Stress granules (SGs) and processing bodies (PBs) are microscopically visible ribonucleoprotein granules that cooperatively regulate the translation and decay of messenger RNA1–3. Using an RNA-mediated interference-based screen, we identify 101 human genes required for SG assembly, 39 genes required for PB assembly, and 31 genes required for coordinate SG and PB assembly. Although 51 genes encode proteins involved in mRNA translation, splicing and transcription, most are not obviously associated with RNA metabolism. We find that several components of the hexosamine biosynthetic pathway, which reversibly modifies proteins with O-linked N-acetylglucosamine (O-GlcNAc) in response to stress, are required for SG and PB assembly. O-GlcNAc-modified proteins are prominent components of SGs but not PBs, and include RACK1 (receptor for activated C kinase 1), prohibitin-2, glyceraldehyde-3-phosphate dehydrogenase and numerous ribosomal proteins. Our results suggest that O-GlcNAc modification of the translational machinery is required for aggregation of untranslated messenger ribonucleoproteins into SGs. The lack of enzymes of the hexosamine biosynthetic pathway in budding yeast may contribute to differences between mammalian SGs and related yeast EGP (eIF4E, 4G and Pab1 containing) bodies.
The precise transcriptional regulation of gene expression is essential for vertebrate development, but the role of posttranscriptional regulatory mechanisms is less clear. Cytoplasmic RNA granules (RGs) function in the posttranscriptional control of gene expression, but the extent of RG involvement in organogenesis is unknown. We describe two human cases of pediatric cataract with loss-of-function mutations in TDRD7 and demonstrate that Tdrd7 nullizygosity in mouse causes cataracts, as well as glaucoma and an arrest in spermatogenesis. TDRD7 is a Tudor domain RNA binding protein that is expressed in lens fiber cells in distinct TDRD7-RGs that interact with STAU1-ribonucleoproteins (RNPs). TDRD7 coimmunoprecipitates with specific lens messenger RNAs (mRNAs) and is required for the posttranscriptional control of mRNAs that are critical to normal lens development and to RG function. These findings demonstrate a role for RGs in vertebrate organogenesis.
The mouse CAF1 (mCAF1) is an ortholog of the yeast (y) CAF1 protein, which is a component of the CCR4-NOT complex, the major cytoplasmic deadenylase of Saccharomyces cerevisiae. Although CAF1 protein belongs to the DEDDh family of RNases, CCR4 appears to be the principle deadenylase of the CCR4-NOT complex. Here, we present evidence that mCAF1 is a processive, 3 -5 -RNase with a preference for poly(A) substrates. Like CCR4, increased length of RNA substrates converted mCAF1 into a processive enzyme. In contrast to two other DEDD family members, PAN2 and PARN, mCAF1 was not activated either by PAB1 or capped RNA substrates. The rate of deadenylation in vitro by yCCR4 and mCAF1 were both strongly influenced by secondary structures present in sequences adjacent to the poly(A) tail, suggesting that the ability of both enzymes to deadenylate might be affected by the context of the mRNA 3 -untranslated region sequences. The ability of mCAF1 to complement a ycaf1 deletion in yeast, however, did not require the RNase function of mCAF1. Importantly, yCAF1 mutations, which have been shown to block its RNase activity in vitro, did not inactivate yCAF1 in vivo, and mRNAs were deadenylated in vivo at nearly the same rate as found for wild type yCAF1. These results indicate that at least in yeast the CAF1 RNase activity is not required for its in vivo function.
Stress granules (SGs) are cytoplasmic foci at which untranslated mRNAs accumulate in cells exposed to environmental stress. We have identified ornithine decarboxylase (ODC), an enzyme required for polyamine synthesis, and eIF5A, a polyamine (hypusine)-modified translation factor, as proteins required for arsenite-induced SG assembly. Knockdown of deoxyhypusine synthase (DHS) or treatment with a deoxyhypusine synthase inhibitor (GC7) prevents hypusine modification of eIF5A as well as arsenite-induced polysome disassembly and stress granule assembly. Time-course analysis reveals that this is due to a slowing of stress-induced ribosome run-off in cells lacking hypusine-eIF5A. Whereas eIF5A only marginally affects protein synthesis under normal conditions, it is required for the rapid onset of stress-induced translational repression. Our results reveal that hypusine-eIF5A-facilitated translation elongation promotes arsenite-induced polysome disassembly and stress granule assembly in cells subjected to adverse environmental conditions.
The evolutionarily conserved PUF proteins stimulate CCR4 mRNA deadenylation through binding to 3′ UTR sequences of specific mRNA. We have investigated the mechanisms by which PUF3 in Saccharomyces cerevisiae accelerates deadenylation of the COX17 mRNA. PUF3 was shown to affect PAN2 deadenylation of the COX17 mRNA independent of the presence of CCR4, suggesting that PUF3 acts though a general mechanism to affect deadenylation. Similarly, eIF4E, the cap-binding translation initiation factor, known to control CCR4 deadenylation, was shown to affect PAN2 activity in vivo. PUF3 was found to be required for eIF4E effects on COX17 deadenylation. Both eIF4E and PUF3 effects on deadenylation were shown, in turn, to necessitate a functional poly(A) binding protein (PAB1) in which removal of the RRM1 domain of PAB1 blocked both their effects on deadenylation. While removal of the proline-rich region (P domain) of PAB1 substantially reduces CCR4 deadenylation at non-PUF3 controlled mRNA and correspondingly blocked eIF4E effects on deadenylation, PUF3 essentially bypassed this P domain requirement. These results indicate that the PAB1-mRNP structure is critical for PUF3 action. We also found that multiple components of the CCR4-NOT deadenylase complex but not PAN2 interacted with PUF3. PUF3 appears, therefore, both to act independently of CCR4 activity, possibly through effects on PAB1-mRNP structure, and to be capable of retaining the CCR4-NOT complex.
