Clare Gooding scite author profile

Polypyrimdine tract binding protein (PTB) is a regulator of alternative splicing, mRNA 3' end formation, mRNA stability and localization, and IRES-mediated translation. Transient overexpression of PTB can influence alternative splicing, sometimes resulting in nonphysiological splicing patterns. Here, we show that alternative skipping of PTB exon 11 leads to an mRNA that is removed by NMD and that this pathway consumes at least 20% of the PTB mRNA in HeLa cells. We also show that exon 11 skipping is itself promoted by PTB in a negative feedback loop. This autoregulation may serve both to prevent disruptively high levels of PTB expression and to restore nuclear levels when PTB is mobilized to the cytoplasm. Our findings suggest that alternative splicing can act not only to generate protein isoform diversity but also to quantitatively control gene expression and complement recent bioinformatic analyses, indicating a high prevalence of human alternative splicing leading to NMD.

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Heteromeric RNP Assembly at LINEs Controls Lineage-Specific RNA Processing

Attig

Federico

Gooding

et al. 2018

Cell

139

152

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SummaryLong mammalian introns make it challenging for the RNA processing machinery to identify exons accurately. We find that LINE-derived sequences (LINEs) contribute to this selection by recruiting dozens of RNA-binding proteins (RBPs) to introns. This includes MATR3, which promotes binding of PTBP1 to multivalent binding sites within LINEs. Both RBPs repress splicing and 3′ end processing within and around LINEs. Notably, repressive RBPs preferentially bind to evolutionarily young LINEs, which are located far from exons. These RBPs insulate the LINEs and the surrounding intronic regions from RNA processing. Upon evolutionary divergence, changes in RNA motifs within LINEs lead to gradual loss of their insulation. Hence, older LINEs are located closer to exons, are a common source of tissue-specific exons, and increasingly bind to RBPs that enhance RNA processing. Thus, LINEs are hubs for the assembly of repressive RBPs and also contribute to the evolution of new, lineage-specific transcripts in mammals.Video Abstract

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Differential alternative splicing activity of isoforms of polypyrimidine tract binding protein (PTB)

Wollerton

Gooding

Robinson

et al. 2001

RNA

131

157

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Polypyrimidine tract binding protein (PTB) is an RNA-binding protein that regulates splicing by repressing specific splicing events. It also has roles in 39-end processing, internal initiation of translation, and RNA localization. PTB exists in three alternatively spliced isoforms, PTB1, PTB2, and PTB4, which differ by the insertion of 19 or 26 amino acids, respectively, between the second and third RNA recognition motif domains. Here we show that the PTB isoforms have distinct activities upon a-tropomyosin (TM) alternative splicing. PTB1 reduced the repression of TM exon 3 in transfected smooth muscle cells, whereas PTB4 enhanced TM exon 3 skipping in vivo and in vitro. PTB2 had an intermediate effect. The PTB4 . PTB2 . PTB1 repressive hierarchy was observed in all in vivo and in vitro assays with TM, but the isoforms were equally active in inducing skipping of a-actinin exons and showed the opposite hierarchy of activity when tested for activation of IRES-driven translation. These findings establish that the ratio of PTB isoforms could form part of a cellular code that in turn controls the splicing of various other pre-mRNAs.

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Polypyrimidine Tract Binding Protein Functions as a Repressor To Regulate Alternative Splicing of α-Actinin Mutally Exclusive Exons

