Rna14p, a component of the yeast nuclear Cleavage / Polyadenylation Factor I, is also localised in mitochondria

RNA14 was identified as a gene involved in premessenger RNA cleavage and polyadenylation. These processing steps take place in the nucleus, but the Rna14p protein is distributed in both the nucleus and the cytoplasm. By subcellular fractionation, we show here that the cytoplasmic fraction is localised in the mitochondria. In order to understand the role played by Rna14p in mitochondria, we have searched for new thermosensitive alleles of RNA14. We isolated thirteen new mutants. Some of them are deficient in mRNA cleavage and polyadenylation at the restrictive temperature – like the first mutant identified (rna14-1). However, others do not appear to be impaired in any of the steps in RNA metabolism investigated, nor do they appear to be involved in the replication or expression of mitochondrial DNA or in respiration. The localisation data strongly suggest that, besides an essential function in mRNA polyadenylation, the Rna14p protein has a non essential function in mitochondrial metabolism.     

Locked tether formation by cooperative folding of Rna14p monkeytail and Rna15p hinge domains in the yeast CF IA complex

The removal of the 3' region of pre-mRNA followed by polyadenylation is a key step in mRNA maturation. In the yeast Saccharomyces cerevisiae, one component of the processing machinery is the cleavage/polyadenylation factor IA (CF IA) complex, composed of four proteins (Clp1p, Pcf11p, Rna14p, Rna15p) that recognize RNA sequences adjacent to the cleavage site and recruit additional processing factors. To gain insight into the molecular architecture of CF IA we solved the solution structure of the heterodimer composed of the interacting regions between Rna14p and Rna15p. The C-terminal monkeytail domain from Rna14p and the hinge region from Rna15p display a coupled binding and folding mechanism, where both peptides are initially disordered. Mutants with destabilized monkeytail-hinge interactions prevent association of Rna15p within CF IA. Conservation of interdomain residues reveals that the structural tethering is preserved in the homologous mammalian cleavage stimulation factor (CstF)-77 and CstF-64 proteins of the CstF complex.     

Rna15 Interaction with the A-Rich Yeast Polyadenylation Signal Is an Essential Step in mRNA 3′-End Formation

In Saccharomyces cerevisiae, four factors [cleavage factor I (CF I), CF II, polyadenylation factor I (PF I), and poly(A) polymerase (PAP)] are required for maturation of the 3' end of the mRNA. CF I and CF II are required for cleavage; a complex of PAP and PF I, which includes CF II subunits, participates in polyadenylation, along with CF I. These factors are directed to the appropriate site on the mRNA by two sequences: one A-rich and one UA-rich. CF I contains five proteins, two of which, Rna15 and Hrp1, interact with the mRNA through RNA recognition motif-type RNA binding motifs. Previous work demonstrated that the UV cross-linking of purified Hrp1 to RNA required the UA-rich element, but the contact point of Rna15 was not known. We show here that Rna15 does not recognize a particular sequence in the absence of other proteins. However, in complex with Hrp1 and Rna14, Rna15 specifically interacts with the A-rich element. The Pcf11 and Clp1 subunits of CF I are not needed to position Rna15 at this site. This interaction is essential to the function of CF I. A mutant Rna15 with decreased affinity for RNA is defective for in vitro RNA processing and lethal in vivo, while an RNA with a mutation in the A-rich element is not processed in vitro and can no longer be UV cross-linked to the Rna15 subunit assembled into CF I. Thus, the recognition of the A-rich element depends on the tethering of Rna15 through an Rna14 bridge to Hrp1 bound to the UA-rich motif. These results illustrate that the yeast 3' end is defined and processed by a mechanism surprisingly different from that used by the mammalian system.     

Chemical shift assignments of a minimal Rna14p/Rna15p heterodimer from the yeast cleavage factor IA complex

The two yeast proteins Rna14p and Rna15p form part of the cleavage/polyadenylation factor IA (CF IA) complex that is involved in the 3′ processing of pre-mRNA. Association of the two proteins is mediated by a small C-terminal peptide from Rna14p and a region in Rna15p that corresponds to the hinge domain first identified within the human orthologue. Here I report the ¹H, ¹³C and ¹⁵N spectral assignments for a bacterially co-expressed heterodimer of Rna14p/Rna15p. Further analysis of secondary chemical shifts reveals that both peptides are predominantly α-helical within the complex.     

