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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.
1

Structural and functional characterization of yellow head virus proteins

Chumporn Soowannayan Unknown Date (has links)
Abstract Yellow head virus (YHV) has caused mass mortalities in Penaeus monodon shrimp farmed throughout Southeast Asia since it was first discovered in the early 1990’s. YHV possesses a positive-sense, single-stranded RNA genome and a rod-shaped enveloped virion. Together with the closely related gill-associated virus (GAV) identified in P. monodon shrimp in Australia, it is classified in the genus Okavirus, family Roniviridae within the order Nidovirales. YHV particles contain only three structural proteins, a nucleocapsid (N) protein (p20) protein and two envelope glycoproteins gp116 and gp64. In this study, the glycosylation status of gp116 and gp64 extracted from YHV virions was characterized in detail, including the identification of active N-linked glycosylation sites and the nature of the attached carbohydrates. This was achieved by optimizing and applying a combination of methods that included SDS-PAGE followed by carbohydrate-specific staining of gels or probing of membrane-bound proteins using lectins with different carbohydrate specificities, enzymatic removal of N-linked carbohydrates and a variety of mass spectrometry techniques. In these analyses, it was found that N-linked glycans are the major contributor to the higher estimated mass of gp116 and gp64 by SDS-PAGE compared to those estimated from their deduced amino acid sequences. Neither gp116 nor gp64 were found to posses O-linked glycans. Mannose residues were identified to be the major glycan component of carbohydrates linked to gp116 and gp64 and are possibly the sole component of carbohydrate linked to gp64. Unlike gp64, other glycans such as terminal N-acetyl--D-galactosamine and N-acetyl--D-glucosamine were identified to be attached to gp116. Assuming that glycosylation processes in shrimp mimic those of vertebrates that are known in more detail, the nature of the glycans attached to gp116 suggests that they might be added and modified during the transportation of the protein from the endoplasmic reticulum (ER) to the trans-Golgi network (TGN). Mass spectrometry analyses of tryptic peptides derived from the native glycoproteins and following their enzymatic deglycosylation, generated approximately 81% (gp116) and 66% (gp64) coverage of their predicted amino acid sequences. Detailed mass spectrometry analyses of peptides derived from the deglycosylated proteins identified that most of the potential N-linked glycosylated site in the virion envelope glycoproteins, 6 of 7 present in gp116 and 3 of 4 present in gp64 were identified to be modified by glycans. In gp116, one site was not identified and in gp64 one site was not utilized. As phosphorylation has been shown to affect nucleocapsid protein (N) functioning in vertebrate nidoviruses, SDS-PAGE using two phosphoprotein-specific staining methods, as well as mass spectrometry methods, were employed to examine whether the YHV N protein present in virions is phosphorylated. The protein staining methods provided contradicting results and no phosphate-containing peptides were identified by mass spectrometry. The apparent absence of phosphate in the N protein was also supported by its isoelectric point (pI ~10) determined by isoelectric focusing and two-dimensional electrophoresis (2-DE) analysis, which was very similar to that predicted (pI = 9.98) from its deduced amino acid sequence. Taken together, the data suggest that the YHV N protein encapsulated within virions is not phosphorylated. The RNA-binding capability of the GAV N protein was assessed using an electrophoretic mobility shift assay (EMSA) technique. Full-length and variously truncated forms of the GAV N protein expressed in bacteria were assessed in the assays. It was found that the full-length recombinant N protein bound to RNA in a sequence non-specific manner. Analysis of the five truncated N protein constructs localized the RNA-binding domain to a 50 amino acid sequence in the N-terminal region residing between Met11 and Arg60. A motif rich in proline and arginine residues, which are commonly found in other RNA-binding proteins, occurred in first 18 amino acids of this region. Although RNA-binding was not sequence-specific, the data suggest that this region of the GAV N protein is the most likely site at which it interacts with and nucleates viral genomic RNA during nucleocapsid formation. A synthetic peptide spanning the 18 amino acid of the putative RNA-binding domain was shown to possess RNA-binding properties similar to the recombinant protein fragment. These results indicated that the 18 amino acid, proline and arginine rich motif (MPVRRPLPPQPPRNARLI) in the N-terminal region of the GAV N protein confers its RNA-binding function. Using an immuno-co-precipitation assay, a host protein was found to interact abundantly with the GAV N protein in infected lymphoid organ cells. Mass spectrometry analysis identified the protein as -actin. Immuno-histochemistical double-labeling methods in conjunction with observations made using confocal and electron microscopy revealed that actin and the N protein were co-located in cytoplasm of infected cells. Electron microscopy suggested that interaction of the two proteins occurs before nucleocapsid envelopment within virions, suggesting that -actin might be involved in transporting the N protein or the nucleocapsid from their sites of synthesis to the rough endoplasmic reticulum where the virion acquires its envelopes. In summary, the research described in this thesis has advanced understanding of the YHV/GAV proteome through the identification of the glycosylation sites in the envelope glycoproteins gp116 and gp64, and demonstrating that nucleocapsid protein encapsulated within virion is unlikely to be phosphorylated. Functional studies have also shown that the nucleocapsid protein binds RNA non-specifically through an 18 amino acid domain near its N-terminus and that it binds and co-localizes with -actin in infected cells, suggesting that -actin may play role in trafficking N protein in infected cells.

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