SMG-8 and SMG-9, two novel subunits of the SMG-1 complex,regulate remodeling of the mRNA surveillance complex during nonsense-mediated mRNA decay

Nonsense-mediated mRNA decay (NMD) is a surveillance mechanism that detects and degrades mRNAs containing premature translation termination codons (PTCs). SMG-1 and Upf1 transiently form a surveillance complex termed “SURF” that includes eRF1 and eRF3 on post-spliced mRNAs during recognition of PTC. If an exon junction complex (EJC) exists downstream from the SURF complex, SMG-1 phosphorylates Upf1, the step that is a rate-limiting for NMD. We provide evidence of an association between the SURF complex and the ribosome in association with mRNPs, and we suggest that the SURF complex functions as a translation termination complex during NMD. We identified SMG-8 and SMG-9 as novel subunits of the SMG-1 complex. SMG-8 and SMG-9 suppress SMG-1 kinase activity in the isolated SMG-1 complex and are involved in NMD in both mammals and nematodes. SMG-8 recruits SMG-1 to the mRNA surveillance complex, and inactivation of SMG-8 induces accumulation of a ribosome:Upf1:eRF1:eRF3:EJC complex on mRNP, which physically bridges the ribosome and EJC through eRF1, eRF3, and Upf1. These results not only reveal the regulatory mechanism of SMG-1 kinase but also reveal the sequential remodeling of the ribosome:SURF complex to the predicted DECID (DECay InDucing) complex, a ribosome:SURF:EJC complex, as a mechanism of in vivo PTC discrimination.     

Binding of a novel SMG-1-Upf1-eRF1-eRF3 complex (SURF) to the exon junction complex triggers Upf1 phosphorylation and nonsense-mediated mRNA decay

Nonsense-mediated mRNA decay (NMD) is a surveillance mechanism that degrades mRNA containing premature termination codons (PTCs). In mammalian cells, recognition of PTCs requires translation and depends on the presence on the mRNA with the splicing-dependent exon junction complex (EJC). While it is known that a key event in the triggering of NMD is phosphorylation of the trans-acting factor, Upf1, by SMG-1, the relationship between Upf1 phosphorylation and PTC recognition remains undetermined. Here we show that SMG-1 binds to the mRNA-associated components of the EJC, Upf2, Upf3b, eIF4A3, Magoh, and Y14. Further, we describe a novel complex that contains the NMD factors SMG-1 and Upf1, and the translation termination release factors eRF1 and eRF3 (SURF). Importantly, an association between SURF and the EJC is required for SMG-1-mediated Upf1 phosphorylation and NMD. Thus, the SMG-1-mediated phosphorylation of Upf1 occurs on the association of SURF with EJC, which provides the link between the EJC and recognition of PTCs and triggers NMD.     

Human SMG-1, a novel phosphatidylinositol 3-kinase-related protein kinase, associates with components of the mRNA surveillance complex and is involved in the regulation of nonsense-mediated mRNA decay

Nonsense-mediated mRNA decay (NMD) is a conserved surveillance mechanism that eliminates imperfect mRNAs that contain premature translation termination codons (PTCs) and code for nonfunctional or potentially harmful polypeptides. We show that a novel phosphatidylinositol 3-kinase-related protein kinase, hSMG-1, is a human ortholog of a product of Caenorhabditis elegans smg-1, one of seven smg genes involved in NMD. hSMG-1 phosphorylates hUPF1/SMG-2 in vivo and in vitro at specific serine residues in SQ motifs. hSMG-1 can associate with hUPF1/SMG-2 and other components of the surveillance complex. In particular, overexpression of a kinase-deficient point mutant of hSMG-1, hSMG-1-DA, results in a marked suppression of the PTC-dependent beta-globin mRNA degradation; whereas that of wild-type hSMG-1 enhances it. We also show that inhibitors of hSMG-1 induce the accumulation of truncated p53 proteins in human cancer cell lines with p53 PTC mutation. Taken together, we conclude that hSMG-1 plays a critical role in NMD through the direct phosphorylation of hUPF1/SMG-2 in the evolutionally conserved mRNA surveillance complex.     

