Characterization of exon skipping mutants of the COP1 gene from Arabidopsis

The removal of introns from pre-mRNA requires accurate recognition and selection of the intron splice sites. Mutations which alter splice site selection and which lead to skipping of specific exons are indicative of intron/exon recognition mechanisms involving an exon definition process. In this paper, three independent mutants to the COP1 gene in Arabidopsis which show exon skipping were identified and the mutations which alter the normal splicing pattern were characterized. The mutation in cop1–1 was a G→A change 4 nt upstream from the 3′ splice site of intron 5, while the mutation in cop1–2 was a G→A at the first nucleotide of intron 6, abolishing the conserved G within the 5′ splice site consensus. The effect of these mutations was skipping of exon 6. The mutation in cop1–8 was G→A in the final nucleotide of intron 10 abolishing the conserved G within the 3′ splice site consensus and leading to skipping of exon 11. The splicing patterns surrounding exons 6 and 11 of COP1 in these three mutant lines of Arabidopsis provide evidence for exon definition mechanisms operating in plant splicing.     

mRNA选择性剪接的分子机制

真核细胞mRNA前体经过剪接成为成熟的mRNA,而mRNA前体的选择性剪接极大地增加了蛋白质的多样性和基因表达的复杂程度,剪接位点的识别可以以跨越内含子的机制(内含子限定)或跨越外显子的机制(外显子限定)进行。选择性剪接有多种剪接形式：选择不同的剪接位点,选择不同的剪接末端,外显子的不同组合及内含子的剪接与否等。选择性剪接过程受到许多顺式元件和反式因子的调控,并与基本剪接过程紧密联系,剪接体中的一些剪接因子也参与了对选择性剪接的调控。选择性剪接也是1个伴随转录发生的过程,不同的启动子可调控产生不同的剪接产物。mRNA的选择性剪接机制多种多样,已发现RNA编辑和反式剪接也可参与选择性剪接过程。     

Characterization of an alternative splicing by a NAGNAG splice acceptor site in the porcine KIT gene

The KIT gene has been shown to have multiple functions in hematopoiesis, melanogenesis, and gametogenesis. In addition, mutations of this gene cause pigmentation disorders in humans and mice and are responsible for coat color differences in pigs. While characterizing polymorphisms in the porcine KIT gene, we detected alternative splicing (AS) of the NAGNAG splice acceptor site at the boundary of intron 4 and exon 5. This AS event generated the E and I isoforms, characterized by insertion or deletion, respectively, of CAG at the borders of coding sequence. AS patterns measured in tissue samples from two randomly selected animals did not identified any tissue-specific outcomes. Analysis of AS patterns using three breeds demonstrated that Landrace and Large White pigs expressed both the E and I isoforms. In contrast, a subset of specimens from Korean Native Pigs (KNP) yielded a single I isoform. Alignment of the sequence from several species revealed that the region between the branch point sequence (BPS) and 3′ acceptor site is conserved. However, it is appeared that the selection of either the proximal or distal splice site varied between species. To test the breed specificity the NAGNAG splice acceptor site, we constructed two lineages of minigenes from KNP and Landrace pigs harboring breed-specific mutations. The minigene splicing assay demonstrated that both types of minigenes expressed both the E and I isoforms in two host cell lines, and no differences were detected in the AS pattern between the two breeds. We conclude that the AS at the NAGNAG splice acceptor site on intron 4/exon 5 in the porcine KIT gene is the result of noise selection at the splice site by the splicing machinery. Therefore, this AS event in the porcine KIT gene is unlikely to have any relationship with the coat color variations of Landrace and KNP breeds.     

Regulation of Fas alternative splicing by antagonistic effects of TIA-1 and PTB on exon definition

Fas exon 6 can be included or skipped to generate mRNAs encoding, respectively, a membrane bound form of the receptor that promotes apoptosis or a soluble isoform that prevents programmed cell death. We report that the apoptosis-inducing protein TIA-1 promotes U1 snRNP binding to the 5' splice site of intron 6, which in turn facilitates exon definition by enhancing U2AF binding to the 3' splice site of intron 5. The polypyrimidine tract binding protein (PTB) promotes exon skipping by binding to an exonic splicing silencer and inhibiting the association of U2AF and U2 snRNP with the upstream 3' splice site, without affecting recognition of the downstream 5' splice site by U1. Remarkably, U1 snRNP-mediated recognition of the 5' splice site is required both for efficient U2AF binding and for U2AF inhibition by PTB. We propose that TIA-1 and PTB regulate Fas splicing and possibly Fas-mediated apoptosis by targeting molecular events that lead to exon definition.     

