Epigenetic regulation of transcription by RNA polymerase III

Chromatin participates actively in all DNA transactions and all phenomena directly under the influence of chromatin are explained by epigenetic mechanisms. The genes transcribed by RNA polymerase (pol) III are generally found in regions free of nucleosomes, the structural units of chromatin. Yet, histone modifications and positions of nucleosomes in the gene flanking regions have been reported to show direct correlation with activity status of these genes. Gene-specific as well as genome-wide studies have also revealed association of several epigenetic components with pol III-transcribed genes. This review presents a summary of the research in past many years, which have gathered enough evidence to conclude that pol III-transcribed genes are important components of an epigenome.     

The cellular RNA-binding protein EAP recognizes a conserved stem-loop in the Epstein-Barr virus small RNA EBER 1.

EAP (EBER-associated protein) is an abundant, 15-kDa cellular RNA-binding protein which associates with certain herpesvirus small RNAs. We have raised polyclonal anti-EAP antibodies against a glutathione S-transferase-EAP fusion protein. Analysis of the RNA precipitated by these antibodies from Epstein-Barr virus (EBV)- or herpesvirus papio (HVP)-infected cells shows that > 95% of EBER 1 (EBV-encoded RNA 1) and the majority of HVP 1 (an HVP small RNA homologous to EBER 1) are associated with EAP. RNase protection experiments performed on native EBER 1 particles with affinity-purified anti-EAP antibodies demonstrate that EAP binds a stem-loop structure (stem-loop 3) of EBER 1. Since bacterially expressed glutathione S-transferase-EAP fusion protein binds EBER 1, we conclude that EAP binding is independent of any other cellular or viral protein. Detailed mutational analyses of stem-loop 3 suggest that EAP recognizes the majority of the nucleotides in this hairpin, interacting with both single-stranded and double-stranded regions in a sequence-specific manner. Binding studies utilizing EBER 1 deletion mutants suggest that there may also be a second, weaker EAP-binding site on stem-loop 4 of EBER 1. These data and the fact that stem-loop 3 represents the most highly conserved region between EBER 1 and HVP 1 suggest that EAP binding is a critical aspect of EBER 1 and HVP 1 function.     

Regulation of influenza virus RNA polymerase activity by cellular and viral factors.

An in vitro RNA synthesis system mimicking replication of genomic influenza virus RNA was developed with nuclear extracts prepared from influenza virus-infected HeLa cells using exogenously added RNA templates. The RNA synthesizing activity was divided into two complementing fractions, i.e. the ribonucleoprotein (RNP) complexes and the fraction free of RNP, which could be replaced with RNP cores isolated from virions and nuclear extracts from uninfected cells, respectively. When nuclear extracts from uninfected cells were fractionated by phosphocellulose column chromatography, the stimulatory activity for RNA synthesis was further separated into two distinct fractions. One of them, tentatively designated RAF (RNA polymerase activating factor), stimulated RNA synthesis with either RNP cores or RNA polymerase and nucleocapsid protein purified from RNP cores as the enzyme source. In contrast, the other, designated PRF (polymerase regulating factor), functioned as an activator only when RNP cores were used as the enzyme source. Biochemical analyses revealed that PRF facilitates dissociation of RNA polymerase from RNP cores. Of interest is that virus-coded non-structural protein 1 (NS1), which has been thought to be involved in regulation of replication, counteracted PRF function. Roles of cellular factors and viral proteins, NS1 in particular, are discussed in terms of regulation of influenza virus RNA genome replication.