Role of SMG‐1‐mediated Upf1 phosphorylation in mammalian nonsense‐mediated mRNA decay

SMG‐1, a member of the PIKK (phosphoinositide 3‐kinase‐related kinase) family, plays a critical role in the mRNA quality control system known as nonsense‐mediated mRNA decay (NMD). NMD protects cells from the accumulation of aberrant mRNAs with premature termination codons (PTCs) which encode nonfunctional or potentially harmful truncated proteins. SMG‐1 directly phosphorylates Upf1 helicase, another key component of NMD, upon recognition of PTC on postspliced mRNA during the initial round of translation. Phosphorylated‐Upf1 recruits the SMG‐5/SMG‐7 complex to induce ribosome dissociation and decapping‐mediated decay. Phospho‐Upf1 also recruits the SMG‐6 endonuclease which might be involved in endo‐cleavage. Upf1 ATPase/helicase activities are likely required for the activation of other mRNA decay enzymes and the mRNA‐protein complex dissociation to complete NMD. At present, a variety of tools are available that can specifically suppress NMD, and it has become possible to examine the contribution of NMD in a variety of physiological and pathological conditions.     

Genetic background affects relative nonsense mRNA accumulation in wild-type and<Emphasis Type="Italic"> upf</Emphasis> mutant yeast strains

The Saccharomyces cerevisiae nonsense-mediated mRNA decay (NMD) pathway targets mRNAs with premature stop codons and some wild-type mRNAs for accelerated decay. Upf1p, Upf2p and Upf3p are required for NMD. NMD-targeted mRNAs are degraded rapidly in wild-type cells and stabilized in upf1, upf2 or upf3 mutants. We report here that the relative CYH2 pre-mRNA/mRNA accumulation is enhanced in cells derived from a W303 background, compared with a variety of commonly used strains. The enhanced CYH2 pre-mRNA accumulation phenotype results from a larger difference in mRNA half-lives in the W303 strains than two previously used strains. This phenotype can be selected in crosses and is also seen in upf2 and upf3 mutants. These results suggest there are genes that influence the efficiency of NMD and that yeast strains derived from the W303 background may be useful for measurement of abundance and half-lives of low abundance, short-lived NMD substrates.     

Splicing enhances translation in mammalian cells: an additional function of the exon junction complex

In mammalian cells, spliced mRNAs yield greater quantities of protein per mRNA molecule than do otherwise identical mRNAs not made by splicing. This increased translational yield correlates with enhanced cytoplasmic polysome association of spliced mRNAs, and is attributable to deposition of exon junction complexes (EJCs). Translational stimulation can be replicated by tethering the EJC proteins Y14, Magoh, and RNPS1 or the nonsense-mediated decay (NMD) factors Upf1, Upf2, and Upf3b to an intronless reporter mRNA. Thus, in addition to its previously characterized role in NMD, the EJC also promotes mRNA polysome association. Furthermore, the ability to stimulate translation when bound inside an open reading frame appears to be a general feature of factors required for NMD.     

The SMG5–SMG7 heterodimer directly recruits the CCR4–NOT deadenylase complex to mRNAs containing nonsense codons via interaction with POP2

Nonsense-mediated mRNA decay (NMD) is a eukaryotic quality control mechanism that detects aberrant mRNAs containing nonsense codons and induces their rapid degradation. This degradation is mediated by SMG6, an NMD-specific endonuclease, as well as the SMG5 and SMG7 proteins, which recruit general mRNA decay enzymes. However, it remains unknown which specific decay factors are recruited and whether this recruitment is direct. Here, we show that SMG7 binds directly to POP2, a catalytic subunit of the CCR4–NOT deadenylase complex, and elicits deadenylation-dependent decapping and 5′-to-3′ decay of NMD targets. Accordingly, a catalytically inactive POP2 mutant partially suppresses NMD in human cells. The SMG7–POP2 interaction is critical for NMD in cells depleted of SMG6, indicating that SMG7 and SMG6 act redundantly to promote the degradation of NMD targets. We further show that UPF1 provides multiple binding sites for decapping factors. These data unveil a missing direct physical link between NMD and the general mRNA decay machinery and indicate that NMD employs diverse and partially redundant mechanisms to ensure robust degradation of aberrant mRNAs.     