Southby

Gooding

Smith

1999

Molecular and Cellular Biology

132

144

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The smooth muscle (SM) and nonmuscle (NM) isoforms of ␣-actinin are produced by mutually exclusive splicing of an upstream NM exon and a downstream SM-specific exon. A rat ␣-actinin genomic clone encompassing the mutually exclusive exons was isolated and sequenced. The SM exon was found to utilize two branch points located 382 and 386 nucleotides (nt) upstream of the 3 splice site, while the NM exon used a single branch point 191 nt upstream. Mutually exclusive splicing arises from the proximity of the SM branch points to the NM 5 splice site, and this steric repression could be relieved in part by the insertion of spacer elements. In addition, the SM exon is repressed in non-SM cells and extracts. In vitro splicing of spacercontaining transcripts could be activated by (i) truncation of the transcript between the SM polypyrimidine tract and exon, (ii) addition of competitor RNAs containing the 3 end of the actinin intron or regulatory sequences from ␣-tropomyosin (TM), and (iii) depletion of the splicing extract by using biotinylated ␣-TM RNAs. A number of lines of evidence point to polypyrimidine tract binding protein (PTB) as the trans-acting factor responsible for repression. PTB was the only nuclear protein observed to cross-link to the actinin RNA, and the ability of various competitor RNAs to activate splicing correlated with their ability to bind PTB. Furthermore, repression of ␣-actinin splicing in the nuclear extracts depleted of PTB by using biotinylated RNA could be specifically restored by the addition of recombinant PTB. Thus, ␣-actinin mutually exclusive splicing is enforced by the unusual location of the SM branch point, while constitutive repression of the SM exon is conferred by regulatory elements between the branch point and 3 splice site and by PTB.Many eukaryotic genes employ alternative splicing as a means of generating protein diversity. This differential incorporation of exons into the mature RNA is often under developmental and/or tissue-specific control and enables the cell to tailor the protein to suit its own particular requirements (61, 67). The basic splicing mechanism involves a two-step process which takes place in a ribonucleoprotein complex called a spliceosome and results in adjacent exons being joined together with the intron between released in the form of a lariat (reviewed in references 1 and 57). There is a further level of complexity in alternative splicing in that different combinations of 5Ј and 3Ј splice sites are ligated. The mechanisms that determine which splice sites are utilized and how this is regulated in different cell types or developmental stages have still not been precisely defined. Much progress has been made in identifying the cis-acting elements involved in alternative splicing, and the roles of some general factors have been demonstrated (1, 67). cis-Acting determinants that influence competing splicing pathways include the relative strengths of the competing 5Ј splice sites (e.g., 9, 78), branch point sequences (e.g., 53, 79), and polypyrimidine tracts...

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Smooth muscle-specific switching of alpha-tropomyosin mutually exclusive exon selection by specific inhibition of the strong default exon.

et al. 1994

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Exons 2 and 3 of alpha‐tropomyosin are spliced in a strict mutually exclusive manner. Exon 3 is a default choice, being selected in almost all cell types where the gene is expressed. The default selection arises from a competition between the two exons, in which the stronger branch point/pyrimidine tract elements of exon 3 win. Exon 2 is selected predominantly or exclusively only in smooth muscle cells. We show here that the basis for the smooth muscle‐specific switching of exon selection is inhibition of exon 3. Exon 3 is still skipped with smooth muscle specificity, even in the absence of exon 2. We have defined two conserved sequence elements, one in each of the introns flanking exon 3, that are essential for this regulation. Mutation of either element severely impairs regulated suppression of exon 3. No other exon or intron sequences appear to be necessary for regulation. We have also demonstrated skipping of exon 3 that is dependent upon both regulatory elements in an in vitro splicing assay. We further show that both splice sites of exon 3 must be inhibited in a concerted fashion to switch to selection of exon 2. This may relate to the requirement for negative elements on both sides of the exon.

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Clare Gooding

Autoregulation of Polypyrimidine Tract Binding Protein by Alternative Splicing Leading to Nonsense-Mediated Decay

Heteromeric RNP Assembly at LINEs Controls Lineage-Specific RNA Processing

Differential alternative splicing activity of isoforms of polypyrimidine tract binding protein (PTB)

Polypyrimidine Tract Binding Protein Functions as a Repressor To Regulate Alternative Splicing of α-Actinin Mutally Exclusive Exons

Smooth muscle-specific switching of alpha-tropomyosin mutually exclusive exon selection by specific inhibition of the strong default exon.

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