Simian immunodeficiency virus displays complex patterns of RNA splicing.

The human and simian immunodeficiency viruses encode at least six gene products that apparently serve regulatory functions. To evaluate the regulation of simian immunodeficiency virus gene expression at the level of RNA splicing, we used the polymerase chain reaction to amplify and clone cDNAs corresponding to a large array of mRNAs from infected cells. We identified mRNAs that used splice acceptor sites upstream of the initiator codons for tat, rev, vpr, nef, vif, and vpx, suggesting that these proteins may be expressed from different mRNAs. We also provide hybridization data suggesting that the same splice acceptor site may be used for both rev and env mRNAs. Furthermore, we isolated both tat and rev cDNAs that utilized three alternative splice acceptor sites at the start of coding exon 2, indicating that different versions of these proteins may be encoded. Finally, approximately 10 to 20% of simian immunodeficiency virus mRNAs spliced an intron from their untranslated 5' ends, and sequences contained within this intron constituted a portion of the tat-responsive TAR element. Thus, alternative pre-mRNA splicing adds a level of complexity to simian immunodeficiency virus expression, which may affect several levels of gene regulation.     

Epstein-Barr virus mRNAs produced by alternative splicing.

The structure of Epstein-Barr virus mRNAs transcribed in B95-8 cells has been studied by cDNA cloning and sequencing. We present here the analysis of four cDNAs. The corresponding mRNAs are probably transcribed from a single promoter located in the US region. They are produced by alternative splicing of exons transcribed from the US, IR and UL regions. The exons are spread over 100 kbp. The exons from the IR region constitute a unit which is repeated several times. The cDNAs share the exons from the US and IR regions. Some of the cDNAs also share some of the exons from the UL region. Each cDNA contains a long open reading frame or the 5' end of a long open reading frame which ends several hundred nucleotides downstream on the viral genome. The 5' untranslated regions are unusually long. Three mRNA species differing in their 5' untranslated regions may encode for the nuclear antigen EBNA-1. The other mRNAs encode for polypeptides which may not have any common region.     

A novel H-2K splice form: predictions for other alternative H-2 splicing events

A large number of H-2K and H-2D cDNA clones from a C3HfB/HeN spleen cDNA library were extensively characterized. All H-2D^k cDNAs were shown to exhibit the short form of exon 8, consistent with the presence of a single lariat branchpoint site within intron 7. Twenty-five H-2K^km2 cDNAs were found to bear a short exon 8, whereas only two clones were shown to carry the longer form of this exon. In one of the H-2K^km2 cDNAs, a novel pattern of H-2 splicing was identified, in which an extra 15 nucleotides, derived from the 3′ end of intron 5, were inserted between the intact and unaltered exon 5 and exon 6 sequences. Resulting from the apparent use of a cryptic splice acceptor site in place of the canonical intron 5 site, this insertion is predicted to generate an in-frame insertion of five nonpolar amino acid residues within a highly polar region of the intracytoplasmic domain of the H-2K polypeptide. The features of this novel splice form served as the basis for predicting additional rare, alternative H-2 pre-mRNA splicing events that might produce functionally relevant microheterogeneity in the encoded H-2 gene products.     

The Choice of Translation Initiation Site of the Rep Proteins from Goose Parvovirus P9-Generated mRNA Is Governed by Splicing and the Nature of the Excised Intron

The goose parvovirus (GPV) Rep 1 and Rep 2 proteins are encoded by P9-generated mRNAs that are either unspliced or spliced within the rep gene region, respectively. These mRNAs are present in an approximately equal ratio. The translation of Rep 1 was initiated from the first AUG in unspliced P9-generated mRNA; however, this AUG was bypassed in spliced P9-generated RNA and Rep 2 translation initiated predominately at the next initiating AUG downstream. We show that the choice of the site of initiation of translation of GPV Rep-encoding mRNAs is governed both by the splicing process itself and by the nature of the excised intron.Goose parvovirus (GPV) has identical hairpin termini, is most similar in both nucleotide sequence and protein homology to adeno-associated virus 2 (AAV2), and has been classified as a member of the Dependovirus genus (10-12); however, unlike the AAVs, GPV can replicate efficiently without the aid of a helper virus (12). The RNA expression profile of GPV is a surprising hybrid of features of the Parvovirus and Dependovirus genera of the Parvovirinae (7). Similar to the Dependovirus AAV5, RNAs transcribed from the GPV upstream P9 promoter, which encode the viral Rep protein(s), are polyadenylated at high efficiency at a polyadenylation [(pA)p] site located within the small intron in the center of the genome (7). No promoter analogous to the Dependovirus P19 promoter has been detected; however, similar to minute virus of mice (MVM) and other members of the Parvovirus genus, approximately half of the pre-mRNAs generated from the P9 promoter are additionally spliced within the putative GPV Rep coding region between a donor site located at nucleotide (nt) 814 and an acceptor site at nt 1198 (7). The GPV RNA profile has been shown to be the same in both human 293T and goose CGBQ cells (7). Thus, the mechanism that GPV uses for the expression of its nonstructural gene is more like that used by members of the autonomous Parvovirus group.In this report, we describe the coding strategy for the nonstructural proteins of GPV. We demonstrate that the large Rep 1 protein is encoded uninterruptedly in open reading frame 1 (ORF 1) from the unspliced P9-generated mRNA using an initiating AUG codon at nt 537. The smaller Rep 2 protein is encoded by the spliced P9-generated mRNA; it initiates in ORF 2 at an AUG at nt 650 and continues in ORF 1 after the splice. Strikingly, the first upstream AUG at nt 537 is not utilized in spliced P9-generated mRNA. We show that the choice of initiation site is governed by the splicing process itself and by the nature of the excised intron.     

