The Sensitivity of Adenovirus and Herpes simplex virus to Honey

Littlejohn, Emma Sophie Vout

January 2009

Honey has been used for centuries as a medicine to treat various ailments and infections. A large amount of research has established that honey has potent antibacterial activity. However, the sensitivity to honey of viral species that cause infections has been studied in only a small number of cases. The aim of this study was to obtain data to clarify and extend knowledge obtained from these previous studies of honey's antiviral activity, and especially study those viruses that cause localised infections which have limited or no therapy available, which are suitable to treatment with topically applied honey. The susceptible A549 cell line and viral isolates of Adenovirus serotypes 1, 3, and 8, and Herpes simplex virus serotypes 1 and 2, were provided by the Waikato Hospital Virology Laboratory. A number of types of honey were investigated from a range of sources: Manuka honey with high concentrations of methylglyoxal, unique manuka factor activity, and phenolics, Honeydew and Rewarewa honeys which have high antioxidant activity, and Ling Heather honey which is high in phenolic compounds. These honeys were selected due to their range of characteristic activities in order to make comparisons with antiviral activity. A variety of tests using cell culture were developed to evaluate the sensitivity of the viruses to whole honey. Each test scored and monitored the development of morphological changes to the cells, to observe whether the honey treatment can prevent the development of these changes known as viral cytopathic effect. These included tests for: protection, in which the cells were pre-treated with, and iii incubated either with or without honey; prevention, where honey was used to treat infected cells, and in plaque reduction assays, to examine whether it can reduce the resultant number of plaques; and neutralisation, in which the virus was directly exposed to the honey for a defined period. It was found with each type of test using cell culture that many of the honeys studied can lower the severity of viral cytopathic effect or delay its onset compared with the development observed with virus that was not treated with honey. This can suggest that the antiviral activity may be a feature of more than one type of honey. In general the antiviral effect increased with the concentration of honey and time the virus was exposed to it. Manuka honey M116 at a concentration of 10% was effective in preventing the development of viral cytopathic effect of each of virus, after the viruses at concentrations in excess of the tissue culture infectious dose had been exposed to the honey for 8 hours. Enzyme-linked immunosorbant assays were used to measure the effect the successful treatments found in the extended neutralisation experiments had on viral surface proteins necessary for viral entry into the cells. The results using this technique suggested that there was very little virus present in the samples that had been treated with honey and with the untreated virus. Therefore it could not be shown whether the honey was acting via this mechanism. It is concluded from the findings in this study that honey is likely to be an effective antiviral treatment for the therapy of localised viral infections, this needs to be verified by clinical trials.

