Export of hepatitis B virus RNA on a Rev-like pathway: inhibition by the regenerating liver inhibitory factor IkappaB alpha.

Nuclear export of hepatitis B virus (HBV) RNA is mediated by a specific RNA element but, in contrast to lentivirus genomic RNA, does not depend on viral proteins. We show that nonetheless, the export of HBV RNA can be blocked by competitive inhibitors of Rev-mediated lentivirus RNA export, suggesting that the export pathways of both viral species share components and might be driven by the same nuclear export machinery. HBV RNA export is also inhibited by overexpression of IkappaB alpha, as reported previously for the export of human immunodeficiency virus RNA. Since IkappaB alpha is strongly overexpressed during liver regeneration, its inhibition of HBV RNA export might contribute to elimination or silent persistence of HBV.     

The secondary structure of the human immunodeficiency virus type 1 transcript modulates viral splicing and infectivity

Splicing of human immunodeficiency virus type 1 (HIV-1) exon 6D is regulated by the presence of a complex splicing regulatory element (SRE) sequence that interacts with the splicing factors hnRNP H and SC35. In this work, we show that, in the context of the wild-type viral sequence, hnRNP H acts as a repressor of exon 6D inclusion independent of its binding to the SRE. However, hnRNP H binding to the SRE acts as an enhancer of exon 6D inclusion in the presence of a critical T-to-C mutation. These seemingly contrasting functional properties of hnRNP H appear to be caused by a change in the RNA secondary structure induced by the T-to-C mutation that affects the spatial location of bound hnRNP H with respect to the exon 6D splicing determinants. We propose a new regulatory mechanism mediated by RNA folding that may also explain the dual properties of hnRNP H in splicing regulation.     

A structured retroviral RNA element that mediates nucleocytoplasmic export of intron-containing RNA.

A common feature of gene expression in all retroviruses is that unspliced, intron-containing RNA is exported to the cytoplasm despite the fact that cellular RNAs which contain introns are usually restricted to the nucleus. In complex retroviruses, the export of intron-containing RNA is mediated by specific viral regulatory proteins (e.g., human immunodeficiency virus type 1 [HIV-1] Rev) that bind to elements in the viral RNA. However, simpler retroviruses do not encode such regulatory proteins. Here we show that the genome of the simpler retrovirus Mason-Pfizer monkey virus (MPMV) contains an element that serves as an autonomous nuclear export signal for intron-containing RNA. This element is essential for MPMV replication; however, its function can be complemented by HIV-1 Rev and the Rev-responsive element. The element can also facilitate the export of cellular intron-containing RNA. These results suggest that the MPMV element mimics cellular RNA transport signals and mediates RNA export through interaction with endogenous cellular factors.     

Binding sites for Rev and ASF/SF2 map to a 55-nucleotide purine-rich exonic element in equine infectious anemia virus RNA

The equine infectious anemia virus (EIAV) Rev protein (ERev) negatively regulates its own synthesis by inducing alternative splicing of its mRNA. This bicistronic mRNA contains four exons; exons 1 and 2 encode Tat, and exons 3 and 4 encode Rev. When Rev is expressed, exon 3 is skipped to produce an mRNA that contains only exons 1, 2, and 4. The interaction of ERev with its cis-acting RNA response element, the RRE, is also essential for nuclear export of intron-containing viral mRNAs that encode structural and enzymatic gene products. The primary ERev binding site and the manner in which ERev interacts with RNA or cellular proteins to exert its regulatory function have not been defined. We have performed in vitro RNA binding experiments to show that recombinant ERev binds to a 55-nucleotide, purine-rich tract proximal to the 5' splice site of exon 3. Because of its proximity to the 5' splice site and since it contains elements related to consensus exonic splicing enhancer sequences, we asked whether cellular proteins recognize the EIAV RRE. The cellular protein, ASF/SF2, a member of the serine- and arginine-rich family of splicing factors (SR proteins) bound to repeated sequences within the 55-nucleotide RRE region. Electrophoretic mobility shift and UV cross-linking experiments indicated that ERev and SR proteins bind simultaneously to the RRE. Furthermore, in vitro protein-protein interaction studies revealed an association between ERev and SR proteins. These data suggest that EIAV Rev-induced exon skipping observed in vivo may be initiated by simultaneous binding of Rev and SR proteins to the RRE that alter the subsequent assembly or catalytic activity of the spliceosomal complex.     

A host factor that binds near the termini of hepatitis B virus pregenomic RNA.

The terminal regions of hepatitis B virus (HBV) pregenomic RNA (pgRNA) harbors sites governing many essential functions in the viral life cycle, including polyadenylation, translation, RNA encapsidation, and DNA synthesis. We have examined the binding of host proteins to a 170-nucleotide region from the 5' end of HBV pgRNA; a large portion of this region is duplicated at the 3' end of this terminally redundant RNA. By UV cross-linking labeled RNA to HepG2 cell extracts, we have identified a 65-kDa factor (p65) of nuclear origin which can specifically bind to this region. Two discrete binding sites were identified within this region; in vitro cross-competition experiments suggest that the same factor binds to both elements. One binding site (termed UBS) overlaps a portion of the highly conserved stem-loop structure (epsilon), while the other site (termed DBS) maps 35 nucleotides downstream of the hexanucleotide polyadenylation sequence. Both binding sites are highly pyrimidine rich and map to regions previously found to be important in the regulation of viral polyadenylation. However, functional analysis of mutant binding sites in vivo indicates that p65 is not involved in the polyadenylation of HBV pgRNA. Potential roles for the factor in viral replication in vivo are discussed.