Serine/arginine-rich splicing factor 3 (SRSF3), a member of the serine/arginine (SR)-rich family of proteins, regulates both alternative splicing of pre-mRNA and export of mature mRNA from the nucleus. Although its role in nuclear mRNA processing is well understood, the mechanism by which it alters the fate of cytoplasmic mRNA molecules remains elusive. Here, we provide evidence that SRSF3 not only regulates the alternative splicing pattern of programmed cell death 4 (PDCD4) mRNA, but also modulates its translational efficiency in the cytoplasm by lowering translation levels. We observed a marked increase in PDCD4 mRNA in translating polysome fractions upon silencing of SRSF3, and, conversely, ectopic overexpression of SRSF3 shifted PDCD4 mRNA into non-translating ribosomal fractions. In live cells, SRSF3 colocalized with PDCD4 mRNA in P-bodies (PBs), where translationally silenced mRNAs are deposited, and this localization was abrogated upon SRSF3 silencing. Furthermore, using two different reporter systems, we showed that SRSF3 interacts directly with PDCD4 mRNA and mediates translational repression by binding to the 5 0 -untranslated region (5 0 -UTR). In summary, our data suggest that the oncogenic potential of SRSF3 might be realized, in part, through the translational repression of PDCD4 mRNA.
Stress granules (SGs) harbour translationally stalled messenger ribonucleoproteins and play important roles in regulating gene expression and cell fate. Here we show that neddylation promotes SG assembly in response to arsenite-induced oxidative stress. Inhibition or depletion of key components of the neddylation machinery concomitantly inhibits stress-induced polysome disassembly and SG assembly. Affinity purification and subsequent mass-spectrometric analysis of Nedd8-conjugated proteins from translationally stalled ribosomal fractions identified ribosomal proteins, translation factors and RNA-binding proteins (RBPs), including SRSF3, a previously known SG regulator. We show that SRSF3 is selectively neddylated at Lys85 in response to arsenite. A non-neddylatable SRSF3 (K85R) mutant do not prevent arsenite-induced polysome disassembly, but fails to support the SG assembly, suggesting that the neddylation pathway plays an important role in SG assembly.
U2 snRNP auxiliary factor 65 kDa (U2AF 65 ) is a general splicing factor that contacts polypyrimidine (Py) tract and promotes prespliceosome assembly. In this report, we show that U2AF 65 stimulates alternative exon skipping in spinal muscular atrophy (SMA)-related survival motor neuron (SMN) pre-mRNA. A stronger 5′ splice-site mutation of alternative exon abolishes the stimulatory effects of U2AF 65 . U2AF 65 overexpression promotes its own binding only on the weaker, not the stronger, Py tract. We further demonstrate that U2AF 65 inhibits splicing of flanking introns of alternative exon in both three-exon and two-exon contexts. Similar U2AF 65 effects were observed in Fas (Apo-1/CD95) pre-mRNA. Strikingly, we demonstrate that U2AF 65 even inhibits general splicing of adenovirus major late (Ad ML) or β-globin pre-mRNA. Thus, we conclude that U2AF 65 possesses a splicing Inhibitory function that leads to alternative exon skipping.U2AF 65 | pre-mRNA splicing | splicing inhibition | exon exclusion | SMN P re-mRNA splicing is a process in which noncoding intron sequences are removed and exon sequences are then ligated together (1, 2). Pre-mRNA splicing is carried out by spliceosome, a large RNA-protein complex that contains five small nuclear ribonucleoproteins (U snRNPs) and more than 100 additional proteins (3). Pre-mRNA splicing occurs in the consensus sequences at the 5′ splice-site, 3′ splice-site, and branch point that are necessary for splicing. The sequence between 3′ AG dinucleotide and branch point is the polypyrimidine (Py) tract that directs spliceosome assembly on the 3′ splice-site. Alternative splicing provides an important regulatory mechanism in higher eukaryotes for multiple proteins produced from a single gene (4, 5).The U2 snRNP auxiliary factor 65 kDa (U2AF 65 ) exists as a heterodimer with U2AF 35 (6). U2AF 65 contains three C-terminal RNA recognition motifs (RRMs) and an N-terminal arginine/ serine-rich (RS) domain (7,8). Using U2AF 65 depletion/adding back technology with in vitro HeLa nuclear extract, it was demonstrated that U2AF 65 is an essential splicing factor (9). Whereas U2AF 65 binds to Py tract to promote prespliceosome assembly and branchpoint/U2 snRNA base pairing, U2AF 35 plays a role in the 3′ splice-site (10, 11). As U2AF 65 prefers high C/U-rich sequences in the Py tract, a stronger interaction between U2AF 65 and Py tract promotes prespliceosome assembly (12). U2AF 65 is also essential in vertebrate development (13,14). Its expression level is related to myotonic dystrophy, cystic fibrosis, and cancers (15, 16).Proximal spinal muscular atrophy (SMA) is an autosomal recessive genetic disease (17) and a leading cause of infant mortality. The motor neurons in the anterior horn of spinal cord are severely damaged in patients with type 1 SMA, usually leading to death before age 2 y as a result of a lack of respiratory support (18,19). In patients with SMA, the SMN1 gene is deleted or mutated, whereas the SMN2 gene, a duplicate of the SMN1 gene, is included (20). SMN2 genomic DNA...
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.