane-coated and bare viral capsids. This last might provide clues on the stage of particle disassembly and cargo release during the final step of the infection process. Atomic Force Microscopy Nanomechanics Viral capsid Force Spectroscopy single molecule experiments Polyelectrolyte brushes ddc:530
43	Assessment of the immunogenicity of porcine <i>Circovirus</i> 2 (PCV2) vaccines : a prototype vaccine and a lambda display vaccine Angunna 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. phage display vaccine Porcine Circovirus 2 bacteriophage lambda PCV2 ORF2 capsid protein
44	The Effects of N-terminus and Disulfide Bonds of Capsid Protein on Particle Formation and Thermal Stability of Grouper Nervous Necrosis Virus Wang, Chun-Hsiung 26 July 2010 (has links) Grouper nervous necrosis viruses belong to the Betanodavirus genus in the Nodaviridae family that is a group of small, non-enveloped icosahedron viruses. More than 30 species of fish are infected by the betanodaviruses, which cause massive mortality in hatchery-reared larvae and juveniles. The infection causes great economic losses to aquaculture and sea-ranching. To study the effects of N-terminus and disulfide bonds of capsid protein on particle formation and thermal stability of grouper nervous necrosis virus, virus-like particles (VLPs) of dragon grouper nervous necrosis virus (DGNNV) were used. Deletion of 35 residues at the N-terminus completely ruined the VLP assembly. When deletions were restricted to 4, 16, or 25 N-terminal residues, the assembly of VLPs remained. Site-directed mutagenesis was used to investigate the effects of N-terminus of capsid protein on particle formation and thermal stability of grouper nervous necrosis virus. Althought all arginine mutants could produce VLPs, the relative amounts and thermal stabilities of arginine-mutated VLPs were decrease. The VLPs from £GN25-R29A and £GN25 mutants have similar structural properties on particle formation and thermal stability. Therefore, the effects of Arg29 mutations are negligible. The relative amounts and thermal stabilities of VLPs from £GN25-R30A and £GN25-R31A mutants are lower than £GN25-R29A VLP. When 25 amino acids at N-terminus of DGNNV capsid protein were removed, Arg30 and Arg31 are important for particle formation and particel stability. Although particle could form as 12 positively charged amino acids were lost (¡µN25-R293031A), the efficiency of particles assembly were decrease to 1.2 ¡Ó 0.9% as compare to wild-type VLPs (WT-VLPs). Site-directed mutagenesis and chemical reducing reagents were used to investigate the roles of disulfide bonds in particle formation and thermal stability of grouper nervous necrosis virus. The homogeneous particles from C187A, C331A and C187A/C331A mutants are indistinguishable from the native virus and WT-VLPs in their sizes and shapes. C115A and C201A mutants could not produce VLPs. The dissociated capsomers from arginine- or cysteine-mutant VLPs all can be reassembled to icosahedrons with efficiencies as high as 100%. When VLP particles are pre-fabricated, the reducing agent cannot disrupt the VLP icosahedron structure. The thiol reduction only caused effects on the disulfide linkages inside the icosahedrons. £]-mercaptoethanol-treated WT-VLPs could not tolerate the thermal effects at a temperature higher than 70¢XC. Once the disulfide linkages in dissociated capsomers were entirely disrupted by £]-mercaptoethanol treatment, the resulting capsomers could not reassemble back to icosahedron particles.These results indicated that Cys115 and Cys201 were essential for capsid formation of DGNNV icosahedron structure in de novo assembly and reassembly pathways, as well as for the thermal stability of pre-fabricated particles. In the observation of Cryo-EM, the shapes and sizes of the N-terminus truncated particle (£GN25-VLP) are indistinct from the full-length particle (WT-VLP). The maximum diameter of DGNNV is approximately 380 Å. Like that of the insect nodaviruses, the surface morphologies of £GN25-VLP and WT-VLP are consistent with a T = 3 quasi-equivalent lattice. The protrusions (~154 to 192 Å), the inner shell of the capsid (~112 to 154 Å), and the RNA (¡Õ112 Å) were observed in the DGNNV structure. The protrusion domain is consisting of three capsid subunits, and the interactions between these subunits are different. Deletion of 25 residues at the N-terminus did not affect VLPs formation and the structure of £GN25-VLP is similar to WT-VLPs. Resolutions was calculated by Fourier shell correlation, and the resolution of WT-VLPs and £GN25-VLPs is 6.5Å and 11.8Å, respectively. thermal stability assembly virus like particle capsid protein disulfide bond grouper nervous necrosis virus
