Claus W. Grassmann

Members of the NF90/NFAR protein group are involved in the life cycle of a positive-strand RNA virus

A major issue of current virology concerns the characterization of cellular proteins that operate as functional components of the viral multiplication process. Here we describe a group of host factors designated as ‘NFAR proteins’ that are recruited by the replication machinery of bovine viral diarrhea virus, a close relative of the human pathogen hepatitis C virus. The NFAR proteins associate specifically with both the termini of the viral RNA genome involving regulatory elements in the 5′ and 3′ non‐translated regions. Modification of the protein interaction sites in the 3′ non‐translated region yielded viral RNAs that were replication deficient. Viral replication was also inhibited by RNAi approaches that reduced the concentration of RNA helicase A, a member of the NFAR group, in the host cells cytoplasm. Further experimental data suggest that NFAR proteins mediate a circular conformation of the viral genome that may be important for the coordination of translation and replication. Because NFAR proteins are presumed components of the antiviral response, we suspect that viral recruitment may also serve to weaken cellular defense mechanisms.

Genetic Analysis of the Pestivirus Nonstructural Coding Region: Defects in the NS5A Unit Can Be Complemented in trans

ABSTRACT The functional analysis of molecular determinants which control the replication of pestiviruses was considerably facilitated by the finding that subgenomic forms of the positive-strand RNA genome of BVDV (bovine viral diarrhea virus) are capable of autonomous replication in transfected host cells. The prototype replicon, BVDV DI9c, consists of the genomic 5′ and 3′ untranslated regions and a truncated open reading frame (ORF) encoding mainly the nonstructural proteins NS3, NS4A, NS4B, NS5A, and NS5B. To gain insight into which of these proteins are essential for viral replication and whether they act in cisor in trans, we introduced a large spectrum of in-frame mutations into the DI9c ORF. Tests of the mutant RNAs in terms of their replication capacity and their ability to support translation and cleavage of the nonstructural polyprotein, and whether defects could be rescued in trans, yielded the following results. (i) RNA replication was found to be dependent on the expression of each of the DI9c-encoded mature proteins NS3 to NS5B (and the known associated enzymatic activities). In the same context, a finely balanced molar ratio of the diverse proteolytic processing products was indicated to be crucial for the formation of an active catalytic replication complex. (ii) Synthesis of negative-strand intermediate and progeny positive-strand RNA was observed to be strictly coupled with all functional DI9c ORF derivatives. NS3 to NS5B were hence suggested to play a pivotal role even during early steps of the viral replication pathway. (iii) Mutations in the NS3 and NS4B units which generated nonfunctional or less functional RNAs were determined to becis dominant. Likewise, lethal alterations in the NS4A and NS5B regions were invariably noncomplementable. (iv) In surprising contrast, replication of functional and nonfunctional NS5A mutants could be clearly enhanced and restored, respectively. In summary, our data provide initial insights into the organization of the pestivirus replication machinery.

A Stem-Loop Motif Formed by the Immediate 5′ Terminus of the Bovine Viral Diarrhea Virus Genome Modulates Translation as well as Replication of the Viral RNA

ABSTRACT Bovine viral diarrhea virus (BVDV), aPestivirus member of the Flaviviridae family, has a positive-stranded RNA genome which consists of a single open reading frame (ORF) and untranslated regions (UTRs) at the 5′ and 3′ ends. The 5′ UTR harbors extensive RNA structure motifs; most of them were shown to contribute to an internal ribosomal entry site (IRES), which mediates cap-independent translation of the ORF. The extreme 5′-terminal region of the BVDV genome had so far been believed not to be required for IRES function. By structure probing techniques, we initially verified the existence of a computer-predicted stem-loop motif at the 5′ end of the viral genome (hairpin Ia) as well as at the 3′ end of the complementary negative-strand replication intermediate [termed hairpin Ia (−)]. While the stem of this structure is mainly constituted of nucleotides that are conserved among pestiviruses, the loop region is predominantly composed of variable residues. Taking a reverse genetics approach to a subgenomic BVDV replicon RNA (DI9c) which could be equally employed in a translation as well as replication assay system based on BHK-21 cells, we obtained the following results. (i) Proper folding of the Ia stem was found to be crucial for efficient translation. Thus, in the context of an authentic replication-competent viral RNA, the 5′-terminal motif operates apparently as an integral functional part of the ribosome entry. (ii) An intact loop structure and a stretch of nucleotide residues that constitute a portion of the stem of the Ia or the Ia (−) motif, respectively, were defined to represent important determinants of the RNA replication pathway. (iii) Formation of the stem structure of the Ia (−) motif was determined to be not critical for RNA replication. In summary, our findings affirmed that the 5′-terminal region of the BVDV genome encodes a bifunctional secondary structure motif which may enable the viral RNA to switch from the translation to the replicative cycle and vice versa.