PLP/DM20 ratio is regulated by hnRNPH and F and a novel G-rich enhancer in oligodendrocytes

Alternative splicing of competing 5′ splice sites is regulated by enhancers and silencers in the spliced exon. We have characterized sequences and splicing factors that regulate alternative splicing of PLP and DM20, myelin proteins produced by oligodendrocytes (OLs) by selection of 5′ splice sites in exon 3. We identify a G-rich enhancer (M2) of DM20 5′ splice site in exon 3B and show that individual G triplets forming M2 are functionally distinct and the distal group plays a dominant role. G-rich M2 and a G-rich splicing enhancer (ISE) in intron 3 share similarities in function and protein binding. The G-rich sequences are necessary for binding of hnRNPs to both enhancers. Reduction in hnRNPH and F expression in differentiated OLs correlates temporally with increased PLP/DM20 ratio. Knock down of hnRNPH increased PLP/DM20 ratio, while hnRNPF did not. Silencing hnRNPH and F increased the PLP/DM20 ratio more than hnRNPH alone, demonstrating a novel synergistic effect. Mutation of M2, but not ISE reduced the synergistic effect. Replacement of M2 and all G runs in exon 3B abolished it almost completely. We conclude that developmental changes in hnRNPH/F associated with OLs differentiation synergistically regulate PLP alternative splicing and a G-rich enhancer participates in the regulation.     

In vivo effects on intron retention and exon skipping by the U2AF large subunit and SF1/BBP in the nematode Caenorhabditis elegans

The in vivo analysis of the roles of splicing factors in regulating alternative splicing in animals remains a challenge. Using a microarray-based screen, we identified a Caenorhabditis elegans gene, tos-1, that exhibited three of the four major types of alternative splicing: intron retention, exon skipping, and, in the presence of U2AF large subunit mutations, the use of alternative 3' splice sites. Mutations in the splicing factors U2AF large subunit and SF1/BBP altered the splicing of tos-1. 3' splice sites of the retained intron or before the skipped exon regulate the splicing pattern of tos-1. Our study provides in vivo evidence that intron retention and exon skipping can be regulated largely by the identities of 3' splice sites.     

Three novel types of splicing aberrations in the tuberous sclerosis TSC2 gene caused by mutations apart from splice consensus sequences

Disease causing aberrations in both tuberous sclerosis predisposing genes, TSC1 and TSC2, comprise nearly every type of alteration with a predominance of small truncating mutations distributed over both genes. We performed an RNA based screening of the entire coding regions of both TSC genes applying the protein truncation test (PTT) and identified a high proportion of unusual splicing abnormalities affecting the TSC2 gene. Two cases exhibited different splice acceptor mutations in intron 9 (IVS9-15G-->A and IVS9-3C-->G) both accompanied by exon 10 skipping and simultaneous usage of a cryptic splice acceptor in exon 10. Another splice acceptor mutation (IVS38-18A-->G) destroyed the putative polypyrimidine structure in intron 38 and resulted in simultaneous intron retention and usage of a downstream cryptic splice acceptor in exon 39. Another patient bore a C-->T transition in intron 8 (IVS8+281C-->T) activating a splice donor site and resulting in the inclusion of a newly recognised exon in the mRNA followed by a premature stop. These splice variants deduced from experimental results are additionally supported by RNA secondary structure analysis based on free energy minimisation. Three of the reported splicing anomalies are due to sequence changes remote from exon/intron boundaries, described for the first time in TSC. These findings highlight the significance of investigating intronic changes and their consequences on the mRNA level as disease causing mutations in TSC.     

