genomic RNA, are competing points of ligation for splicing, and their alternate selection usually determines the protein encoded by the mature RNA (3, 15, 18, 35, 43, 47). However, some of these mRNAs are multicistronic, encoding more than one protein (15, 48, 49). Increased diversity of spliced mRNAs for several HIV-1 proteins results from the alternative cassetting of two noncoding exons into a proportion of transcripts (15, 43, 47). In addition, the use of several cryptic SA and SD sites may lead to the synthesis of novel chimeric viral proteins (5, 15, 46, 47). The varied use of these diverse splicing signals results in the synthesis of several sets of structurally different RNAs that serve as alternative templates for the translation of the same protein, including the viral envelope, regulatory, and accessory proteins. Because this complex pattern of RNA expression is maintained among many HIV-1 isolates of diverse origins (42, 43, 50), it is likely that this complexity is critical for the successful completion of the HIV-1 infectious cycle and not simply an inherent redundancy in viral RNA processing. The major advantage of examining regulated splicing of a self-replicating entity such as HIV-1 is that such investigations can use whole cells, rather than in vitro splicing extracts, and the biological consequences can be readily correlated with RNA and protein expression as well as with virus infectivity. While mixed groups of mRNAs encode most HIV-1 proteins, it is unclear whether different cell types use alternative splicing to regulate HIV-1 RNA expression. The principal cell types that are infected by HIV-1, CD4+ lymphocytes and monocytederived macrophages, are known to alternatively splice RNA from some cellular genes, depending on the maturation or activation status of the cell (e.g., CD45 [54, 55]) or on the cell type (e.g., CD46 [44]). Given the wide sequence diversity of HIV-l strains (37), it is likely that sequence differences will 6365