Reconstitution of CF IA from overexpressed subunits reveals stoichiometry and provides insights into molecular topology

Yeast cleavage factor I (CF I) is an essential complex of five proteins that binds signal sequences at the 3' end of yeast mRNA. CF I is required for correct positioning of a larger protein complex, CPF, which contains the catalytic subunits executing mRNA cleavage and polyadenylation. CF I is composed of two parts, CF IA and Hrp1. The CF IA has only four subunits, Rna14, Rna15, Pcf11, and Clp1, but the structural organization has not been fully established. Using biochemical and biophysical methods, we demonstrate that CF IA can be reconstituted from bacterially expressed proteins and that it has 2:2:1:1 stoichiometry of its four proteins, respectively. We also describe mutations that disrupt the dimer interface of Rna14 while preserving the other subunit interactions. On the basis of our results and existing interaction data, we present a topological model for heterohexameric CF IA and its association with RNA and Hrp1.     

Regulation of tRNA suppressor activity by an intron-encoded polyadenylation signal.

A 26-nt sequence from the 3' UTR of the yeast GAL7 mRNA directs accurate and efficient cleavage and polyadenylation to form the 3' end of the GAL7 mRNA in vivo and in vitro. Here we asked whether this polyadenylation signal can function within the context of a tRNA. Insertion of the GAL7 signal into the intron of the dominant SUP4 nonsense suppressor allowed us to judge the effect of the insert on SUP4 function by observation of nonsense suppression efficiency in vivo. The GAL7 signal impairs the function of SUP4 in an orientation-dependent manner in vivo, consistent with its ability to specify cleavage and polyadenylation in this context in vitro. Mutation of a UA repeat within the GAL7 signal restores SUP4 function partially, consistent with the role of this repeat as an efficiency element in polyadenylation. Mutations that impair the mRNA 3' end-processing factors Rna14p and Rna15p restore suppressor function partially. Northern blot analysis, PCR amplification, and DNA sequence analysis show that the GAL7 signal directs polyadenylation within the body of pre-SUP4 and within the terminator, suggesting that polyadenylation inhibits 5' and 3' end processing, as well as removal of the pre-tRNA intron. These findings indicate that the GAL7 polyadenylation signal is capable of targeting a pre-tRNA to the mRNA processing pathway.     

Conditional defect in mRNA 3'' end processing caused by a mutation in the gene for poly(A) polymerase.

Maturation of most eukaryotic mRNA 3' ends requires endonucleolytic cleavage and polyadenylation of precursor mRNAs. To further understand the mechanism and function of mRNA 3' end processing, we identified a temperature-sensitive mutant of Saccharomyces cerevisiae defective for polyadenylation. Genetic analysis showed that the polyadenylation defect and the temperature sensitivity for growth result from a single mutation. Biochemical analysis of extracts from this mutant shows that the polyadenylation defect occurs at a step following normal site-specific cleavage of a pre-mRNA at its polyadenylation site. Molecular cloning and characterization of the wild-type allele of the mutated gene revealed that it (PAP1) encodes a previously characterized poly(A) polymerase with unknown RNA substrate specificity. Analysis of mRNA levels and structure in vivo indicate that shift of growing, mutant cells to the nonpermissive temperature results in the production of poly(A)-deficient mRNAs which appear to end at their normal cleavage sites. Interestingly, measurement of the rate of protein synthesis after the temperature shift shows that translation continues long after the apparent loss of polyadenylated mRNA. Our characterization of the pap1-1 defect implicates this gene as essential for mRNA 3' end formation in S. cerevisiae.     

Arginine methylation and binding of Hrp1p to the efficiency element for mRNA 3'-end formation

Hrp1p is a heterogeneous ribonucleoprotein (hnRNP) from the yeast Saccharomyces cerevisiae that is involved in the cleavage and polyadenylation of the 3'-end of mRNAs and mRNA export. In addition, Hrplp is one of several RNA-binding proteins that are posttranslationally modified by methylation at arginine residues. By using functional recombinant Hrp1p, we have identified RNA sequences with specific high affinity binding sites. These sites correspond to the efficiency element for mRNA 3'-end formation, UAUAUA. To examine the effect of methylation on specific RNA binding, purified recombinant arginine methyltransferase (Hmt1p) was used to methylate Hrp1p. Methylated Hrp1p binds with the same affinity to UAUAUA-containing RNAs as unmethylated Hrpl p indicating that methylation does not affect specific RNA binding. However, RNA itself inhibits the methylation of Hrp1p and this inhibition is enhanced by RNAs that specifically bind Hrpl p. Taken together, these data support a model in which protein methylation occurs prior to protein-RNA binding in the nucleus.     

