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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
41

Selective Fusion-Tag-Catalyzed Protein Immobilizations for Microarray and Biosensor Applications

Voelker, Alden Earl 23 August 2013 (has links)
No description available.
42

Effects of fusion tags on protein partitioning In aqueous two-phase systems and use in primary protein recovery

Hassinen, Cynthia January 2002 (has links)
<p>The two techniques aqueoustwo-phase partitioning and expanded bed adsorption that bothare suitable for primary protein recovery were studied. Most ofthe work was focused on partition in aqueous two-phase systemsand in particular on the possibility to effect the partitionbehaviour by fusion of short peptide tags or protein domains tothe target protein.</p><p>The partitioning of fusionproteins between different variants of the domain tag Z and thenaturally occurring protein DNA Klenow polymerase were studiedin Breox/Reppal aqueous two-phase systems. Most studies wereperformed with cell homogenate. The Breox/Reppal system was infocus because if the fusion protein can be partitioned to theBreox-rich top phase the next step can be a thermoseparatingaqueous two-phase system. When the Breox phase is heated to50°C it switches from a one-phase system to a two-phasesystem resulting in an almost pure water rich top phase andhighly concentrated Breox-rich bottom phase. The Breox can thenbe reused and the protein recovered from the water phase. TheZ-domain was genetically modified in different ways to Z<sub>basic1</sub>, Z<sub>acid2</sub>and Z<sub>trp12</sub>and fused to the Klenow protein to try toenhance partitioning to the Breox-rich phase. From theexperiments it was not possible to observe any effects on thepartition behaviour irrespectively of tested properties of thedomain tag. Despite the absence of domain tag effects highK-values, i.e. partition to the Breox-rich top phase, wereobserved in the Breox/Reppal system. However, the proteinK-values seemed to be rather sensitive to the cell homogenateload and showed a tendency to decrease with increased cellhomogenate load. Also increased phosphate concentration reducedthe K-values. The partitioning of cell debris also seemed todependent on the cell homogenate load. At higher homogenateload (<=20g DW/L) clear Breox-rich top phases were observedwith the cell debris collected in Reppal-rich bottomphases.</p><p>Two different tetrapeptides,AlaTrpTrpPro and AlaIleIlePro were inserted near the C-terminusof the protein ZZT0. The Trp-rich peptide unit stronglyincreased both the partitioning of ZZT0 into the poly(ethyleneglycol) (PEG)-rich phase in a PEG/potassium phosphate aqueoustwo-phase system and its retention on PEG and propylhydrophobic interaction chromatographic columns with potassiumphosphate as eluent in isocratic systems. Both the partitioningand the retention increased with increasing number of Trp-richpeptide units inserted into ZZT0. Insertion of Ile-richtetrapeptide units affected the partitioning and retention to amuch lesser extent. Partition and modelling data also indicateda folding of inserted Trp and Ile tetrapeptide units, probablyto minimise their water contact. It was also investigated howto predict the partitioning of proteins in isoelectricPEG/phosphate aqueous two-phase systems.</p><p>The capture ofß-galactosidase from<i>E. coli</i>cell homogentate (50g DW/L) by metal chelatexpanded bed adsorption was studied. These experiments showedthat capture, with a certain degree of selectivity, andclarification of ß-galactosidase could be achieved from acell homogenate. However, a rather low recovery of about 35 %was obtained at a capacity of 0.25mg/mL of gel. Thus, severalparameters remain to be optimised like the load buffercomposition and the cell homogenate load.</p><p><b>Keywords:</b><i>E. coli</i>, aqueous two-phase systems, fusion proteins,hydrophobic interaction chromatography, expanded bedadsorption, ß-galactosidase, Klenow polymerase, Z-domain,peptide tags</p>
43

Construction Of Various Fusion Proteins Of Recombinant Citrate Synthase From Thermoplasma Volcanium

