Tick-borne Nyamanini virus replicates in the nucleus and exhibits unusual genome and matrix protein properties.

Tick-borne Nyamanini virus (NYMV) is the prototypic member of a recently discovered genus in the order Mononegavirales, designated Nyavirus. The NYMV genome codes for six distinct genes. Sequence similarity and structural properties suggest that genes 1, 5, and 6 encode the nucleoprotein (N), the glycoprotein (G), and the viral polymerase (L), respectively. The function of the other viral genes has been unknown to date. We found that the third NYMV gene codes for a protein which, when coexpressed with N and L, can reconstitute viral polymerase activity, suggesting that it represents a polymerase cofactor. The second viral gene codes for a small protein that inhibits viral polymerase activity and further strongly enhances the formation of virus-like particles when coexpressed with gene 4 and the viral glycoprotein G. This suggests that two distinct proteins serve a matrix protein function in NYMV as previously described for members of the family Filoviridae. We further found that NYMV replicates in the nucleus of infected cells like members of the family Bornaviridae. NYMV is a poor inducer of beta interferon, presumably because the viral genome is 5' monophosphorylated and has a protruding 3' terminus as observed for bornaviruses. Taken together, our results demonstrate that NYMV possesses biological properties previously regarded as typical for filoviruses and bornaviruses, respectively.

Genomic RNAs of Borna disease virus are elongated on internal template motifs after realignment of the 3' termini.

The terminal structures of the Borna disease virus (BDV) genome (vRNA) and antigenome (cRNA) differ from those of other negative strand RNA viruses, as both molecules possess four nucleotides at the 3' terminus without an apparent template at the 5' end of the opposite strand. Consequently, the v- and cRNA molecules are not perfect mirror images, a situation that is not compatible with conventional strategies to maintain genetic information. We show here that recombinant viruses recovered from cDNA lacking the nontemplated nucleotides efficiently reconstitute the 3' overhangs. Analyses of recombinant viruses encoding genetic markers in potential alternative template sequences demonstrated that the BDV v- and cRNA molecules are extended by a realign-and-elongation process on internal template motifs located in close proximity to the 3' ends of v- and cRNA, respectively. The data further suggest that cRNA elongation is restricted to a single template motif of the nascent strand, whereas elongation of vRNA might use multiple template motifs. We propose that the elongation of the 3' termini supports the terminal integrity of the genomic RNA molecules during BDV persistence, and furthermore provides an elegant strategy to eliminate the triphosphate groups from the 5' termini of the BDV v- and cRNA without compromising the genetic information of the virus.