A cold-sensitive mRNA splicing mutant is a member of the RNA helicase gene family.

Strauss, Evelyn; Guthrie, Christine

doi:10.1101/gad.5.4.629

Cited by 142 publications

(104 citation statements)

References 75 publications

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“…Since PRP2 activity is an essential requirement for the first transesterification reaction (27) PRP2A spliceosomes could not process pre-mRNA into spliced mRNA (Fig. 3A, lanes 3-5), and they formed splicing complex I but no splicing complex 11 (28,29 and data not shown). Complementation with a heat-inactivated temperature-sensitive prp8 extract restored splicing activity (Fig.…”

Section: Methodsmentioning

confidence: 97%

“…A prp8 allele has been isolated as a genetic suppressor ofthe DEAD-box protein splicing factor PRP28, a putative RNA helicase. From this a model was proposed in which PRP28 protein destabilizes the U4/U6 snRNA interaction prior to step 1 of splicing, counterbalanced by a stabilizing effect of PRP8 protein (11). A mutation affecting another DEAD-box protein, DED1, has been isolated as a cold-sensitive suppressor of a temperature-sensitive prp8 allele (12).…”

Section: Introductionmentioning

confidence: 99%

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Interaction of the yeast splicing factor PRP8 with substrate RNA during both steps of splicing

1995

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PRP8 protein of Saccharomyces cerevisiae interacts directly with pre-mRNA in spliceosomes, shown previously by UV-crosslinking. To analyse at which steps of splicing and with which precursor-derived RNA species the interaction(s) take place, UV-crosslinking was combined with PRP8-specific immunoprecipitation and the coprecipitated RNA species were analysed. Specific precipitation of intron-exon 2 and excised intron species was observed. PRP8 protein could be UV-crosslinked to pre-mRNA in PRP2-depleted spliceosomes stalled before initiation of the splicing reaction. Thus, the interaction of PRP8 protein with substrate RNA is established prior to the first transesterification reaction, is maintained during both steps of splicing and continues with the excised intron after completion of the splicing reaction. RNase Ti treatment of spliceosomes revealed that substrate RNA fragments of the 5' splice site region and the branchpoint-3' splice site region could be coimmunoprecipitated with PRP8 specific antibodies, indicating that these are potential sites of interaction for PRP8 protein with substrate RNA. Protection of the branchpoint-3' splice site region was detected only after step 1 of splicing. The results allow a first glimpse at the pattem of PRP8 protein-RNA interactions during splicing and provide a fundamental basis for future analysis of these interactions.

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Section: Methodsmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Interaction of the yeast splicing factor PRP8 with substrate RNA during both steps of splicing

1995

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“…In addition to the above-discussed contacts with the pre-mRNA, Prp8 is expected to interact with a number of spliceosomal components+ An allele of PRP8 ( prp8-201) was found to suppress a cold-sensitive allele of U4 snRNA+ The mutation in prp8-201 maps close to the region involved in polypyrimidine tract recognition (Kuhn et al+, 1999;Umen & Guthrie, 1996)+ Prp40, a component of yeast U1 snRNP, physically interacts with the proline-rich domain at the N-terminus of yPrp8 (Abovich & Rosbash, 1997)+ Finally, Prp8 was shown to genetically interact with two putative helicases: DED1 (Jamieson et al+, 1991) and Prp28 (Strauss & Guthrie, 1991)+ Interestingly, the human homolog of Prp28 (U5-100kD) is also an integral component of the U5 snRNP (Teigelkamp et al+, 1997), suggesting that Prp8 may directly interact with Prp28 and possibly other U5 snRNP components, including U5 snRNA+ While the crosslinking studies have confirmed a close contact between Prp8 and pre-mRNA, Prp8 also has been shown to interact with a series of other spliceosomal components throughout the reaction+ Thus, it is likely that Prp8 plays a central role in splicing, coordinating a series of events through interactions with several spliceosomal components, and perhaps participating in formation of the active site of the splice-osome+ This could be achieved either by providing a binding site for the splice sites, or possibly also by contributing to the chemical reaction in a more direct way+ At present, the mechanistic details concerning the pre-mRNA splicing catalysis are not known+ The catalytic center is likely to involve a combination of specific RNA:RNA interactions and other contacts that rely on amino acid residues+ Because of the discussed close contacts between Prp8, pre-mRNA, and other spliceosomal components, as well as the established RNA: RNA interactions involving U2 and U6 snRNAs, it seems likely that Prp8, along with U2 and U6 snRNAs, participates in formation of the catalytic center+…”

Section: Prp8 Interacts With Multiple Spliceosomal Componentsmentioning

confidence: 99%

The C-terminal region of hPrp8 interacts with the conserved GU dinucleotide at the 5′ splice site

Reyes

Gustafson

Luo

et al. 1999

RNA

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A U5 snRNP protein, hPrp8, forms a UV-induced crosslink with the 59 splice site (59SS) RNA within splicing complex B assembled in trans-as well as in cis-splicing reactions. Both yeast and human Prp8 interact with the 59SS, branch site, polypyrimidine tract, and 39SS during splicing. To begin to define functional domains in Prp8 we have mapped the site of the 59SS crosslink within the hPrp8 protein. Immunoprecipitation analysis limited the site of crosslink to the C-terminal 50-60-kDa segment of hPrp8. In addition, size comparison of the crosslink-containing peptides generated with different proteolytic reagents with the pattern of fragments predicted from the hPrp8 sequence allowed for mapping of the crosslink to a stretch of five amino acids in the C-terminal portion of hPrp8 (positions 1894-1898). The site of the 59SS:hPrp8 crosslink falls within a segment spanning the previously defined polypyrimidine tract recognition domain in yPrp8, suggesting that an overlapping region of Prp8 may be involved both in the 59SS and polypyrimidine tract recognition events. In the context of other known interactions of Prp8, these results suggest that this protein may participate in formation of the catalytic center of the spliceosome.

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“…However, genetic approaches have led to the isolation of many splicing deficient mutants, called prp mutants (20,21). Some PRP genes encode snRNP components, such as PRP4, PRP8 and PRP24 (14,19,(22)(23)(24) and others, such as PRP2, PRP5, PRP9, PRP11, PRP16, PRP22 and PRP28, are implicated in spliceosome assembly or disassembly (25)(26)(27)(28)(29)(30)(31).…”

Section: Introductionmentioning

confidence: 99%

The biochemical defects ofprp4-1andprp6-1yeast splicing mutants reveal that the PRP6 protein is required for the accumulation of the [U4/U6.U5] tri-snRNP

Galisson

Legrain

1993

Nucl Acids Res

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A cold-sensitive mRNA splicing mutant is a member of the RNA helicase gene family.

Cited by 142 publications

References 75 publications

Interaction of the yeast splicing factor PRP8 with substrate RNA during both steps of splicing

Interaction of the yeast splicing factor PRP8 with substrate RNA during both steps of splicing

The C-terminal region of hPrp8 interacts with the conserved GU dinucleotide at the 5′ splice site

The biochemical defects ofprp4-1andprp6-1yeast splicing mutants reveal that the PRP6 protein is required for the accumulation of the [U4/U6.U5] tri-snRNP

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