CA- and purine-rich elements form a novel bipartite exon enhancer which governs inclusion of the minute virus of mice NS2-specific exon in both singly and doubly spliced mRNAs

The alternatively spliced 290-nucleotide NS2-specific exon of the parvovirus minute virus of mice (MVM), which is flanked by a large intron upstream and a small intron downstream, constitutively appears both in the R1 mRNA as part of a large 5'-terminal exon (where it is translated in open reading frame 3 [ORF3]), and in the R2 mRNA as an internal exon (where it is translated in ORF2). We have identified a novel bipartite exon enhancer element, composed of CA-rich and purine-rich elements within the 5' and 3' regions of the exon, respectively, that is required to include NS2-specific exon sequences in mature spliced mRNA in vivo. These two compositionally different enhancer elements are somewhat redundant in function: either element alone can at least partially support exon inclusion. They are also interchangeable: either element can function at either position. Either a strong 3' splice site upstream (i.e., the exon 5' terminus) or a strong 5' splice site downstream (i.e., the exon 3' terminus) is sufficient to prevent skipping of the NS2-specific exon, and a functional upstream 3' splice site is required for inclusion of the NS2-specific exon as an internal exon into the mature, doubly spliced R2 mRNA. The bipartite enhancer functionally strengthens these termini: the requirement for both the CA-rich and purine-rich elements can be overcome by improvements to the polypyrimidine tract of the upstream intron 3' splice site, and the purine-rich element also supports exon inclusion mediated through the downstream 5' splice sites. In summary, a suboptimal large-intron polypyrimidine tract, sequences within the downstream small intron, and a novel bipartite exonic enhancer operate together to yield the balanced levels of R1 and R2 observed in vivo. We suggest that the unusual bipartite exonic enhancer functions to mediate proper levels of inclusion of the NS2-specific exon in both singly spliced R1 and doubly spliced R2.     

Intron definition is required for excision of the minute virus of mice small intron and definition of the upstream exon

Alternative splicing of pre-mRNAs plays a critical role in maximizing the coding capacity of the small parvovirus genome. The small-intron region of minute virus of mice (MVM) pre-mRNAs undergoes an unusual pattern of overlapping alternative splicing--using two donors (D1 and D2) and two acceptors (A1 and A2) within a region of 120 nucleotides--that determines the steady-state ratios of the various viral mRNAs. In this report, we show that the determinants that govern excision of the small intron are complex and are also required for efficient definition of the upstream exon. For the MVM small intron in its natural context, the two donors appear to compete for the splicing machinery: the position of D1 favors its usage, while the primary sequence of D2 must be more like the consensus sequence than is D1 to be used efficiently. We have genetically defined the branch points that are used for generation of the major and minor spliced forms and show that recognition of components of the small-intron acceptors is likely to be the dominant determinant in alternative small-intron excision. We have also identified a G-rich intronic enhancer sequence within the small intron that is essential for splicing of the minor form (D2 to A2) but not the major form (D1 to A1) of MVM mRNAs and is required for efficient definition of the upstream NS2-specific exon. In its natural context, the small intron appears to be excised by a mechanism consistent with intron definition. When the MVM small intron is expanded, various parameters of its excision are altered, indicating that critical cis-acting signals are context dependent. Relative use of the donors and acceptors is altered, and the upstream NS2-specific exon is no longer efficiently defined. The fact that definition of the upstream NS2-specific exon can be achieved by the MVM small intron in its natural context, but not when it is expanded, suggests that the multiple determinants that govern definition and excision of the small intron are required, in concert, for upstream exon definition. Our data are consistent with a model in which alternative splicing of the MVM P4-generated pre-mRNAs is governed by a hybrid of intron- and exon-defining mechanisms.