We have previously shown that a purine-rich sequence located within exon M2 of the mouse immunoglobulin gene functions as a splicing enhancer, as judged by its ability to stimulate splicing of a distant upstream intron. This sequence element has been designated ERS (exon recognition sequence). In this study, we investigated the stimulatory effects of various ERS-like sequences, using the in vitro splicing system with HeLa cell nuclear extracts. Here (la, 9, 13, 34) or the secondary structure of the region around splice sites (10,11,25,38,39,46) affects splice site selection. In addition, there are numerous reports that suggest a role for specific exon sequences in splicing (4,6,12,15,16,18,20,24,26,27,32,33,40,41,45,48,49).We have previously shown that a purine-rich sequence located within the last exon, M2, of the mouse immunoglobulin p, (IgM) gene plays an essential role in the splicing of this gene (47,48). We found that this sequence functions as a splicing enhancer: it stimulated splicing of a distant intron that is present in the upstream region. This stimulatory effect was observed even with introns derived from different genes (48). We also found that this sequence promotes the formation of the early splicing complex (48). These results show that the sequence that we identified within IgM exon M2 represents a novel element involved in splice site selection. We designated this sequence element ERS (exon recognition sequence).Moreover, we have found that several exon sequences whose mutation or deletion affects splice site selection contain purine-rich sequences similar to the ERS of IgM exon M2 (IgM-ERS) (see Table 1 in reference 48). The examples include the avian sarcoma-leukosis virus (ASLV) gene (12,21), the chicken cardiac troponin T (cTNT) gene (4,5,49), the hypoxanthine-guanine phosphoribosyltransferase (hprt) gene (41), the bovine growth hormone (BGH) gene (15), the rat beta-tropomyosin gene (16), the fibronectin gene (27), and the neural cell adhesion molecule (NCAM) gene (42). This observation raised the possibility that the purinerich sequences of these genes are other examples of ERS and that the effects of exon mutations are ascribed to the loss of the enhancer activity of ERS. In this regard, Xu et al. recently reported that both the purine-rich sequence of the cTNT exon and the synthetic GAAGAGGAGG repeat sequence facilitate splicing of a heterologous intron in in vivo experiments (49). This finding is consistent with our notion