Ozdogan, Seda 01 June 2004 (has links) (PDF)
In this study, a strategy called gene splicing by overlap extension, &ldquo / Gene SOEing&rdquo / , was used for the construction of the fusion proteins with the purpose of increasing the thermostability of mesophilic enzymes by incorporation of stability domain from a thermostable enzyme. Gene SOEing is a PCR-based approach for recombining DNA molecules at precise junctions irrespective of nucleotide sequences at the recombination site and without the use of restriction endonucleases or ligase. In fusion constructs, as the stability determinant Thermoplasma volcanium citrate synthase (CS) large domain has been used. This gene has recently been cloned in our laboratory. In two different fusions, as fusion partners, dehalogenase II (dehCII) gene of Pseudomonas sp. CBS3 and aminoglycoside-3&#039 / -phosphotransferase-II (APH(3&#039 / )-II) gene of E. coli were employed. Following the Gene SOEing, two fusion products, 1722 bp long CS Large Domain-dehCII and 1750 bp long CS Large Domain-APH(3&#039 / )-II were constructed. Also a 1586 bp long dehCII-APH(3&#039 / )-II fusion was prepared. Three fusion constructs were cloned in E. coli. Cloning was confirmed in each case, by restriction analysis of the isolated plasmids from recombinant colonies. APH(3&#039 / )-II gene associated with CS Large Domain-APH(3&#039 / )-II and dehCII-APH(3&#039 / )-II fusion constructs were successfully expressed in E. coli as revealed by enzyme assay and antibiotic agar plate assay. CS Large Domain-APH(3&#039 / )-II fusion protein retained 9.4% of the original APH(3&#039 / )-II activity after 10 minutes at 60&ordm / C. However, CS Large Domain-dehCII and dehCII-APH(3&#039 / )-II fusions did not display any dehalogenase activity.
44

Molecular and diagnostic aspects of the protein p41 of HHV-6 and silencing of the CD46 receptor by RNA interference /

Xu, Yunhe, January 2003 (has links)
Diss. (sammanfattning) Stockholm : Karol. inst., 2003. / Härtill 4 uppsatser.
45

Regulation of neuronal apoptosis by the mitochondria /

Precht, Thomas A. January 2008 (has links)
Thesis (Ph.D. in Pharmacology) -- University of Colorado Denver, 2008. / Typescript. Includes bibliographical references (leaves 112-125). Free to UCD Anschutz Medical Campus. Online version available via ProQuest Digital Dissertations;
46

Role of c-Jun NH-terminal Kinase in Bcr/Abl Induced Cell Transformation: a dissertation