The cyclic nucleotide phosphodiesterase of Dictyostelium discoideum: the structure of the gene and its regulation and role in development

The cyclic nucleotide phosphodiesterase (phosphodiesterase) of Dictyostelium discoideum plays an essential role in development by hydrolyzing the cAMP used as a chemoattractant by aggregating cells. We have studied the biochemistry of the phosphodiesterase and a functionally related protein, the phosphodiesterase inhibitor protein, and have cloned the cognate genes. A 1.8-kb and a 2.2-kb mRNA are transcribed from the single-phosphodiesterase gene. The 2.2-kb mRNA comprises the majority of the phosphodiesterase mRNA found in differentiating cells and is transcribed only during development from a promoter at least 2.5 kb upstream of the translational start site. The 1.8-kb phosphodiesterase mRNA is detected at all stages of growth and development, is present at lower levels than the developmentally induced mRNA, and is transcribed from a site proximal to the protein-coding region. The phosphodiesterase gene contains a minimum of three exons, and a 2.3-kb intron, the longest yet reported for this organism. We have shown that the pdsA gene and four fgd genes affect the accumulation of the phosphodiesterase mRNAs, and we believe that these loci represent a significant portion of the genes regulating expression of the phosphodiesterase. The phosphodiesterase gene was introduced into cells by transformation and used as a tool to explore the effects of cAMP on the terminal stages of development. In cells expressing high levels of phosphodiesterase activity, final morphogenesis cannot be completed, and differentiated spore and stalk cells do not form. We interpret these results to support the hypothesis that cAMP plays an essential role in organizing cell movements in late development as well as in controlling the aggregation of cells in the initial phase of the developmental program.     

Fetal and variant alpha-fetoproteins are encoded by mRNAs that differ in sequence at the 5' end

The temperature-sensitive RLA209-15 fetal rat hepatocyte line grown at the nonpermissive temperature (40 degrees C, normal phenotype) produces authentic rat alpha-fetoproteins (AFPs) of 69K and 73K (fetal AFPs) which are encoded by a 2.2-kb mRNA. These cells also produce low levels of a 1.7-kb AFP mRNA and a 65K variant AFP when grown at the permissive temperature (33 degrees C, transformed phenotype). Hybrid-selected translation demonstrates that the 1.7-kb AFP mRNA encodes the 65K variant AFP. Northern blot hybridization and S1 nuclease analyses indicate that the 1.7-kb mRNA lacks sequences present in the first seven 5' exons of the 2.2-kb AFP mRNA. However, the 1.7- and 2.2-kb AFP mRNAs share common sequences extending from the beginning of the eighth exon (corresponding to nucleotide 873 of the fetal AFP mRNA) to the 3' end. Primer extension analysis suggests that the 1.7-kb RNA contains additional sequences 5' to the common regions shared by both AFP mRNAs. We have previously shown that adult rat liver produces a 1.7-kb AFP mRNA; we now report the isolation of a cDNA (ARFP5) encoding this variant AFP mRNA from an adult rat liver cDNA library. Restriction endonuclease mapping and sequence analysis of ARFP5 confirm that the 1.7- and 2.2-kb AFP mRNAs share similar sequences at the 3' region (approximately 1.1 kb). However, ARFP5 contains an additional 90 bp variant AFP mRNA-specific 5' sequence which is located in the seventh intron of the rat AFP gene.(ABSTRACT TRUNCATED AT 250 WORDS)     

The marine red alga Chondrus crispus has a highly divergent β-tubulin gene with a characteristic 5′ intron: functional and evolutionary implications

We characterized a nuclear gene and its corresponding cDNA encoding β-tubulin (gene TubB1) of the marine red alga Chondrus crispus. The deduced TubB1 protein is the most divergent β-tubulin so far reported with only 64 to 69% amino acid identity relative to other β-tubulins from higher and lower eukaryotes. Our analysis reveals that TubB1 has an accelerated evolutionary rate probably due to a release of functional constraints in connexion with a specialization of microtubular structures in rhodophytes. It further indicates that isoform diversity and functional differentiation of tubulins in eukaryotic cells may be controlled by independent selective constraints. TubB1 has a short spliceosomal intron at its 5′ end which seems to be a characteristic feature of nuclear protein-coding genes from rhodophytes. The splice junctions of the four known rhodophyte introns comply well with the corresponding consensus sequences of higher plants in agreement with previous suggestions from phylogenetic inference that red algae and green plants may be sister groups. The paucity and asymmetrical location of introns in rhodophyte genes can be explained by differential intron loss due to conversion of genes by homologous recombination with cDNAs corresponding to reverse transcribed mRNAs or partially spliced pre-mRNAs, respectively. The identification of an intron containing TubB1 cDNA in C. crispus confirms that pre-mRNAs can escape both splicing and degradation in the nucleus prior to transport into the cytoplasm. Differential Southern hybridizations under non-stringent conditions with homologous and heterologous probes suggest that C. crispus contains a second degenerate β-tubulin gene (or pseudogene?) which, however, is only distantly related to TubB1 as it is to the more conserved homologues of other organisms.