Honey

Antiviral

Virus

Treatment for viral infection

The role of a geminiviral DNA β satellite in viral pathogenicity and movement

Saeed, Muhammad

January 2006

Geminiviruses ( family Geminiviridae ) have circular single - stranded genomes encapsidated in twinned quasi - isometric particles and are responsible for major crop losses worldwide. The largest genus, Begomovirus, comprises viruses transmitted by the whitefly Bemisia tabaci. Most begomoviruses have bipartite genomes, termed DNA A and DNA B. The DNA A component encodes proteins required for viral DNA replication and encapsidation whereas the DNA B encodes two proteins that are essential for systemic movement. A small number of begomoviruses have a monopartite DNA genome that resembles the DNA A of bipartite begomoviruses. This DNA carries all gene functions for replication and pathogenesis. Specific small circular single - stranded DNA satellites containing a single open reading frame ( ORF ), termed DNA β, have recently been found in association with certain monopartite begomovirus infections. They comprise about 1350 nucleotides and require a helper begomovirus for replication and encapsidation. DNA β contributes to the production of symptoms and enhanced helper virus accumulation in certain hosts. This study examines the role of DNA β satellite in viral pathogenicity and movement in the host plant. Infectivity analysis of Tomato leaf curl virus and DNA β having mutation in the C1 and V1 ORF indicated that the complementary - sense ORF, βC1, is responsible for inducing disease symptoms in Nicotiana tabacum. An ORF present on the plus strand, βV1, appeared to have no role in pathogenesis. Tobacco plants transformed with the βC1 ORF under the control of the Cauliflower mosaic virus 35S promoter, or with a dimeric DNA β exhibited severe disease - like phenotypes, while plants transformed with a mutated version of βC1 appeared normal. Northern blot analysis of RNA from the transgenic plants using strand - specific probes identified a single complementary - sense transcript. The transcript carried the full βC1 ORF encoding a 118 amino acids product. It mapped to the DNA β nucleotide ( nt ) position 186 - 563 and contained a polyadenylation signal 18 nt upstream of the stop codon. A TATA box was located 43 nt upstream of the start codon. These results indicate that βC1 protein is responsible for DNA β induced disease symptoms. Tomato leaf curl New Delhi virus ( ToLCNDV ) is a bipartite begomovirus in which both DNA A and DNA B are required for systemic infection. Inoculation of tomato plants with ToLCNDV DNA A alone induced local but not systemic infection whereas co - inoculation with DNA A and the DNA β resulted in systemic infection. The presence of both DNA A and the DNA β in systemically infected tissues and the absence of DNA B was confirmed by probe hybridization. DNA β containing a disrupted βC1 ORF did not mobilize the DNA A for systemic infection. Co - inoculation of plants with DNA A and a construct of βC1 ORF, under the control of the Cauliflower mosaic virus 35S promoter, resulted in the systemic movement of the DNA A. βC1 fused to GFP accumulated around and inside the nucleus, at the periphery of tobacco and onion epidermis cells and co - localized with the endoplasmic reticulum. This distribution would be consistent with βC1 mediating intra cellular transport from the nucleus to the plasma membrane. These results showed that the βC1 protein can replace the functions of DNA B in allowing the systemic movement of a bipartite geminivirus DNA A. / Thesis (Ph.D.)--School of Agriculture, Food and Wine, 2006.

Molecular epidemiology and characterization of the receptor binding of porcine circovirus type 2 (PCV2)

Ma, Ching-man.

January 2006

Thesis (M. Phil.)--University of Hong Kong, 2007. / Title proper from title frame. Also available in printed format.

Molecular characterization of apoptosis induced by severe acute respiratory syndrome coronavirus spike protein

Yeung, Yin-shan.

January 2006

Thesis (M. Phil.)--University of Hong Kong, 2007. / Title proper from title frame. Also available in printed format.

Viral Marketing : en analys av dold marknadsföring på YouTube

Puro, Emma, Randeniye, Nathalie

January 1009

No description available.

YouTube

marknadsföring

Internet

dold marknadsföring

viral videos

att synas på internet - ett praktiskt företagsperspektiv

Rippe, Martin, Thoong, Van

January 2009

<p>Today Internet is clogged up and packed with homepages and information from both private persons and commercial companies. This has led to a decreased availability for a company to be noticed. The most common tool for consumers to use while searching for products online is via search engines. But because of the nature of these, not all companies can have good placements. Our research question was, "How do small online-companies attract consumers to their website"? The purpose of this thesis is to identify how a company works through online-communications and how to attract consumers to their home page. We also examine how companies with high placements in search engines differ in their work to attract consumers to their website in relation to companies with low placements in search engines. Furthermore, we also examine the practical work that is made to enhance the home page, as to make it easier for the customer and to enhance the probability of selling a first product. We were able to make a relevant questionnaire by reviewing new and relevant literature on subject’s field. Using telephone interviews we gather data for our empery. The uniqueness with this study is that we primarily look at relevant promotional aspects, which has not been considered adequately earlier, in the view of a practical perspective for a company. Our results were that in practice, to attract customers, a company primarily works to bee seen in search motors and in important places that are linked to the company's home page. The companies that were examined put a lot of effort to develop the homepage to make it easier for the customer. Also, the companies work with confiding proceedings through homepages so to make the customer attracted to the offerings and finally by the product. The study found differences in how companies handles their link-switching within the web, how they work with viral marketing and how they focus their work with shopbots depending whereas they score a high or a low placement in the editorial part of search engines.</p>

internet

online

företagsperspektiv

marknadsföring

viral

shopbots

Vaccinia virus I7L core protein proteinase

Byrd, Chelsea M.

