Abstract
BackgroundThe carboxyl terminal of Epstein-Barr virus (EBV) ZEBRA protein (also termed BZLF-1 encoded replication protein Zta or ZEBRA) binds to both NF-κB and p53. The authors have previously suggested that this interaction results from an ankyrin-like region of the ZEBRA protein since ankyrin proteins such as IκB interact with NF-κB and p53 proteins. These interactions may play a role in immunopathology and viral carcinogenesis in B lymphocytes as well as other cell types transiently infected by EBV such as T lymphocytes, macrophages and epithelial cells.MethodsRandomization of the ZEBRA terminal amino acid sequence followed by statistical analysis suggest that the ZEBRA carboxyl terminus is most closely related to ankyrins of the invertebrate cactus IκB-like protein. This observation is consistent with an ancient origin of ZEBRA resulting from a recombination event between an ankyrin regulatory protein and a fos/jun DNA binding factor. In silico modeling of the partially solved ZEBRA carboxyl terminus structure using PyMOL software demonstrate that the carboxyl terminus region of ZEBRA can form a polymorphic structure termed ZANK (ZEBRA ANKyrin-like region) similar to two adjacent IκB ankyrin domains.ConclusionsViral capture of an ankyrin-like domain provides a mechanism for ZEBRA binding to proteins in the NF-κB and p53 transcription factor families, and also provides support for a process termed "Ping-Pong Evolution" in which DNA viruses such as EBV are formed by exchange of information with the host genome. An amino acid polymorphism in the ZANK region is identified in ZEBRA from tumor cell lines including Akata that could alter binding of Akata ZEBRA to the p53 tumor suppressor and other ankyrin binding protein, and a novel model of antagonistic binding interactions between ZANK and the DNA binding regions of ZEBRA is suggested that may be explored in further biochemical and molecular biological models of viral replication.
Highlights
The carboxyl terminal of Epstein-Barr virus (EBV) ZEBRA protein binds to both NF-B and p53
Identification of a structural and functional divergence between ZEBRA carboxyl terminus and fos/jun transcription factors Epstein Barr Virus (EBV) encoded ZEBRA protein is capable of switching the viral state from latency to lytic growth through its effects on specific DNA binding sites termed ZRE (ZEBRA Response Elements)[7]
Efforts to discover a specific mechanism for proteinprotein interactions of the carboxyl terminus region of ZEBRA based upon the partially solved structure have been unsuccessful, some similarities are evident between this region and C/EBP-a, a CAAT-binding transcription factor whose dysregulation is implicated in acute myeloid leukemia [13]
Summary
The carboxyl terminal of Epstein-Barr virus (EBV) ZEBRA protein ( termed BZLF-1 encoded replication protein Zta or ZEBRA) binds to both NF-B and p53. The authors have previously suggested that this interaction results from an ankyrin-like region of the ZEBRA protein since ankyrin proteins such as IB interact with NF-B and p53 proteins. The ubiquitous human pathogen Epstein Barr Virus (EBV), genome structure contains a region co-linear with the vertebrate variable. These observations suggest that EBV and other DNA viruses evolve through sharing of genetic information with the host genome termed “Ping Pong Evolution”. An amino acid polymorphism in this region of ZEBRA is identified that could potentially alter the functional properties of the ZEBRA protein interactions with both NF-B and the distantly related tumor suppressor p53[6]
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