Topography of the three late mRNA''s of polyoma virus which encode the virion proteins.

The three cytoplasmic polyadenylated mRNA's which separately encode the three capsid proteins (VP1, VP2, and VP3) of polyoma virus were mapped on the viral genome by one- and two-dimensional gel electrophoreses of nuclease S1-resistant RNA-DNA hybrids. The mRNA's, which we designated mVP1, mVP2, and mVP3 to indicate the coding functions deduced from the cosedimentation of the RNAs and the messenger activities, comprise an overlapping set of 3'-coterminal molecules which also share a heterogeneous family of noncoding 5'-terminal regions (Flavell et al., Cell 16:357--371, 1979; Legon et al., Cell 16:373--388, 1979). The three species differ in the length of the 3' colinear coding region which is spliced to the 5' leader sequences. The common polyadenylated 3' end maps at map unit 25.3. The 5' ends of the colinear bodies of mVP1, mVP3, and mVP2 map at 48.5, 59.5, and 66.5 map units, respectively. An examination of the polyoma virus DNA sequence (Arrand et al., J. Virol. 33:606--618, 1980) in the vicinities of splicing sites approximated by the S1 gel mapping data for sequences common to the ends of known intervening sequences allowed prediction of the precise splice points in polyoma virus late mRNA's. In all three cases, the leader sequences are joined to the mRNA bodies at least 48 nucleotides before the translational initiation codon used in each particular messenger. The start signal which functions in each mRNA is the first AUG (or GUG) triplet after the splice junction.     

A suboptimal 5' splice site is a cis-acting determinant of nuclear export of polyomavirus late mRNAs.

Mouse polyomavirus has been used as a model system to study nucleocytoplasmic transport of mRNA. Three late mRNAs encoding the viral capsid proteins are generated by alternative splicing from common pre-mRNA molecules. mRNAs encoding the virion protein VP2 (mVP2) harbor an unused 5' splice site, and more than half of them remain fully unspliced yet are able to enter the cytoplasm for translation. Examination of the intracellular distribution of late viral mRNAs revealed, however, that mVP2 molecules are exported less efficiently than are mVP1 and mVP3, in which the 5' splice site has been removed by splicing. Point mutations and deletion analyses demonstrated that the efficiency of mVP2 export is inversely correlated with the strength of the 5' splice site and that unused 3' splice sites present in the mRNA have little or no effect on export. These results suggest that the unused 5' splice site is a key player in mVP2 export. Interestingly, mRNAs carrying large deletions but retaining the 5' splice site exhibited a wild-type mVP2 export phenotype, suggesting that there are no other constitutive cis-acting sequences involved in mVP2 export. RNA stability measurements confirmed that the subcellular distribution differences between these mRNAs were not due to differential half-lives between the two cellular compartments. We therefore conclude that the nuclear export of mVP2 is strongly influenced by a suboptimal 5' splice site. Furthermore, results comparing spliced and unspliced forms of mVP2 molecules indicated that the process of splicing does not enhance nuclear export. Since mVP2 and some of its mutant forms can accumulate in the cytoplasm in the absence of splicing, we propose that splicing is not a prerequisite for mRNA export in the polyomavirus system; rather, removal of splicing machinery from mRNAs may be required. The possibility that export of other viral mRNAs can be influenced by suboptimal splicing signals is also discussed.     

Electron microscopic demonstration of the presence of amplified sequences at the 5''-ends of the polyoma virus late mRNAs.

Electron microscopic techniques were used to examine the structure of the leader sequences at the 5'-ends of the late polyoma virus mRNAs. The three late mRNA's were partially purified and hybridized to an E. coli plasmid containing two polyoma virus genomes inserted in tandem. The hybrids were spread by the cytochrome c-formamide technique and visualized in the electron microscope. These studies revealed that whereas the body of a given mRNA molecule can hybridize with only one of the two corresponding body sequences in the two adjacent viral genomes, the leader of the same mRNA molecule can hybridize with both copies of the leader sequence-specific DNA. The mVP1 and mVP3 RNA species thus generated hybrids containing two loops, while mVP2 molecules formed hybrids containing one loop. Hence, the leaders of the three polyoma virus late mRNA species must contain two or more repeats of a sequence transcribed from a unique DNA segment. Length measurements showed that most leaders in the late mRNA's consist of at least 200 nucleotides and some contain up to 500 nucleotides, whereas the basic repeat sequence contains about 60 nucleotides.