08 April 2005

Vaccinia virus (VV) is a large double-stranded DNA virus that is a prototypic member of the orthopoxvirus family. Previous works has showed that three of the major structural proteins found within the mature VV virion core 4a, 4b, and 25K are produced from higher molecular weight precursors at late times during infection and processed via a common morphogenic cleavage pathway that is intimately linked with virion assembly and maturation. The enzyme that carries out these cleavage reactions is unknown. A transient expression assay was used to demonstrate that the 17L gene product and its encoded cysteine proteinase activity is responsible for cleavage of each of the three major core protein precursors. Cleavage was demonstrated to occur at the authentic Ala-Gly-Xaa cleavage sites and require active enzyme. A truncated 17L protein lost the ability to cleave the core protein precursors. A conditional-lethal recombinant virus was constructed in which the expression of the 17L gene is under the control of the tetracycline operator/repressor system. In the absence of 17L expression, processing of the major VV core proteins is inhibited and electron microscopy revealed defects in virion morphogenesis prior to complete core condensation. Plasmid-borne 17L is capable of rescuing the growth of this virus. A structural model of 17L was developed and a unique chemical library was assayed for both cell toxicity and the ability to inhibit the growth of VV in tissue culture cells. A novel class of inhibitors was discovered that is capable of inhibiting VV. An in-vitro cleavage assay was developed to further characterize the activity of 17L. This assay is based on producing the major core protein precursors in a coupled transcription and translation assay and then mixing them with 17L enzyme extracts. Using this assay, 17L is shown to be capable of cleavage of each substrate. 17L is further characterized as a cysteine proteinase due to the inhibitory effects of known cysteine proteinase inhibitors such as NEM and iodoacetic acid, as well as through the use of specific small molecule inhibitors in this in-vitro assay. / Graduation date: 2005

Vaccinia

Viral proteinases

DNA viruses -- Genetics

Palmitylation of vaccinia virus proteins : identification of modification sites and biological relevance

Grosenbach, Douglas W.

29 April 1999

Vaccinia virus encodes at least eight proteins that are modified post-translationally by the addition of a 16-carbon saturated fatty acid through thioester linkage to cysteine residues. This is referred to as palmitylation of proteins. The purpose of this work was to gain an understanding of palmitylation, focusing on what defined the substrate for the modification, and the biological relevance of protein palmitylation in the vaccinia virus life cycle. A systematic approach was taken to identify the genes in vaccinia virus that encode these proteins. We found that vaccinia virus palmitylproteins are of the "late" temporal class, associate with intracellular membranes, and are specific for a particular form of the infectious virion. These criteria were used to narrow the number of genes expressed by vaccinia virus that potentially encode palmitylproteins. The "candidate" palmitylprotein genes were cloned and transiently expressed in mammalian tissue culture cells and analyzed for incorporation of palmitic acid. In addition to three previously identified vaccinia virus palmitylproteins, three new palmitylproteins were identified. The six known palmitylprotein genes were mutated to determine the site of modification, leading to the identification of the modification site for four of the six proteins. One of the proteins, p37, was analyzed further for biological significance of the palmitate modification. A recombinant vaccinia virus was constructed that did not express the wild-type palmitylated form of p37, but expressed a nonpalmitylated form of the protein instead. This virus was severely inhibited from proceeding past a particular morphogenetic stage, leading to an attenuated phenotype in tissue culture systems. Although the expression of the nonpalmitylated protein appeared normal compared to the wild-type protein, the lack of the palmityl moiety resulted in the loss of a targeting signal that directed the protein to its normal intracellular location. By this work, significant contributions have been made toward understanding the process of protein palmitylation. We have identified, at least for vaccinia virus, primary structural determinants specifying the modification, leading to the identification of a palmitylation motif. Considering the attenuated phenotype of the mutant virus, our conclusion is that palmitylation is necessary for biological function, at least for p37. / Graduation date: 1999