Hess, Patricia M. 01 April 2003 (has links)
The c-Jun NH2-terminal kinase (JNK) group of kinases include ten members that are created by alternative splicing of transcripts derived from Jnk1, Jnk2 and Jnk3 genes. The JNK1 and JNK2 protein kinases are ubiquitously expressed while JNK3 is expressed in a limited number of tissues. The JNK signaling pathway is implicated in multiple physiological processes including cell transformation. There is growing evidence that JNK signaling is involved in oncogenesis. Nevertheless, the role that JNK plays in malignant transformation is still unclear. The aim of this thesis is to examine the role of JNK in malignant transformation. For this purpose, I used the Bcr/Abl oncogene as a transforming agent. Bcr/Abl is a leukemogenic oncogene that is created by reciprocal translocation between chromosome 9 and 22. The translocation breakpoint is variable and several different Bcr/Abl isoforms have been identified such as Bcr/AblP185 and Bcr/AblP210, whose expression is associated with different types of leukemia. Bcr/Abl activates the JNK signaling pathway in hematopoietic cells and increases AP-1 transcription activity. Furthermore, dominant negative approaches demonstrate that inhibition of c-Jun or JNK prevents Bcr/ Abl-induced cell transformation in vitro. These data implicate the JNK signaling pathway in Bcr/Abl transformation although the role that JNK might have in this process is unclear. Thus, I examined the importance of JNK signaling in Bcr/Abl-induced lymphoid or myeloid transformation. For this purpose I compared Bcr/AblP185- and Bcr/AblP210- induced transformation of wild-type and JNK1-deficient cells using three approaches: in vitro, in vivo and ex vivo. The results obtained with the in vitro approach suggest that both Bcr/AblP185 and Bcr/AblP210 require JNK activity to induce lymphoid transformation. While JNK1-deficiency inhibits Bcr/AblP210 oncogenic potential in lymphoid cells both in vitro and in vivo, pharmacological inhibition of JNK activity (JNK1 and/or JNK2) blocked Bcr/AblP185 induced malignant proliferation in vitro. The differential requirement for JNK observed in the two Bcr/Abl isoforms can be ascribed to the presence in Bcr/AblP210 of the Dbl domain which can activate the JNK pathway in vitro. In the case of Bcr/AblP210, JNK1 is critical for the survival of the ex vivo derived transformed lymphoblasts upon growth factor removal. This result correlates with the fact that mice reconstituted with Bcr/AblP210 transformed Jnk1-l- bone marrow showed normal malignant lymphoid expansion in the bone marrow yet they had reduced numbers of lymphoblast in the bloodstream and lacked peripheral organ infiltration. Thus JNK1 is essential for the survival of the transformed lymphoblast outside the bone marrow microenvironment in Bcr/AblP210induced lymphoid leukemia. Interestingly, while JNK1 is essential for lymphoid transformation, it is dispensable for the proliferation of transformed myeloblasts. Taken together these results indicate that the JNK signaling pathway plays an essential role in the survival of Bcr/AblP210 lymphoblasts and that JNK-deficiency decreases the leukomogenic potential of Bcr/AblP210 in vivo. Thus, cell survival mediated by JNK may contribute to the pathogenesis of proliferative diseases.
47

Characterization of the Relationship Between Measles Virus Fusion, Receptor Binding, and the Virus-Specific Interaction Between the Hemagglutinin and Fusion Glycoproteins: a Dissertation

