The HIV-1 accessory protein Vif is essential for viral replication by counteracting the host restriction factor APOBEC3G (A3G), and balanced levels of both proteins are required for efficient viral replication. Noncoding exons 2/2b contain the Vif start codon between their alternatively used splice donors 2 and 2b (D2 and D2b). For vif mRNA, intron 1 must be removed while intron 2 must be retained. Thus, splice acceptor 1 (A1) must be activated by U1 snRNP binding to either D2 or D2b, while splicing at D2 or D2b must be prevented. Here, we unravel the complex interactions between previously known and novel components of the splicing regulatory network regulating HIV-1 exon 2/2b inclusion in viral mRNAs. In particular, using RNA pulldown experiments and mass spectrometry analysis, we found members of the heterogeneous nuclear ribonucleoparticle (hnRNP) A/B family binding to a novel splicing regulatory element (SRE), the exonic splicing silencer ESS2b, and the splicing regulatory proteins Tra2/SRSF10 binding to the nearby exonic splicing enhancer ESE2b. Using a minigene reporter, we performed bioinformatics HEXplorerguided mutational analysis to narrow down SRE motifs affecting splice site selection between D2 and D2b. Eventually, the impacts of these SREs on the viral splicing pattern and protein expression were exhaustively analyzed in viral particle production and replication experiments. Masking of these protein binding sites by use of locked nucleic acids (LNAs) impaired Vif expression and viral replication.IMPORTANCE Based on our results, we propose a model in which a dense network of SREs regulates vif mRNA and protein expression, crucial to maintain viral replication within host cells with varying A3G levels and at different stages of infection. This regulation is maintained by several serine/arginine-rich splicing factors (SRSF) and hnRNPs binding to those elements. Targeting this cluster of SREs with LNAs may lead to the development of novel effective therapeutic strategies.KEYWORDS HEXplorer score, exon recognition, host restriction factor, human immunodeficiency virus, pre-mRNA processing, splicing regulatory elements D uring long terminal repeat (LTR)-driven transcription, over 50 mRNA isoforms emerge by alternative splicing of the HIV-1 precursor mRNA (1, 2). According to their distinct sizes, mRNA isoforms can be divided into three different classes: 2-kb mRNAs (intronless), encoding Tat, Rev, and Nef; intron-containing 4-kb mRNAs, encoding Vif, Vpr, Vpu, and Env; and 9-kb unspliced mRNAs, encoding Gag and Gag-Pol (3). Viral gene expression follows a strict chronological order (4-6). In the early phase, only intronless mRNAs are transported out of the nucleus and translated, whereas intron-
