A role for exon sequences and splice-site proximity in splice-site selection

Analysis of the in vitro splicing products of RNA precursors containing tandem duplications of the 5' or 3' splice sites of human beta-globin IVS 1 revealed that exon sequences play an important role in the relative use of the duplicated sites. These studies also show that the proximity of the 5' and 3' splice sites is an important determinant in the selection of splice-sites. Deletion, substitution, or even subtle changes of exon sequences can alter the pattern of splice-site selection, and in many cases the splice site adjacent to the altered exon is not used. The relative use of the duplicated splice sites can also be altered by diluting the splicing extract, suggesting that factors involved in splice-site selection are limiting.     

Identification and characterization by antisense oligonucleotides of exon and intron sequences required for splicing.

Certain thalassemic human beta-globin pre-mRNAs carry mutations that generate aberrant splice sites and/or activate cryptic splice sites, providing a convenient and clinically relevant system to study splice site selection. Antisense 2'-O-methyl oligoribonucleotides were used to block a number of sequences in these pre-mRNAs and were tested for their ability to inhibit splicing in vitro or to affect the ratio between aberrantly and correctly spliced products. By this approach, it was found that (i) up to 19 nucleotides upstream from the branch point adenosine are involved in proper recognition and functioning of the branch point sequence; (ii) whereas at least 25 nucleotides of exon sequences at both 3' and 5' ends are required for splicing, this requirement does not extend past the 5' splice site sequence of the intron; and (iii) improving the 5' splice site of the internal exon to match the consensus sequence strongly decreases the accessibility of the upstream 3' splice site to antisense 2'-O-methyl oligoribonucleotides. This result most likely reflects changes in the strength of interactions near the 3' splice site in response to improvement of the 5' splice site and further supports the existence of communication between these sites across the exon.     

Regulation of alternative RNA splicing by exon definition and exon sequences in viral and mammalian gene expression

Intron removal from a pre-mRNA by RNA splicing was once thought to be controlled mainly by intron splicing signals. However, viral and other eukaryotic RNA exon sequences have recently been found to regulate RNA splicing, polyadenylation, export, and nonsense-mediated RNA decay in addition to their coding function. Regulation of alternative RNA splicing by exon sequences is largely attributable to the presence of two majorcis-acting elements in the regulated exons, the exonic splicing enhancer (ESE) and the suppressor or silencer (ESS). Two types of ESEs have been verified from more than 50 genes or exons: purine-rich ESEs, which are the more common, and non-purine-rich ESEs. In contrast, the sequences of ESSs identified in approximately 20 genes or exons are highly diverse and show little similarity to each other. Through interactions with cellular splicing factors, an ESE or ESS determines whether or not a regulated splice site, usually an upstream 3 splice site, will be used for RNA splicing. However, how these elements function precisely in selecting a regulated splice site is only partially understood. The balance between positive and negative regulation of splice site selection likely depends on thecis-element's identity and changes in cellular splicing factors under physiological or pathological conditions.     

A combinatorial role for exon, intron and splice site sequences in splicing in maize

Plant introns are typically AU-rich or U-rich, and this feature has been shown to be important for splicing. In maize, however, about 20% of the introns exceed 50% GC, and most of them are efficiently spliced. A series of constructs has been designed to analyze the cis requirements for splicing of the GC-rich Bz2 maize intron and two other GC-rich intron derivatives. By manipulating exon, intron and splice site sequences it is shown that exons can play an important role in intron definition: changes in exon sequences can increase splicing efficiency of a GC-rich intron from 17% to 86%. The relative difference, or base compositional contrast, in GC and U content between exon and intron sequences in the vicinity of splice sites, rather than the absolute base-content of the intron or exons, correlates with splicing efficiency. It is also shown that GC-rich intron constructs that are poorly spliced can be partially rescued by an improved 3' splice site.     

Regulation of tau exon 10 splicing by a double stem-loop structure in mouse intron 10

Tau exon 10 (E10) splicing is a crucial event in its developmental change of tau isoform and tauopathy. To investigate the splicing mechanism, we isolated and compared mouse tau genomic sequence with human sequence. We identified a new element in mouse intron 10 (I10) to suppress E10 splicing, which was located just after the stem-loop region previously proposed in human sequence and found to potentially form another stem-loop. Human I10 with a mutation (+29G to A) causing a decreased E10 splicing was also predicted to form similar double stem-loop, suggesting that this element is universally involved in regulation of E10 splicing.     

Trans splicing in Oenothera mitochondria: nad1 mRNAs are edited in exon and trans-splicing group II intron sequences.

The complete NADH dehydrogenase subunit 1 (nad1) ORF in Oenothera mitochondria is encoded by five exons. These exons are located in three distant locations of the mitochondrial genome. One genomic region encodes exon a, the second encodes exons b and c, and the third specifies exons d and e. Cis-splicing group II introns separate exons b and c and d and e, while trans-splicing reactions are required to link exons a and b and c and d. The two parts of the group II intron sequences involved in these trans-splicing events can be aligned in domain IV. Exon sequences and the maturase-related ORF in intron d/e are edited by numerous C to U alterations in the mRNA. Two RNA editing events in the trans-splicing intron a/b improve conservation of the secondary structure in the stem of domain VI. RNA editing in intron sequences may thus be required for the trans-splicing reaction.     

