The Long Noncoding Region of the Human Parainfluenza Virus Type 1 F Gene Contributes to the Read-Through Transcription at the M-F Gene Junction

Abstract

Sendai virus (SV) and human parainfluenza virus type 1 (hPIV1) have genomes consisting of nonsegmented negative-sense RNA in which the six genes are separated by well-conserved intergenic (IG) sequences and transcriptional start (S) and end signals. In hPIV1-infected cells, transcriptional termination at the M-F gene junction is ineffective; a large number of M-F read-through transcripts are produced (T. Bousse, T. Takimoto, K. G. Murti, and A. Portner, Virology 232 :44-52, 1997). In contrast, few M-F read-through transcripts are detected in SV-infected cells. Sequence analysis indicated that the hPIV1 IG and S sequences in the M-F junction differ from those of SV. Furthermore, the hPIV1 F gene contains an unusually long noncoding sequence. To identify the cis -acting elements that prevent transcriptional termination at the M-F junction, we rescued recombinant SV (rSVhMFjCG) in which its M-F gene junction was replaced by that of hPIV1. Cells infected with rSVhMFjCG produced an abundance of M-F read-through transcripts; this result indicated that the hPIV1 M-F junction is responsible for inefficient termination. When one or both of the IG and S sites in rSVhMFjCG were replaced by those of SV, the efficiency of transcriptional termination increased but not to the level observed in wild-type SV-infected cells. Deletion of most of the long noncoding region of the hPIV1 F gene in rSVhMFjCG in addition to the mutations in IG and S signals resulted in efficient termination that was equivalent to the level observed in wild-type virus-infected cells. Therefore, the long noncoding sequence of the hPIV1 F gene contains cis -acting element(s) that affects transcriptional termination. Our evaluation of the effect of inefficient transcriptional termination on viral replication in culture revealed that cells infected with rSVhMFjCG produced less F protein than cells infected with wild-type SV and that assembly of the recombinant SV in culture was less efficient. These phenotypes seem to be responsible for the extended survival of mice infected with rSVhMFjCG.