To elucidate the Epstein-Barr virus replisome

Traylen, Christopher

January 2016

Epstein-Barr virus (EBV) is a member of the γ-herpesvirus subfamily of Herpesviridae. EBV is a double stranded DNA virus infecting humans causing a variety of disease from asymptomatic infection to association with certain tumours including Burkitts lymphoma, Hodgkin's disease and nasopharyngeal carcinoma. EBV encodes an immediate-early protein called Zta (BZLF1, EB1, ZEBRA), which is an important transcription factor and replication factor direct in disrupting latency. EBV encodes viral proteins that assemble as a replisome at the viral lytic origin recognition site (Ori-Lyt). Zta binds Ori-Lyt and it is unclear how Zta interacts and recruits the complex to the site of DNA replication, while coordinating and recruiting host factors. After a mutation to three alanines (ZtaAAA) data implicates that the extreme C-terminus of Zta is essential for replication. The question posed is how does Zta assemble the replisome? Identification of the lytic changes that contribute to lytic replication, including cellular components that may contribute to EBV replication is attempted. Transfected control, Zta and ZtaAAA in HEK293-BZLF1-KO cells was compared. Size exclusion chromatography identified a higher molecular weight complex containing Zta during viral replication. SILAC (Stable isotope labelling by amino acids in cell culture) coupled to proteomics analysis identified the elution fraction composition. An interpretation of these cellular components in the context of lytic replication is explored. Identification of interactions of Zta with cellular proteins was attempted by SILAC histidine tagged Zta with pull down assay. Quantitative data was returned and a confirmation of interactions was attempted. A global proteomics approach was also performed. An enrichment method to isolate SILAC labeled Burkitts Lymphoma cells undergoing EBV lytic replication was coupled to mass spectrometry analysis to identify changes in host and viral proteins. Overall, cellular targets that may interact with Zta are to be confirmed. The global proteomics study recognized for the first time by proteomic analysis the identification of three EBV lytic replication cycle proteins.

570

QD0415 Biochemistry ; QR0355 Virology

Methylation dependent interactions of viral transcription factor Zta with DNA

Flower, Kirsty

January 2011

Epstein Barr Virus, a human herpes virus associated with infectious mononucleosis, Burkitt's lymphoma, Nasopharyngeal Carcinoma and Hodgkin's disease, can infect B cells and establish latency. Zta, a member of the bZIP transcription factor family, is a viral transcription and replication factor required for activation of lytic cycle. Zta is able to bind DNA, through specific Zta Response Elements (ZREs). Interestingly, Zta binds in a methylation dependent manner to specific CpGcontaining ZREs, known as Class III ZREs. RpZRE3 is one of the first examples of such a site, and can be found in the promoter of a key viral lytic gene, BRLF1. Through computational analysis and in vitro binding assays, it was found that the core 7mer sequence of RpZRE3 is sufficient for complex formation in vitro, and that the core sequence can be found in a variety of human gene promoter regions. As more methylation dependent ZREs emerged, a method to predict CpGcontaining ZREs was devised using position frequency matrices, coupled with in vitro binding verification, leading to the discovery of 12 novel CpG containing methylation dependent ZREs. The regulatory regions of both the EBV genome (type 1) and the human genome were mapped for a list of experimentally verified ZRE core sequences (both methylation dependent and independent). This analysis allowed identification of novel viral and host genes, potentially under the control of Zta activation, which were further analysed using existing transcriptome and methylome data. An investigation into potential host factors using the same methylation dependent mechanism was started, and an unknown protein was seen to bind in a methylation dependent manner to RpZRE3 in the absence of Zta in vitro.

572

QD0415 Biochemistry ; QR0355 Virology