Dismantle microtubule networks ICP0 co-localizes with α-tubulin, and dismantles host cell microtubule networks once it translocates to the cytoplasm.
Transcription In HSV-1 infected cells, ICP0 activates the transcription of many viral and cellular genes. It acts synergistically with HSV-1 immediate early (IE) protein,
ICP4, and is essential for the reactivation of latent herpes virus and viral replication.
Degradation of antiviral pathways ICP0 is responsible for overcoming a variety of cellular antiviral responses. After translocating to the nucleus early in infection, ICP0 promotes the degradation of many cellular antiviral genes, including those for nuclear body-associated proteins promyelocytic leukemia protein (PML) and Sp100, causing disruption of PML nuclear bodies and reduced cellular antiviral capacity. ICP0 also inhibits the activity of IFN regulatory factors (
IRF3) and
IRF7, which are key
transcription factors that induce production of antiviral
cytokines called
interferons. Barriers to viral replication induced by interferons can also be overcome by the action of ICP0. This function of ICP0 also prevents the production of
RNase L, an enzyme that degrades single-stranded viral and cellular RNAs and induces host cell
apoptosis in virus infected cells.
Interaction with host cell SUMO-1 protein and disruption PML nuclear bodies Small ubiquitin-related modifier 1 (SUMO-1) is a protein produced by human cells that is involved in the modification of many proteins, including human PML protein. HSV-1 ICP0 and several of its homologs in other herpes viruses bind to SUMO-1 in a manner similar to
endogenous proteins,
Interaction with neuron-differentiating protein NRSF and protein cofactor coREST ICP0 interacts with a human protein, known as neuronal restrictive silencer factor (NRSF) or
RE1-silencing transcription factor (REST), that regulates differences in gene expression between cells of
neuronal or non-neuronal origin. NRSF is found in non-neuronal cells but not in fully
differentiated neurons. which combines with NRSF to repress expression of neuronal genes in non-neuronal cells. Although the full NRSF protein is not typically found in neurons, truncated forms of NRSF are produced that selectively control the expression of certain
neurotransmitter channels in specialized neurons. Combination of ICP0 with these NRSF-like neuronal factors may silence herpes genes in neurons, blocking the production of other immediate-early genes such as
ICP4 and reducing production of
ICP22. The repressed production of immediate-early HSV genes may contribute to the establishment of
latency during infection with herpes viruses. == Suppression of ICP0 activity ==