Spelling suggestions: "subject:"herpes virus"" "subject:"terpes virus""
1 |
Analysis of the immune response to herpes simpex virus using cells constitutively expressing virus glycoproteinsBlacklaws, B. A. January 1987 (has links)
No description available.
|
2 |
Herpes simplex virus gene expression in establishment and maintenance of latent infectionLaycock, K. A. January 1988 (has links)
No description available.
|
3 |
Nucleotide sequencing studies in Herpes Simplex VirusHodgman, T. C. January 1984 (has links)
No description available.
|
4 |
Properties of DNA in cells infected by Herpes Simplex Virus Type 1Aranda-Anzaldo, A. January 1986 (has links)
No description available.
|
5 |
The interactions of EHV-1 infected leucocytes and equine endothelial cellsSmith, Deborah Jane January 2000 (has links)
No description available.
|
6 |
The effect of herpes simplex virus type 1 on chromosomes of human cellsPeat, D. S. January 1986 (has links)
No description available.
|
7 |
Transcriptional regulation of the Epstein-Barr virus immediate early genesJenkins, Peter John January 1999 (has links)
No description available.
|
8 |
Developing Epstein-Barr virus-based stable episomes for gene expression from large genomic inserts to complement cell phenotypesWade-Martins, Richard January 1998 (has links)
No description available.
|
9 |
Molecular analysis of Kaposi's sarcoma associated herpes virus (KSHV) in immunocompromised patientsO'Leary, John James January 1996 (has links)
No description available.
|
10 |
Cell cycle protein expression in AIDS-related and classical Kaposi's sarcomaHong, Angela Manyin January 2004 (has links)
Kaposi�s sarcoma (KS) is a peculiar vascular neoplasm that occurs mainly in elderly Mediterranean men and patients with acquired immunodeficiency syndrome (AIDS). The current literature indicates that KS is initiated by the human herpes virus 8 (HHV8) as a reactive polyclonal process but with deregulation of oncogene and tumour suppressor genes, it can progress to a true malignancy with monoclonality. Clinically, classical KS often presents as an indolent disease affecting mainly the lower extremities whereas AIDS-related KS has no site predilection and can progress rapidly with systemic involvement. Histologically, KS can be classified into patch, plaque and nodular stages. Interestingly, classical and AIDS-related KS are indistinguishable histologically and this suggests that AIDS-related KS and classical KS might be initiated by a common aetiology but given their different clinical courses, they may progress through different mechanisms. In view of the importance of the cell cycle proteins in the development and progression of many human malignancies, this thesis aims to examine the role of these proteins in the progression of the two main clinical subtypes of KS. The cell cycle protein expressions in a cohort of 47 patients with KS with welldocumented clinical and histological features were studied. Using a monclonal antibody against the latent nuclear antigen-1 molecule of HHV8, HHV8 was detected in 78% of the cases. The more advanced nodular lesions were found to have a higher level of proliferative activity as measured by the proliferation x marker, Ki-67. This suggests it is valid to use the histological specimens as a tumour progression model of KS. The role of the Rb/cyclin D1/p16 pathway was examined. The more advanced nodular stage KS lesions were more likely to be positive for cyclin D1, suggesting that cyclin D1 is important in the progression from patch stage to nodular stage. p16 acts as a tumour suppressor and it has an inhibitory effect on cyclin D1. The p16 expression rate was low in early stage KS but high in the more advanced lesions. It seems that reduced p16 expression occurs early in KS and may be important in its development. The rate of Rb expression, on the other hand, did not differ significantly among the histological subtypes. The results revealed the significant role of the Rb/cyclin D1/p16 pathway in the progression of KS. Of the mitotic cyclins examined, cyclin A expression was correlated with the advanced tumor stage. The rate of p34cdc2 expression was high in the lesions and there was no correlation with histological stage. This suggests that p34cdc2 is important in the early development of the tumour but not necessarily in its progression. Along the p53-apoptotic pathway, mutant p53 expression was significantly more common in the nodular stage. The cyclin G1 (a protooncogene, one of the target genes of p53) expression also paralleled that of mutant p53 with the majority of the KS lesions showing cyclin G1 expression and significant xi correlation between advanced histological stage and increasing rate of cyclin G1 expression. These findings suggest that progression along the p53 pathway may be important in the advanced stage development of KS. On the other hand, expression of the CDK inhibitor, p27, a protein that normally negatively regulates cyclin G1, was reduced in nodular KS. These findings suggest that some KS lesions may progress through a deregulated or abnormal p53 pathway. There were correlations between cyclin D1, cyclin A, cyclin G1, mutant p53 and negative HIV status. The findings suggest that components of both the Rb/cyclin D1/p16 and p53-apoptotic pathways are important in the progression of classical KS. Rb protein was the only cell cycle protein whose rate of expression correlated significantly with HHV8 status in KS. The majority of HHV8 positive lesions were also positive for Rb protein, unlike HHV8 negative lesions. This suggests that some of the HHV8 negative lesions can progress through a defective Rb pathway whereas the role of Rb in the progression may not be as important in the HHV8 positive lesions. This was an unexpected finding given that one of the postulated mechanisms of tumour initiation by the HHV8 virus is via the viral cyclin it produces. The viral cyclin produced by HHV8 acts through the Rb pathway much the same as cyclin D1 and one would have expected that HHV8 positive cases are less likely to be positive for the Rb protein. In summary, the majority of the KS lesions examined in this thesis show HHV8 infection. The Rb/cyclin D1/p16 pathway appears to be important in the progression of the different stages of KS and expression of the proteins involved in the p53 pathway were found to be important in the advanced stages of the development of KS. There were differential expressions of cell cycle proteins between AIDS-related and classical KS, and between HHV8 positive and HHV8 negative lesions. The findings also provided some clues to the possible mechanisms of development in KS lesions that were not initiated by HHV8.
|
Page generated in 0.047 seconds