Exon involvement in the regulation of MuSVts110 RNA splicing

MuSVts110 is a conditionally defective mutant of Moloney murine sarcoma virus which undergoes a novel tmperature-dependent splice event at growth temperatures of 33$\sp\circ$C or lower. Relative to wild-type MuSV-124, MuSVts110 contains a 1487 base deletion spanning from the 3$\sp\prime$ end of the p30 gag coding region to just downstream of the first v-mos initiation codon. As a result, the gag and mos genes are fused out of frame and no v-mos protein is expressed. However, upon a shift to 33$\sp\circ$C or lower, a splice event occurs which removes 431 bases, realigns the gag and mos genes, and allows read-through translation of a P85gag-mos transforming protein. Interestingly, while the cryptic splice sites utilized in MuSVts110 are present and unaltered in MuSV-124, they are never used. Due to the 1487 base deletion, the MuSV-124 intron was reduced from 1919 to 431 bases suggesting that intron size might be involved in the activation of these cryptic splice sites in MuSVts110. Since the splicing phenotype of the MuSVts110 equivalent (TS32 DNA) which contains the identical 1487 base deletion introduced into otherwise wild-type MuSV-124 DNA, was indistinguishable from authentic MuSVts110, it was concluded that this deletion alone is responsible for activation of the cryptic splice sites used in MuSVts110. These results also confirmed that thermodependent splicing is an intrinsic property of the viral RNA and not due to some cellular defect. Furthermore, analysis of gag gene deletion and frameshift MuSVts110 mutants demonstrated that viral gag gene proteins do not play a role in regulation of MuSVts110 splicing. Instead, cis-acting viral sequences appear to mediate regulation of the splice event.^ Our initial observation that truncation of the MuSVts110 transcript, leaving only residual amounts of the flanking exon sequences, completely abolished splicing activity argued that exon sequences might participate in the regulation of the splice event.^ Analysis of exon sequence involvement has also identified cis-acting sequences important in the thermodependence of the splice event. Data suggest that regulation of the MuSVts110 splice event involves multiple interactions between specific intron and exon sequences and spliceosome components which together limit splicing activity to temperatures of 33$\sp\circ$C or lower while simultaneously restricting splicing to a maximum of 50% efficiency. (Abstract shortened with permission of author.) ^

Regulation of mRNA splicing in Moloney murine sarcoma virus mutants

Cells infected with the conditionally defective MuSVts110 mutant of Moloney murine sarcoma virus are transformed at 33$\sp\circ$C but appear morphologically normal at 39$\sp\circ$C. The molecular basis for this phenotype is as follows: MuSVts110 contains a 1487 nucleotide central deletion that has truncated the 3$\sp\prime$ end to the gag gene and the 5$\sp\prime$ end of the mos gene. The resulting gag-mos junction is out-of-frame and the v-mos protein is not expressed. At 33$\sp\circ$C or lower, a splicing event is activated such that a 431 base intron is removed to realign the gag and mos gene in-frame, allowing the expression of a transforming protein P85$\sp{gag-mos}$. Temperature-dependent splicing appeared to be an intrinsic property of MuSVts110 transcripts and not a general feature of pre-mRNA splicing in 6m2 cells since splicing activity of a heterologous transcript in the same cells did not vary with temperature. The possibility that the splice event was not temperature-sensitive, but that the accumulation of spliced transcript at the lower growth temperatures was due to its selective thermolability was ruled out as stability studies revealed that the relative turnover rates of the unspliced and spliced MuSVts110 transcripts were not affected by temperature.^ The consensus sequences containing the splice sites activated in the MuSVts110 mutant (5$\sp\prime$ gag and 3$\sp\prime$ mos) are present, but not utilized, in wild-type MuSV-124. To test the hypothesis that it was the reduction of the 1919 base intervening sequence in MuSV-124 to 431 bases in MuSVts110 which activated splicing, the identical 1487 base deletion was introduced into cloned wild-type MuSV-124 DNA to create the MuSVts110 equivalent, ts32.^ To examine conditions permissive for splicing, we assayed splice site activation in a series of MuSV-124 "intron-modification" mutants. Data suggest that splicing in wild-type MuSV-124 may be blocked due to the lack of a proximal branchpoint sequence, but can be activated by those intron mutations which reposition a branch site closer to the 3$\sp\prime$ splice site. (Abstract shortened with permission of author.) ^