Vaccinia

Viral proteins

Post-translational modification

Replication of vaccinia virus in the presence of 1,10-phenanthroline

ApRoberts, Robyn E.

25 September 1998

1,10-phenanthroline and its non-chelating isomer, 1,7-phenanthroline were used to inhibit the replication of vaccinia virus (VV). Serial passage of VV in the presence of various concentrations of either 1,10-phenanthroline or 1,7-phenanthroline was carried out. No drug resistant mutants were isolated, suggesting that the observed inhibition was due to a cellular protease as opposed to the putative viral protease G1L. Cultures infected in the presence of the inhibitors, were radio labeled with �����S-methionine at various time points post infection, to determine which step of VV replication was inhibited. Infections in the presence of 1,10-phenanthroline proceeded only through early gene transcription, suggesting that the point of inhibition was uncoating. Finally, cells infected with VV with or without the inhibitors at time zero and eight hours post infection were used to generate transmission electron microscopic images. Taken together these results indicate that inhibition was occurring at the level of uncoating. / Graduation date: 1999

DNA viruses -- Reproduction

Orthopoxviruses

Viral genetics

Fatty acylation of Vaccinia virus proteins : dual myristylation and palmitylation of the A-type inclusion protein

Martin, Karen H.

21 April 1997

The attachment of myristic acid to the N-terminal glycine residue of many eukaryotic and viral proteins is often essential for the acquisition of the protein's biological activity. Vaccinia virus (VV), the prototype member of the Poxviridae, expresses several myristylated proteins during the course of infection. Only one of these proteins, L1R, has been identified and characterized. Experiments were performed to identify and analyze four additional VV myristylproteins. These proteins were identified as the A-type inclusion protein (92 kDa), G9R (39 kDa), A16L (36 kDa), and E7R (17 kDa). The latter three proteins were shown to be myristylated on an N-terminal glycine residue. Additional studies demonstrated that both A16L and E7R are soluble proteins, unlike L1R, which is a constituent of the viral envelope. Furthermore, A16L could not be detected in either purified extracellular enveloped virus (EEV) or in intracellular mature virus (IMV). These are the two predominant forms of infectious virions produced during a VV infection. E7R was detected in EEV and, to a lesser extent, in IMV. Unlike the other proteins, the amino terminal sequence of the A-type inclusion protein did not fit the consensus sequence for N-myristylation (M-G-X-X-X-S/T/A/C/N), suggesting that it was internally myristylated. A combination of studies revealed that the protein is both myristylated and palmitylated. Addition of each acyl group could be separated temporally: myristylation occured co-translationally, while palmitylation occurred post-translationally. Genetic analyses of lysine doublets and arginine/lysine doublets within the A-type inclusion protein indicated that these sites are not utilized for myristylation. This is in contrast to the precursors of TNFoc and Ilia which are internally-myristylated on a lysine doublet. It is not clear why this protein would be both myristylated and palmitylated. Only class four palmitylproteins, such as the Src family of proteins, have been shown to be both myristylated and palmitylated. The A-type inclusion protein expressed by cowpox virus forms a large symmetrical matix in the cytoplasm of infected cells and generally contains mature virions. It is possible, therefore, that the function of acylation may be to stabilize the protein matrix or to assist in occlusion of enveloped virus particles. / Graduation date: 1998

Vaccinia

Viral proteins

Post-translational modification

Acylation