Corey, Elizabeth Ann 17 May 2006 (has links)
Measles (MV) virions, like those of other enveloped viruses, enter cells by fusing their lipid membranes with those of the target host cells. Additionally, infected tissues often possess giant multinucleate cells, known as syncytia, which are formed by fusion of infected cells with uninfected neighbors. Expression of both the MV attachment (H) and fusion (F) proteins is required for membrane fusion. MV H mediates receptor binding in order to bring the two membranes into close proximity prior to F activation and is thought to trigger F activation through a specific interaction between the two proteins. Although measles H and F are efficiently transported to the cell surface when expressed independently, evidence has been reported in support of an intracellular interaction between the two proteins that can be detected using an ER co-retention approach. However, it was not determined if the putative co-retention was specific to the two measles glycoproteins, as is their ability to complement each other for efficient fusion promotion. Thus, in this thesis, the formation of an intracellular complex between MV H and F was re-examined. Consistent with the formation of an intracellular complex, cell surface expression and receptor binding of untagged wt MV H is slightly reduced by co-expression of an excess of ER-tagged MV F compared to co-expression with wt F. However, the reduction in surface expression is non-specific in that it can also be induced with heterologous proteins of NDV, which lack significant homology with those of MV. Although this approach did not detect a specific intracellular interaction between MV H and F, it cannot be ruled out that there is a weak association of the proteins that is undetectable by this method. This led to the use of an alternative approach to investigate the cellular site(s) of interaction between the measles H and F proteins. Consistent with a cell surface interaction between MV H and F, the combination of surface biotinylation and co-immunoprecipitation detects formation of a virus-specific H-F complex. Approximately, 21% of the total amount of MV H at the cell surface can be captured with MV F using an antibody against the latter protein. Two complementary approaches were used to address the relationship between this cell surface interaction and receptor recognition by MV H. First, the proteins were co-immunoprecipitated from the surface of Chinese hamster ovary (CHO) cells, which do not express either MV receptor, CD46 or CD150. Similar levels of MV H can be co-immunoprecipitated with F from the surfaces of parental CHO cells and stably transfected cells that express, human CD46 (CHO-CD46), indicating that binding to CD46 is not the trigger for the H-F interaction. Second, MV H proteins, carrying mutations that dramatically reduce CD46 binding, were shown to co-immunoprecipitate efficiently with F from the surface of HeLa cells. Significantly, these results indicate that MV H and F interact in the absence of, and thus prior to, receptor binding. This is in direct contrast to the NDV HN-F cell surface interaction, which is thought to be triggered by receptor binding. Identification of the domains of the para myxovirus attachment and fusion proteins that mediate membrane fusion activities is an essential part of understanding the mechanism of fusion. As a result of the H-F interaction prior to receptor binding, MV H attachment to its cellular receptor must result in conformational changes that trigger activation of the F protein. Site-directed mutagenesis analyses of two regions of MV H indicate that a HR domain in the stalk of the attachment protein is essential to the ability of H to activate F. However, either it is not the only region of H that interacts with F or it is indirectly involved in F activation because mutations in the HR do not disrupt MV H-F complex formation at the cell surface. Additionally, the functional interaction between MV H and F may be mediated, at least in part, by Loop 1 of the amino terminus of the C-rich region of the fusion protein. However, the exact role of this region of the F protein in fusion promotion remains to be determined. Importantly, the cell surface interaction between MV H and F proteins appears to be mediated by more that one region of each protein. In contrast to NDV, in no case has a definitive link between any single amino acid difference in MV H or F and an inability to form the cell surface H-F complex been established. In conclusion, the data presented in this dissertation support a model of measles membrane fusion in which the Hand F proteins form a complex prior to receptor recognition. This complex may hold F in its meta-stable pre-fusion state until binding of H to receptors at the cell surface triggers dissociation of the complex, releasing F to assume its fusogenic form. Importantly, these data also indicate that, although paramyxoviruses may all use the same general process. for promotion of membrane fusion, the mechanism may vary in multiple aspects. A more complete understanding of the means by which measles promotes membrane fusion may direct the development of specific strategies aimed at interfering with the early stages of infection.
48

Characterization of the Interaction Between the Attachment and Fusion Glycoproteins Required for Paramyxovirus Fusion: a Dissertation