45	HIV-1 capsid engages nucleoporin NUP153 to promote viral nuclear entry Matreyek, Kenneth Anzai 25 February 2014 (has links) Lentiviruses can infect non-dividing cells, and various cellular nuclear transport proteins provide crucial functions for lentiviral nuclear entry and integration. Genome-wide small interfering RNA screens previously identified nuclear pore complex component nucleoporin 153 (NUP153) as being important for infection by human immunodeficiency virus type 1 (HIV-1). We found that HIV-1 infection of NUP153 depleted cells resulted in normal levels of reverse transcription, a moderate reduction of 2-long terminal repeat circles, and a relatively large reduction in integrated proviruses, consistent with a role for NUP153 during nuclear entry of the HIV-1 pre-integration complex. We ascertained the capsid (CA) to be the major viral determinant for NUP153 dependence during infection, and accordingly observed a direct interaction between the CA N-terminal domain and the phenylalanine-glycine (FG)-repeat enriched NUP153 C-terminal domain (NUP153C). NUP153C fused to the effector domains of the rhesus Trim5alpha restriction factor (Trim-NUP153C) potently restricted HIV-1, providing an intracellular readout for the NUP153C-CA interaction during retroviral infection. Primate lentiviruses and equine infectious anemia virus (EIAV) bound NUP153C under these conditions, results that correlated with direct binding between purified recombinant proteins in vitro. These binding phenotypes moreover correlated with the requirement for endogenous NUP153 function during infection. Mutagenesis experiments identified NUP153C and CA residues important for binding, and different FG motifs within NUP153C mediated binding to HIV-1 versus EIAV CA proteins. HIV-1 CA binding mapped to residues that line a common alpha helix 3/4 hydrophobic pocket that also mediates binding to the small molecule PF-3450074 (PF74) inhibitor and cleavage and polyadenylation specific factor 6 (CPSF6) protein, with Asn57 (Asp58 in EIAV) playing a particularly important role. PF74 and CPSF6 each competed with NUP153C for binding to HIV-1 CA, and significantly higher concentrations of PF74 were needed to inhibit HIV-1 infection in the face of Trim-NUP153C expression or NUP153 knockdown. Correlation between CA mutant viral cell cycle and NUP153 dependencies moreover indicated that the NUP153C-CA interaction underlies the ability of HIV-1 to infect non-dividing cells. We propose that HIV-1 CA binds NUP153 FG motifs to affect viral nuclear import, serving as a novel example of viral hijacking of a fundamental cellular process. Virology Molecular biology Cellular biology Capsid FG motif HIV Lentivirus Nuclear Import Nuclear Pore Complex
46	The functional interplay between TNPO3, CPSF6 and HIV-1 CA Oztop, Ilker 21 October 2014 (has links) Lentiviruses can infect postmitotic cells, indicative of a role for the nucleocytoplasmic transport machinery. Genome-wide RNA interference screens identified transportin 3 (TNPO3) that may regulate human immunodeficiency virus type 1 (HIV-1) preintegration complex (PIC) nuclear import but plays no role during murine leukemia virus (MLV) infection. Independently, TNPO3 was shown to bind HIV-1 integrase (IN), a PIC component, suggesting a potential mechanism for nuclear import. We demonstrated direct binding between TNPO3 and several retroviral INs, which did not correlate with TNPO3 dependency profiles of the respective retroviruses. Infectivity assays employing HIV-1/MLV chimeric viruses ascertained that the capsid (CA) domain, but not IN, was the functional determinant of TNPO3 dependence. A carboxy-terminal truncation mutant of the serine-arginine rich (SR) protein family member, cleavage and polyadenylation specific factor 6 (CPSF6), CPSF6-358, which lacks its RS domain, was shown to restrict HIV-1 PIC nuclear import. We demonstrated that CPSF6 interacts with HIV-1 