Mpe1, a Zinc Knuckle Protein, Is an Essential Component of Yeast Cleavage and Polyadenylation Factor Required for the Cleavage and Polyadenylation of mRNA

In Saccharomyces cerevisiae, in vitro mRNA cleavage and polyadenylation require the poly(A) binding protein, Pab1p, and two multiprotein complexes: CFI (cleavage factor I) and CPF (cleavage and polyadenylation factor). We characterized a novel essential gene, MPE1 (YKL059c), which interacts genetically with the PCF11 gene encoding a subunit of CFI. Mpe1p is an evolutionarily conserved protein, a homolog of which is encoded by the human genome. The protein sequence contains a putative RNA-binding zinc knuckle motif. MPE1 is implicated in the choice of ACT1 mRNA polyadenylation site in vivo. Extracts from a conditional mutant, mpe1-1, or from a wild-type extract immunoneutralized for Mpe1p are defective in 3'-end processing. We used the tandem affinity purification (TAP) method on strains TAP-tagged for Mpe1p or Pfs2p to show that Mpe1p, like Pfs2p, is an integral subunit of CPF. Nevertheless a stable CPF, devoid of Mpe1p, was purified from the mpe1-1 mutant strain, showing that Mpe1p is not directly involved in the stability of this complex. Consistently, Mpe1p is also not necessary for the processive polyadenylation, nonspecific for the genuine pre-mRNA 3' end, displayed by the CPF alone. However, a reconstituted assay with purified CFI, CPF, and the recombinant Pab1p showed that Mpe1p is strictly required for the specific cleavage and polyadenylation of pre-mRNA. These results show that Mpe1p plays a crucial role in 3' end formation probably by promoting the specific link between the CFI/CPF complex and pre-mRNA.     

Characterization of the Distal Polyadenylation Site of the ?-Adducin (Add2) Pre-mRNA

Most genes have multiple polyadenylation sites (PAS), which are often selected in a tissue-specific manner, altering protein products and affecting mRNA stability, subcellular localization and/or translability. Here we studied the polyadenylation mechanisms associated to the beta-adducin gene (Add2). We have previously shown that the Add2 gene has a very tight regulation of alternative polyadenylation, using proximal PAS in erythroid tissues, and a distal one in brain. Using chimeric minigenes and cell transfections we identified the core elements responsible for polyadenylation at the distal PAS. Deletion of either the hexanucleotide motif (Hm) or the downstream element (DSE) resulted in reduction of mature mRNA levels and activation of cryptic PAS, suggesting an important role for the DSE in polyadenylation of the distal Add2 PAS. Point mutation of the UG repeats present in the DSE, located immediately after the cleavage site, resulted in a reduction of processed mRNA and in the activation of the same cryptic site. RNA-EMSA showed that this region is active in forming RNA-protein complexes. Competition experiments showed that RNA lacking the DSE was not able to compete the RNA-protein complexes, supporting the hypothesis of an essential important role for the DSE. Next, using a RNA-pull down approach we identified some of the proteins bound to the DSE. Among these proteins we found PTB, TDP-43, FBP1 and FBP2, nucleolin, RNA helicase A and vigilin. All these proteins have a role in RNA metabolism, but only PTB has a reported function in polyadenylation. Additional experiments are needed to determine the precise functional role of these proteins in Add2 polyadenylation.     

Novel Protein-Protein Contacts Facilitate mRNA 3′-Processing Signal Recognition by Rna15 and Hrp1

Precise 3′-end processing of mRNA is essential for correct gene expression, yet in yeast, 3′-processing signals consist of multiple ambiguous sequence elements. Two neighboring elements upstream of the cleavage site are particularly important for the accuracy (positioning element) and efficiency (efficiency element) of 3′-processing and are recognized by the RNA-binding proteins Rna15 and Hrp1, respectively. In vivo, these interactions are strengthened by the scaffolding protein Rna14 that stabilizes their association. The NMR structure of the 34 -kDa ternary complex of the RNA recognition motif (RRM) domains of Hrp1 and Rna15 bound to this pair of RNA elements was determined by residual dipolar coupling and paramagnetic relaxation experiments. It reveals how each of the proteins binds to RNA and introduces a novel class of protein-protein contact in regions of previously unknown function. These interdomain contacts had previously been overlooked in other multi-RRM structures, although a careful analysis suggests that they may be frequently present. Mutations in the regions of these contacts disrupt 3′-end processing, suggesting that they may structurally organize the ribonucleoprotein complexes responsible for RNA processing.