Defective splicing, disease and therapy: searching for master checkpoints in exon definition

The number of aberrant splicing processes causing human disease is growing exponentially and many recent studies have uncovered some aspects of the unexpectedly complex network of interactions involved in these dysfunctions. As a consequence, our knowledge of the various cis- and trans-acting factors playing a role on both normal and aberrant splicing pathways has been enhanced greatly. However, the resulting information explosion has also uncovered the fact that many splicing systems are not easy to model. In fact we are still unable, with certainty, to predict the outcome of a given genomic variation. Nonetheless, in the midst of all this complexity some hard won lessons have been learned and in this survey we will focus on the importance of the wide sequence context when trying to understand why apparently similar mutations can give rise to different effects. The examples discussed in this summary will highlight the fine ‘balance of power’ that is often present between all the various regulatory elements that define exon boundaries. In the final part, we shall then discuss possible therapeutic targets and strategies to rescue genetic defects of complex splicing systems.     

Activation of cryptic splice sites is a frequent splicing defect mechanism caused by mutations in exon and intron sequences of the OPA1 gene

Mutations in OPA1 are the most frequent cause underlying autosomal dominant optic atrophy (adOA). Until now only few putative splicing mutations in the OPA1 gene have been investigated at the mRNA level and all these result in exon skipping. Here, we report the identification and cDNA analysis of four intronic and three exonic OPA1 gene mutations that cause a variety of splicing defects including activation of cryptic splice sites in either flanking exon or intron sequences, and a leaky splicing mutation. Our results show that cDNA analysis is of prime importance for the full evaluation of the effect of putative splicing mutations in the OPA1 gene.     

Group II intron splicing in chloroplasts: identificationof mutations determining intron stability and fate of exon RNA.

In order to investigate in vivo splicing of group II introns in chloroplasts, we previously have integrated the mitochondrial intron rI1 from the green alga Scenedesmus obliquus into the Chlamydomonas chloroplast tscA gene. This construct allows a functional analysis of conserved intron sequences in vivo, since intron rI1 is correctly spliced in chloroplasts. Using site-directed mutagenesis, deletions of the conserved intron domains V and VI were performed. In another set of experiments, each possible substitution of the strictly conserved first intron nucleotide G1 was generated, as well as each possible single and double mutation of the tertiary base pairing gamma-gamma ' involved in the formation of the intron's tertiary RNA structure. In most cases, the intron mutations showed the same effect on in vivo intron splicing efficiency as they did on the in vitro self-splicing reaction, since catalytic activity is provided by the intron RNA itself. In vivo, all mutations have additional effects on the chimeric tscA -rI1 RNA, most probably due to the role played by trans -acting factors in intron processing. Substitutions of the gamma-gamma ' base pair lead to an accumulation of excised intron RNA, since intron stability is increased. In sharp contrast to autocatalytic splicing, all point mutations result in a complete loss of exon RNA, although the spliced intron accumulates to high levels. Intron degradation and exon ligation only occur in double mutants with restored base pairing between the gamma and gamma' sites. Therefore, we conclude that intron degradation, as well as the ligation of exon-exon molecules, depends on the tertiary intron structure. Furthermore, our data suggest that intron excision proceeds in vivo independent of ligation of exon-exon molecules.     

The human polycystic kidney disease 2-like (PKDL) gene: exon/intron structure and evidence for a novel splicing mechanism

Polycystin-L is a member of the expanding family of polycystins. Mutations in polycystin-1 or -2 cause human autosomal dominant polycystic kidney disease (ADPKD). The mouse ortholog of PKDL, Pkdl, is deleted in a mouse line with renal and retinal defects. We recently have shown that polycystin-L has calcium channel properties. In the current study, we determined the exon/intron organization of the PKDL gene and its alternative splicing. We show that PKDL has 16 exons. All splice acceptor/donor sites for these exons conform to the GT-AG rule. The positions of introns and the sizes of exons in the PKDL gene are very similar to those of PKD2, except for the last two 3′ end exons. RT-PCR demonstrates the existence of at least three polycystin-L splice variants: PKDL(Δ5), PKDL(Δ456), and PKDL(Δ15) that are expressed in a tissue-specific manner. In addition, we have localized polymorphic marker D10S603 to intron 4 and exon 5 of PKDL. Elucidation of the gene structure, exact location, and alternative splicing patterns of PKDL will facilitate its evaluation as a candidate gene in cystic or other genetic disorders. Received: 26 July 1999 / Accepted: 16 September 1999     

Exon and intron sequences, respectively, repress and activate splicing of a fibroblast growth factor receptor 2 alternative exon.