CA, and a single point mutation in CA, Asn74Asp (N74D), abolished this interaction. N74D also rendered HIV-1 TNPO3-independent and impaired cyclophilin A (CypA) binding to CA. The CA:CPSF6 binding interface, as described in a partial co-crystal structure, defined a surface pocket on CA that faces the CA hexamer:hexamer interspace. Infectivities and CA binding profiles of CA mutants within this pocket or with aberrant CypA-related phenotypes were assessed to compare their CPSF6-358 sensitivity and TNPO3 dependence, which largely correlated. We showed an overall correlation between the CPSF6/CPSF6-358 binding profiles of these HIV-1 CA mutants and their CPSF6-358 sensitivity, whereas TNPO3 binding and TNPO3 dependence did not correlate. Based on similar infectivity profiles of CA mutants and the loss of the RS domain from CPSF6-358 we tested for a direct interaction between CPSF6 and TNPO3. We demonstrated specific binding between recombinant TNPO3 and the CPSF6.RS domain. Mutagenesis experiments suggested a multicontact binding interface. The interaction was downmodulated by Ras-related nuclear protein (Ran)-GTP, indicating that CPSF6 is a bona fide import substrate of TNPO3. Our results support a model where TNPO3 regulates nuclear CPSF6 localization and that in its absence CPSF6 may restrict infection by directly interacting with HIV-1 CA at the hexamer:hexamer interface. Virology Biochemistry Molecular biology capsid CPSF6 CypA HIV Nuclear Import TNPO3
47	Comparing influenza virus hemagglutinin (HA) expression in three different baculovirus expression systems Elliott, Alexandra 05 September 2012 (has links) In this study, the expression of HA, a key immunogenic protein of influenza viruses, in insect cells was compared using three baculovirus expression strategies: protein over-expression, surface (GP64) display, and capsid (VP39) display. Further, a recombinant virus expressing NA, another immunogenic influenza virus protein, was generated and fused to an HA epitope-tag. Western immunoblot using various antibodies, including those against HA, demonstrated the expression of HA and NA for all recombinant viruses. HA showed stronger expression when fused to the C-terminus of VP39 than the N-terminus, but unlike other expression methods, there was no observable cleavage of HA in VP39-displayed viruses. Cells infected with only over-expressed and surfaced-displayed HA were biologically active, and capable of hemadsorption and hemagglutination of chicken red blood cells. These results suggest that GP64 display or over-expression are the most efficacious modes of HA-expression for use as antigen to detect anti-HA antibodies in poultry. / NSERC, OGS, OMAFRA, CPRC Baculovirus capsid display Baculovirus Expression Vector Systems Influenza virus
48	Conformational changes of polyomavirus during cell entry Dolatshahi, Marjan. January 2008 (has links) Similar to other non-enveloped viruses, the mechanism of cell entry for polyomaviruses is poorly understood. The polyomavirus capsid is an icosahedron composed of 72 pentamers of the major capsid protein VP1. There is one copy of minor capsid proteins, VP2 or VP3, at the center of each pentamer. According to previous studies, polyomavirus cell entry is a multi-step process which includes: 1) VP1 binding to sialic acid (SA) on the surface of host cells, 2) interaction of VP1 with alpha4beta1 integrin and 3) subsequent cell penetration. Biochemical studies have shown that SA alters polyomavirus protease sensitivity, suggesting a conformational change. The aim of this study was to determine these conformational changes at the molecular level. Therefore, we used single particle cryo-electron microscopy to construct 3D maps of wild type (WT) murine polyomavirus, WT bound to SA, a mutant with a disrupted integrin binding site, and the mutant bound to SA. Our results reveal that in both WT and mutant viruses, a significant conformational change happens after binding with SA which is seen as an additional ring of density inside the virus. Moreover some negative densities are seen in the difference map of WT and WT bound with SA, which suggests movement of some viral proteins after binding with SA. Polyomavirus -- physiology. Capsid Proteins -- metabolism. Receptors, Virus -- metabolism. N-Acetylneuraminic Acid -- metabolism. Mice.