Conserved signals around the 5' splice sites in eukaryotic nuclear precursor mRNAs: G-runs are frequent in the introns and C in the exons near both 5' and 3' splice sites

It is known that the GT doublet is well conserved at the 5' exon/intron splice junction and is frequently embedded in the AGGT quartet. Although only the underlined G is invariable, splicing and ligation are accurately executed. In this work we search for additional conserved potential signals which may aid in 5' splice site recognition. Extensive searches which are not limited to a preconceived consensus sequence are carried out. We investigate the distributions of the 256 quartets in a 1000 nucleotide span around the 5' splice sites in approximately 1700 eukaryotic nuclear precursor mRNAs. Several potential signals are noted. Of particular interest are quartets containing runs of G, e.g., G4, G3T, G3C, G3A and AG3 in the intron immediately downstream and some C-containing quartets in the exon upstream of the 5' splice site. In an analogous calculation, (A)GGG(A) has also been found to be frequent in the intron, 60 nucleotides upstream and (A)CCC(A) in the exon downstream of the 3' splice site. These results are consistent with the recent indications that exon sequences may play a role in efficient splicing. Some models are proposed.     

Alternative splicing of type II procollagen exon 2 is regulated by the combination of a weak 5' splice site and an adjacent intronic stem-loop cis element

Alternative splicing of the type II procollagen gene (COL2A1) is developmentally regulated during chondrogenesis. Chondroprogenitor cells produce the type IIA procollagen isoform by splicing (including) exon 2 during pre-mRNA processing, whereas differentiated chondrocytes synthesize the type IIB procollagen isoform by exon 2 skipping (exclusion). Using a COL2A1 mini-gene and chondrocytes at various stages of differentiation, we identified a non-classical consensus splicing sequence in intron 2 adjacent to the 5' splice site, which is essential in regulating exon 2 splicing. RNA mapping confirmed this region contains secondary structure in the form of a stem-loop. Mutational analysis identified three cis elements within the conserved double-stranded stem region that are functional only in the context of the natural weak 5' splice site of exon 2; they are 1) a uridine-rich enhancer element in all cell types tested except differentiated chondrocytes; 2) an adenine-rich silencer element, and 3) an enhancer cis element functional in the context of secondary structure. This is the first report identifying key cis elements in the COL2A1 gene that modulate the cell type-specific alternative splicing switch of exon 2 during cartilage development.     

cis-elements involved in alternative splicing in the rat beta-tropomyosin gene: the 3'-splice site of the skeletal muscle exon 7 is the major site of blockage in nonmuscle cells.

We have been using the rat beta-tropomyosin (beta-TM) gene as a model system to study the mechanism of alternative splicing. The beta-TM gene spans 10 kb with 11 exons and encodes two distinct isoforms, namely skeletal muscle beta-TM and fibroblast TM-1. Exons 1-5, 8, and 9 are common to all mRNAs expressed from this gene. Exons 6 and 11 are used in fibroblasts, as well as in smooth muscle cells, whereas exons 7 and 10 are used exclusively in skeletal muscle cells. Our previous studies localized the critical elements for regulated alternative splicing to sequences within exon 7 and the adjacent upstream intron. We also demonstrated that these sequences function, in part, to regulate splice-site selection in vivo by interacting with cellular factors that block the use of the skeletal muscle exon in nonmuscle cells (1). Here we have further characterized the critical cis-acting elements involved in alternative splice site selection. Our data demonstrate that exon 7 and its flanking intron sequences are sufficient to regulate the suppression of exon 7 in nonmuscle cells when flanked by heterologous exons derived from adenovirus. We have also shown by both in vivo and in vitro assays that the blockage of exon 7 in nonmuscle cells is primarily at its 3'-splice site. A model is presented for regulated alternative splicing in both skeletal muscle and nonmuscle cells.     