Melanson, Vanessa R. 16 December 2005 (has links)
The first step of viral infection requires the binding of the viral attachment protein to cell surface receptors. Following binding, viruses penetrate the cellular membrane to deliver their genome into the host cell. For enveloped viruses, which have a lipid bilayer that surrounds their nucleocapsids, entry into the host cell requires the fusion of viral and cellular membranes. This process is mediated by viral glycoproteins located on the surface of the virus. For many enveloped viruses, such as influenza, Ebola, and human immunodeficiency virus, the fusion protein is responsible for mediating both attachment to cellular receptors and membrane fusion. However, paramyxoviruses are unique among fusion promoting viruses because their receptor binding and fusion activities reside on two separate proteins. This unique distribution of functions necessitates a mechanism by which the two proteins can transmit the juxtaposition of the viral and host cell membranes, mediated by the attachment protein (HN/H), into membrane fusion, mediated by the fusion (F) protein. This mechanism allows for paramyxoviruses to gain entry into and spread between cells, and therefore, is an important aspect of virus infection and disease progression. Despite the conservation of receptor binding activity among members of the Paramyxovirinaesubfamily, for most of these viruses, including Newcastle disease virus (NDV), heterologous HN proteins cannot complement F in the promotion of fusion; both the HN and F proteins must originate from the same virus. This is consistent with the existence of a virus-specific interaction between the two glycoproteins. Thus, one or more domains on the HN and F proteins is thought to mediate a specific interaction between them that is an integral part of the fusion process. Therefore, the primary focus of this thesis is the identification of the site(s) on HN that directly contacts F in the HN-F interaction. The ectodomain of the HN protein consists of a stalk and a terminal globular head. Analysis of the fusion activity of chimeric paramyxovirus HN proteins indicates that the stalk region of HN determines its F protein specificity. The first goal of this research was to address the question of whether the stalk not only determines F-specificity, but does so by directly mediating the interaction with F. To establish a correlation between the amount of fusion and the extent of the HN-F interaction, a specific and quantitative co-immunoprecipitation assay was used that detects the HN-F complex at the cell surface. As an initial probe of the role of the HN stalk in mediating the interaction with F, N-glycans were individually added at several positions in the region. N-glycan addition at positions 69 and 77 in the stalk specifically and completely block both fusion and the HN-F interaction without affecting either HN structure or its other activities. However, though they also prevent fusion, N-glycans added at other positions in the stalk also modulate activities that reside in the globular head of HN. This correlates with an alteration of the tetrameric structure of the protein as indicated by sucrose gradient sedimentation analyses. These additional N-glycans likely indirectly affect fusion, perhaps by interfering with changes in the conformation of HN that link receptor binding to the fusion activation of F. To address the issue of whether N-glycan addition at any position in HN would abolish fusion, an N-glycan was added in another region at the base of the globular head of HN (residues 124-152), which was previously predicted by a peptide-based analysis to mediate the interaction with F. HN carrying this additional N-glycan exhibits significant fusion promoting activity, arguing against this site being part of the F-interactive domain in HN. These data support the idea that the F-interactive site on HN is defined by the stalk region of the protein. Site-directed mutagenesis was used to begin to explore the role of individual residues in the stalk in the interaction with F. The characteristics of the F-interactive domain in the stalk of HN are that it is a conserved motif with enough sequence heterogeneity to account for the specificity of the interaction. One such region that meets these requirements is the intervening region (IR) (residues 89-95); a non-helical domain situated between two conserved heptad repeats. Several amino acid substitutions for a completely conserved proline residue in this region impair not only fusion and the HN-F interaction, but also decrease neuraminidase activity in the globular domain and alter the structure of the protein, suggesting that the substitutions indirectly affect the HN-F interaction. Substitutions for L94 also interfere with fusion, but have no significant effect on any other HN function or its structure. Amino acid substitutions at two other positions in the IR (A89 and L90) also modulate only fusion. In all cases, diminished fusion correlates with a decreased ability of the mutated HN protein to interact with F at the cell surface. These findings indicate that the IR is critical to the role of HN in the promotion of fusion and are consistent with its direct involvement in the interaction with the homologous F protein. These are the first point mutations in the HN protein for which a correlation has been demonstrated between the extent of the HN-F interaction and the amount of fusion. This argues strongly that the co-IP assay is an accurate reflection of the HN-F interaction. The second goal of this research was to address the HN-F interaction from the perspective of the F protein by investigating the relationship between receptor binding, the HN-F interaction, and fusion using a highly fusogenic form of the F protein. It has previously been shown that an L289A substitution in NDV F eliminates the requirement for HN in the promotion of fusion and enhances HN-dependent fusion above wild-type (wt) levels. Here, it was shown that the HN-independent fusion exhibited by L289A-F in Cos-7 cells cannot be duplicated in BHK cells. However, when L289A-F is co-expressed with wt HN, enhanced fusion above wt levels is observed in BHK cells. Additionally, when L289A-F is co-expressed with IR-mutated HN proteins previously shown to promote low levels of fusion with wt F, a 2.5-fold increase in fusion was observed. However, similar to wt F, an interaction between L289A-F and the IR-mutated HN proteins was not detected. These results imply that the attachment function of HN, as well as the conformational change in L289A-F, are necessary for the enhanced level of fusion exhibited by HN proteins co-expressed with L289A-F. Indeed, two MAbs detected a conformational difference between L289A-F and the wt F protein. These findings support the idea that the L289A substitution converts F to a form that is less dependent on an interaction with HN for conversion to the fusion-active form. The last goal of this research was to address the cellular site of the HN-F interaction, still a controversial issue based on conflicting data from studies of different paramyxoviruses, using various approaches. This is a particular point of interest, as it speaks to the mechanism by which the HN-F interaction regulates fusion. Thus, NDV HN and F were successfully retained intracellularly with a multiple arginine or KK motif, respectively. The results of Endoglycosidase H resistance and F cleavage studies indicate that the mutated proteins, HN-ER and F-ER, are retained in a compartment prior to the medial-Golgi apparatus and that they are unable to interact with a high enough affinity to co-retain or even cause reduced transport of their wt partner glycoproteins. This is consistent with the HN-F interaction occurring at the cell surface, possibly triggered by receptor binding. In conclusion, this thesis presents evidence to argue that the IR in the stalk of the NDV HN protein directly mediates the interaction with the F protein that is necessary for fusion. Overall, the data presented in this thesis extend the current knowledge of the mechanism by which the paramyxovirus attachment protein can trigger the F protein to initiate membrane fusion. A clear understanding of this process has the potential to identify new anti-viral strategies, such as small molecule inhibitors, aimed at controlling paramyxovirus infection by interfering with early steps in the virus infection cycle.
49