49	Two Dimensional Genetic Approach to the Development of a Controllable Lytic Phage Display System Sheldon, Katlyn 20 February 2013 (has links) Bacteriophage Lambda (λ) has played a historical role as an essential model contributing to our current understanding of molecular genetics. Lambda’s major capsid protein “gpD” occurs on each capsid at 405 to 420 copies per phage in homotrimeric form and functions to stabilize the head and likely to compact the genomic DNA. The interesting conformation of this protein allows for its exploitation through the genetic fusion of peptides or proteins to either the amino or carboxy terminal end of gpD, while retaining phage assembly functionality and viability. The lytic nature of λ and the conformation of gpD in capsid assembly makes this display system superior to other display options. Despite previous reports of λ as a phage display candidate, decorative control of the phage remains an elusive concept. The primary goal of this study was to design and construct a highly controllable head decoration system governed by two genetic conditional regulation systems; plasmid-mediated temperature sensitive repressor expression and bacterial conditional amber mutation suppression. The historical λ Dam15 conditional allele results in a truncated gpD fragment when translated in nonsuppressor, wild-type E. coli cells, resulting in unassembled, nonviable progeny. I sequenced the Dam15 allele, identifying an amber (UAG) translational stop at the 68th codon. Employing this mutant in combination with a newly created isogenic cellular background utilizing the amber suppressors SupD (Serine), SupE (Glutamine), SupF (Tyrosine) and Sup— (wild type), we sought to control the level of incorporation of undecorated gpD products. As a second dimension, I constructed two separate temperature-inducile plasmids whereby expression of either D or D::eGFP was governed by the λ strong λ CI[Ts]857 temperature-sensitive repressor and expressed from the λ PL strong promoter. Our aim was to measure the decoration of the λ capsid by a D::gfp fusion under varying conditions regulated by both temperature and presence of suppression. This was achieved utilizing this controllable system, enabling the measurement of a variable number of fusions per phage based on diverse genetic and physical environments without significantly compromising phage viability. Surprisingly, both SupE and SupF showed similar levels of Dam15 suppression, even though sequencing data indicated that only SupE could restore the native gpD sequence at amino acid 68 (Q). In contrast, SupD (S), conferred very weak levels of suppression, but imparted an environment for very high decoration of gpD::eGFP per capsid, even at lower (repressed) temperatures. The presence of albeit few wild-type gpD molecules allowed for an even greater display than that of the perceived “100%” decoration scenario provided by the nonsuppressor strain. It appears that the lack of wild-type gpD does not allow for the space required to display the maximum number of fusions and in turn creates an environment that affects both phage assembly and therefore phage viability. Finally, the use of Western blotting, confirmed the presence of gpD::eGFP fusion decoration by employing a polyclonal anti-eGFP antibody. The significance of this work relates to the unique structure of λ’s capsid and its ability to exploit gpD in the design of controlled expression, which is guiding future research examining the fusion of different therapeutic peptides and proteins. Furthermore this approach has important implications specifically for the design of novel vaccines and delivery vehicles for targeted gene therapy in which steric hindrance and avidity are important concerns. The execution of this project employed basic bacterial genetics, phage biology and molecular biology techniques in the construction of bacterial strains and plasmids and the characterization of the phage display system. bacteriophage lambda capsid phage display amber suppression temperature-inducible fusion temperate gpD eGFP Biology
50	Nora virus as a model to study persistent infection in Drosophila melanogaster Habayeb, Mazen January 2009 (has links) Drosophila melanogaster has been widely used as a model organism to study the immune responses against bacteria, fungi, parasites and viruses. Here, I present a D. melanogaster virus as a model to study persistent virus infections. I have discovered and characterized the Nora virus, a small picorna-like RNA virus able to persistently infect D. melanogaster. The Nora virus genome encodes four open reading frames; a feature not present in other picorna-like viruses. The Nora virus is not closely related to any other virus family, but rather is the first virus in a new family of picorna-like viruses. The major replicative proteins of this virus are encoded in the second open reading frame and the capsid proteins are encoded in the fourth open reading frame. The sequence of the capsid proteins are not obviously related to any other previously described protein. By looking at expressed sequence tags (EST) projects, we identified an EST sequence from the parasitic wasp Nasonia which appears to encode proteins that have sequence similarity to the Nora virus capsid proteins. I have shown that the Nora virus persists in the fly intestine however I did not observe serious pathological effects in the infected flies. The virus is shed through feces and the transmission occurs horizontally via the ingestion of virus-contaminated food. Moreover, I observed variability in the viral titers among single flies of the same infected stock. Some flies are able to clear the Nora virus but not others and this phenomenon seems to be titer-dependent. Surprisingly, none of the known Drosophila antiviral responses play a role against the Nora virus. In conclusion, my work shows that studying the Nora virus interaction with the Drosophila immune system can lead to new findings on viral persistence mechanisms of RNA viruses and of Drosophila viral innate immunity. Nora virus Drosophial persistence transmission RNAi capsid proteins

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