Cleavage and polyadenylation specificity factor 1 (CPSF1) regulates alternative splicing of interleukin 7 receptor (IL7R) exon 6

Interleukin 7 receptor, IL7R, is expressed exclusively on cells of the lymphoid lineage, and its expression is crucial for the development and maintenance of T cells. Alternative splicing of IL7R exon 6 results in membrane-bound (exon 6 included) and soluble (exon 6 skipped) IL7R isoforms. Interestingly, the inclusion of exon 6 is affected by a single-nucleotide polymorphism associated with the risk of developing multiple sclerosis. Given the potential association of exon 6 inclusion with multiple sclerosis, we investigated the cis-acting elements and trans-acting factors that regulate exon 6 splicing. We identified multiple exonic and intronic cis-acting elements that impact inclusion of exon 6. Moreover, we utilized RNA affinity chromatography followed by mass spectrometry to identify trans-acting protein factors that bind exon 6 and regulate its splicing. These experiments identified cleavage and polyadenylation specificity factor 1 (CPSF1) among protein-binding candidates. A consensus polyadenylation signal AAUAAA is present in intron 6 of IL7R directly downstream from the 5′ splice site. Mutations to this site and CPSF1 knockdown both resulted in an increase in exon 6 inclusion. We found no evidence that this site is used to produce cleaved and polyadenylated mRNAs, suggesting that CPSF1 interaction with intronic IL7R pre-mRNA interferes with spliceosome binding to the exon 6 5′ splice site. Our results suggest that competing mRNA splicing and polyadenylation regulate exon 6 inclusion and consequently determine the ratios of soluble to membrane-bound IL7R. This may be relevant for both T cell ontogeny and function and development of multiple sclerosis.     

Complex splicing control of the human Thrombopoietin gene by intronic G runs

The human thrombopoietin (THPO) gene displays a series of alternative splicing events that provide valuable models for studying splicing mechanisms. The THPO region spanning exon 1–4 presents both alternative splicing of exon 2 and partial intron 2 (IVS2) retention following the activation of a cryptic 3′ splice site 85 nt upstream of the authentic acceptor site. IVS2 is particularly rich in stretches of 3–5 guanosines (namely, G1–G10) and we have characterized the role of these elements in the processing of this intron. In vivo studies show that runs G7–G10 work in a combinatorial way to control the selection of the proper 3′ splice site. In particular, the G7 element behaves as the splicing hub of intron 2 and its interaction with hnRNP H1 is critical for the splicing process. Removal of hnRNP H1 by RNA interference promoted the usage of the cryptic 3′ splice site so providing functional evidence that this factor is involved in the selection of the authentic 3′ splice site of THPO IVS2.     

Defective splicing induced by 4NQO in the hamster hprt gene

The molecular analysis of mutations affecting mRNA processing may contribute to a better understanding of the splicing mechanism through the identification of genomic sequences necessary for the recognition of splice sites. In this paper we report the sequence analysis of 14 splice mutants induced by 4-nitroquinoline 1-oxide (4NQO) at the hamster hypoxanthine-guanine-phosphoribosyltransferase (hprt) locus. We show that mutations at the 3′ acceptor splice site or at the first or fifth base of the 5′ donor splice site are responsible for exon skipping. In addition, mutations in exon sequences also determine the skipping of one or more exons. Our data indicate that point mutations in intron regions at either side of an internal exon may induce the skipping of the same exon, supporting a model where the exon is the unit of early spliceosome assembly. Furthermore, they suggest that the splicing of hprt mRNA precursors may proceed through a clustering of exons 2, 3 and 4 which are then spliced in a concerted way.     

Elements regulating an alternatively spliced exon of the rat fibronectin gene.

We have investigated the regulation of splicing of one of the alternatively spliced exons in the rat fibronectin gene, the EIIIB exon. This 273-nucleotide exon is excluded by some cells and included to various degrees by others. We find that EIIIB is intrinsically poorly spliced and that both its exon sequences and its splice sites contribute to its poor recognition. Therefore, cells which recognize the EIIIB exon must have mechanisms for improving its splicing. Furthermore, in order for EIIB to be regulated, a balance must exist between the EIIIB splice sites and those of its flanking exons. Although the intron upstream of EIIIB does not appear to play a role in the recognition of EIIIB for splicing, the intron downstream contains sequence elements which can promote EIIIB recognition in a cell-type-specific fashion. These elements are located an unusually long distance from the exon that they regulate, more than 518 nucleotides downstream from EIIIB, and may represent a novel mode of exon regulation.