Effects of fusion tags on protein partitioning In aqueous two-phase systems and use in primary protein recovery

Hassinen, Cynthia January 2002 (has links)
The two techniques aqueoustwo-phase partitioning and expanded bed adsorption that bothare suitable for primary protein recovery were studied. Most ofthe work was focused on partition in aqueous two-phase systemsand in particular on the possibility to effect the partitionbehaviour by fusion of short peptide tags or protein domains tothe target protein. The partitioning of fusionproteins between different variants of the domain tag Z and thenaturally occurring protein DNA Klenow polymerase were studiedin Breox/Reppal aqueous two-phase systems. Most studies wereperformed with cell homogenate. The Breox/Reppal system was infocus because if the fusion protein can be partitioned to theBreox-rich top phase the next step can be a thermoseparatingaqueous two-phase system. When the Breox phase is heated to50°C it switches from a one-phase system to a two-phasesystem resulting in an almost pure water rich top phase andhighly concentrated Breox-rich bottom phase. The Breox can thenbe reused and the protein recovered from the water phase. TheZ-domain was genetically modified in different ways to Zbasic1, Zacid2and Ztrp12and fused to the Klenow protein to try toenhance partitioning to the Breox-rich phase. From theexperiments it was not possible to observe any effects on thepartition behaviour irrespectively of tested properties of thedomain tag. Despite the absence of domain tag effects highK-values, i.e. partition to the Breox-rich top phase, wereobserved in the Breox/Reppal system. However, the proteinK-values seemed to be rather sensitive to the cell homogenateload and showed a tendency to decrease with increased cellhomogenate load. Also increased phosphate concentration reducedthe K-values. The partitioning of cell debris also seemed todependent on the cell homogenate load. At higher homogenateload (&lt;=20g DW/L) clear Breox-rich top phases were observedwith the cell debris collected in Reppal-rich bottomphases. Two different tetrapeptides,AlaTrpTrpPro and AlaIleIlePro were inserted near the C-terminusof the protein ZZT0. The Trp-rich peptide unit stronglyincreased both the partitioning of ZZT0 into the poly(ethyleneglycol) (PEG)-rich phase in a PEG/potassium phosphate aqueoustwo-phase system and its retention on PEG and propylhydrophobic interaction chromatographic columns with potassiumphosphate as eluent in isocratic systems. Both the partitioningand the retention increased with increasing number of Trp-richpeptide units inserted into ZZT0. Insertion of Ile-richtetrapeptide units affected the partitioning and retention to amuch lesser extent. Partition and modelling data also indicateda folding of inserted Trp and Ile tetrapeptide units, probablyto minimise their water contact. It was also investigated howto predict the partitioning of proteins in isoelectricPEG/phosphate aqueous two-phase systems. The capture ofß-galactosidase fromE. colicell homogentate (50g DW/L) by metal chelatexpanded bed adsorption was studied. These experiments showedthat capture, with a certain degree of selectivity, andclarification of ß-galactosidase could be achieved from acell homogenate. However, a rather low recovery of about 35 %was obtained at a capacity of 0.25mg/mL of gel. Thus, severalparameters remain to be optimised like the load buffercomposition and the cell homogenate load. <b>Keywords:</b>E. coli, aqueous two-phase systems, fusion proteins,hydrophobic interaction chromatography, expanded bedadsorption, ß-galactosidase, Klenow polymerase, Z-domain,peptide tags / NR 20140805
50