Two alternative exons, BEK and K-SAM, code for part of the ligand binding site of fibroblast growth factor receptor 2. Splicing of these exons is mutually exclusive, and the choice between them is made in a tissue-specific manner. We identify here pre-mRNA sequences involved in controlling splicing of the K-SAM exon. The short K-SAM exon sequence 5'-TAGGGCAGGC-3' inhibits splicing of the exon. This inhibition can be overcome by mutating either the exon's 5' or 3' splice site to make it correspond more closely to the relevant consensus sequence. Two separate sequence elements in the intron immediately downstream of the K-SAM exon, one of which is a sequence rich in pyrimidines, are both needed for efficient K-SAM exon splicing. This is no longer the case if either the exon's 5' or 3' splice site is reinforced. Furthermore, if the exon inhibitory sequence is removed, the intron sequences are not required for splicing of the K-SAM exon in a cell line which normally splices this exon. At least three elements are thus involved in controlling splicing of the K-SAM exon: suboptimal 5' and 3' splice sites, an exon inhibitory sequence, and intron activating sequences.     

Alternative splicing of a human alpha-tropomyosin muscle-specific exon: identification of determining sequences.

The human alpha-tropomyosin gene hTMnm has two mutually exclusive versions of exon 5 (NM and SK), one of which is expressed specifically in skeletal muscle (exon SK). A minigene construct expresses only the nonmuscle (NM) isoform when transfected into COS-1 cells and both forms when transfected into myoblasts. Twenty-four mutants were produced to determine why the SK exon is not expressed in COS cells. The results showed that exons NM and SK are not in competition for splicing to the flanking exons and that there is no intrinsic barrier to splicing between the exons. Instead, exon SK is skipped whenever there are flanking introns. Splicing of exon SK was induced when the branch site sequence 70 nucleotides upstream of the exon was mutated to resemble the consensus and when the extremities of the exon itself were changed to the corresponding NM sequence. Precise swaps of the NM and SK exon sequences showed that the exon sequence effect was dominant to that of intron sequences. The mechanism of regulation appears to be unlike that of other tropomyosin genes. We propose that exclusion of exon SK arises because its 3' splicing signals are weak and are prevented by an exon-specific repressor from competing for splice site recognition.     

Ribozyme stability, exon skipping, and a potential role for RNA helicase in group I intron splicing by Coxiella burnetii

The 23S rRNA gene of Coxiella burnetii, the agent of Q fever in humans, contains an unusually high number of conserved, selfish genetic elements, including two group I introns, termed Cbu.L1917 (L1917) and Cbu.L1951 (L1951). To better understand the role that introns play in Coxiella's biology, we determined the intrinsic stability time periods (in vitro half-lives) of the encoded ribozymes to be ～15 days for L1917 and ～5 days for L1951, possibly due to differences in their sizes (551 and 1,559 bases, respectively), relative degrees of compactness of the respective RNA structures, and amounts of single-stranded RNA. In vivo half-lives for both introns were also determined to be ～11 min by the use of RNase protection assays and an Escherichia coli model. Intron RNAs were quantified in synchronous cultures of C. burnetii and found to closely parallel those of 16S rRNA; i.e., ribozyme levels significantly increased between days 0 and 3 and then remained stable until 8 days postinfection. Both 16S rRNA and ribozyme levels fell during the stationary and death phases (days 8 to 14). The marked stability of the Coxiella intron RNAs is presumably conferred by their association with ribosomes, a stoichiometric relationship that was determined to be one ribozyme, of either type, per 500 ribosomes. Inaccuracies in splicing (exon 2 skipping) were found to increase during the first 5 days in culture, with a rate of approximately one improperly spliced 23S rRNA per 1.3 million copies. The in vitro efficiency of L1917 intron splicing was significantly enhanced in the presence of a recombinant Coxiella RNA DEAD-box helicase (CBU_0670) relative to that of controls, suggesting that this enzyme may serve as an intron RNA splice facilitator in vivo.     

Stepwise assembly of a pre-mRNA splicing complex requires U-snRNPs and specific intron sequences

We have investigated the early events of pre-mRNA splicing in vitro by sucrose gradient sedimentation analysis. Time course experiments revealed the assembly, in two steps, of a large (50S) pre-mRNA splicing complex, preceded by formation of two other complexes that sediment at approximately 22S and 35S. Pre-mRNA and the intermediates and products of the in vitro splicing reaction cosediment with the 50S complex, while only pre-mRNA is associated with the 22S and 35S complexes. No splicing is observed in the absence of a 50S complex. Formation of the 50S complex requires ATP, whereas formation of the 22S and 35S complexes does not. U-snRNPs are necessary for assembly of the 35S and the 50S complexes but not for assembly of the 22S complex. Analysis with mutant substrate RNAs demonstrated that a polypyrimidine stretch near the 3' splice site and an intact 5' splice site are absolutely required for splicing complex formation.     

A novel mutation in erythropoietic protoporphyria: an aberrant ferrochelatase mRNA caused by exon skipping during RNA splicing

An aberrant ferrochelatase mRNA lacking exon 10 was found in a patient with erythropoietic protoporphyria (EPP). In her genomic DNA an A → T transversion at position ?3 of the donor site of intron 10 appeared to be responsible for the exon skipping. Both the patient and her sister were heterozygous for this mutation.