Role of Host Cellular Membrane Raft Domains in the Assembly and Release of Newcastle Disease Virus: A Dissertation

Laliberte, Jason P. 01 April 2008 (has links)
Newcastle disease virus (NDV) belongs to the Paramyxoviridae, a family of enveloped RNA viruses that includes many important human and animal pathogens. Although many aspects of the paramyxovirus life cycle are known in detail, our understanding of the mechanisms regulating paramyxovirus assembly and release are poorly understood. For many enveloped RNA viruses, it has recently become apparent that both viral and host cellular determinants coordinate the proper and efficient assembly of infectious progeny virions. Utilizing NDV as a model system to explore viral and cellular determinants of paramyxovirus assembly, we have shown that host cell membrane lipid raft domains serve as platforms of NDV assembly and release. This conclusion was supported by several key experimental results, including the exclusive incorporation of host cell membrane raftassociated molecules into virions, the association of structural components of the NDV particle with membrane lipid raft domains in infected cells and the strong correlation between the kinetics of viral protein dissociation from membrane lipid raft domains and incorporation into virions. Moreover, perturbation of infected cell membrane raft domains during virus assembly resulted in the disordered assembly of abnormal virions with reduced infectivity. These results further established membrane raft domains as sites of virus assembly and showed the integrity of these domains to be critical for the proper assembly of infectious virions. Although specific viral protein-protein interactions are thought to occur during paramyxovirus assembly, our understanding of how these interactions are coordinated is incomplete. While exploring the mechanisms underlying the disordered assembly of non-infectious virions in membrane raft-perturbed cells, we determined that the integrity of membrane raft domains was critical in the formation and virion incorporation of a complex consisting of the NDV attachment (HN) and fusion (F) proteins. The reduced virus-to-cell membrane fusion capacity of particles released from membrane raft-perturbed cells was attributed to an absence of the HN – F glycoprotein-containing complex within the virion envelope. This result also correlated with a reduction of these glycoprotein complexes in membrane lipid raft fractions of membrane raft-perturbed cells. Specifically, it was determined that the formation of newly synthesized HN and F polypeptides into the glycoprotein complex destined for virion incorporation was dependent on membrane lipid raft integrity. Finally, a novel virion complex between the ribonucleoprotein (RNP) structure and the HN attachment protein was identified and characterized. Unlike the glycoprotein complex, the detection of the RNP – HN protein-containing complex was not affected by membrane raft perturbation during virus assembly in the cell. The biological importance of this novel complex for the proper assembly of an infectious progeny virion is currently under investigation. The results presented in this thesis outline the role of host cell membrane lipid raft domains in the assembly and release processes of a model paramyxovirus. Furthermore, the present work extends our understanding of how these particular host cell domains mechanistically facilitate the ordered assembly and release of an enveloped RNA virus.

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