The Nek8 protein kinase, mutated in the human cystic kidney disease nephronophthisis, is both activated and degraded during ciliogenesis

Mutations in the never-in-mitosis A-related kinase, Nek8, are associated with cystic kidney disease in both humans and mice, with Nek8 being the NPHP9 gene in the human juvenile cystic kidney disease, nephronophthisis. Human Nek8/NPHP9 localizes to centrosomes and the proximal region of cilia in dividing and ciliated cells, respectively. However, the regulation of Nek8 kinase activity, as well as its role in ciliogenesis, remains to be defined. Here, by establishing Nek8 kinase assays, we first demonstrate that the localization of Nek8 to centrosomes and cilia is dependent on both kinase activity and the C-terminal non-catalytic RCC1 domain. The kinase domain alone is active, but does not localize correctly, while the RCC1 domain localizes correctly and can be phosphorylated by Nek8. We propose that centrosome recruitment is mediated by the RCC1 domain, but requires a conformational change in the full-length protein that is promoted by autophosphorylation. Interestingly, three human NPHP9-associated mutants retain full kinase activity. However, only two of these, L330F and A497P, localize correctly, suggesting that the third mutant, H425Y, disrupts a centrosome targeting sequence in the RCC1 domain. Importantly, we find that induction of ciliogenesis upon cell cycle exit is accompanied by both activation and proteasomal degradation of Nek8, and that activation is dependent upon phosphorylation within the catalytic domain. Taken together, these findings reveal important insights into the mechanisms through which Nek8 activity and localization are regulated during ciliogenesis.     

An unusual arrangement of two 14-3-3-like domains in the SMG5–SMG7 heterodimer is required for efficient nonsense-mediated mRNA decay

The nonsense-mediated mRNA decay (NMD) pathway triggers the rapid degradation of aberrant mRNAs containing premature translation termination codons (PTCs). In metazoans, NMD requires three 14-3-3-like proteins: SMG5, SMG6, and SMG7. These proteins are recruited to PTC-containing mRNAs through the interaction of their 14-3-3-like domains with phosphorylated UPF1, the central NMD effector. Recruitment of SMG5, SMG6, and SMG7 causes NMD target degradation. In this study, we report the crystal structure of the Caenorhabditis elegans SMG5–SMG7 complex. The 14-3-3-like phosphopeptide recognition domains of SMG5 and SMG7 heterodimerize in an unusual perpendicular back-to-back orientation in which the peptide-binding sites face opposite directions. Structure-based mutants and functional assays indicate that the SMG5–SMG7 interaction is conserved and is crucial for efficient NMD in human cells. Notably, we demonstrate that heterodimerization increases the affinity of the SMG5–SMG7 complex for UPF1. Furthermore, we show that the degradative activity of the SMG5–SMG7 complex resides in SMG7 and that the SMG5–SMG7 complex and SMG6 play partially redundant roles in the degradation of aberrant mRNAs. We propose that the SMG5–SMG7 complex binds to phosphorylated UPF1 with high affinity and recruits decay factors to the mRNA target through SMG7, thus promoting target degradation.     

SMD and NMD are competitive pathways that contribute to myogenesis: effects on PAX3 and myogenin mRNAs

UPF1 functions in both Staufen 1 (STAU1)-mediated mRNA decay (SMD) and nonsense-mediated mRNA decay (NMD), which we show here are competitive pathways. STAU1- and UPF2-binding sites within UPF1 overlap so that STAU1 and UPF2 binding to UPF1 appear to be mutually exclusive. Furthermore, down-regulating the cellular abundance of STAU1, which inhibits SMD, increases the efficiency of NMD, whereas down-regulating the cellular abundance of UPF2, which inhibits NMD, increases the efficiency of SMD. Competition under physiological conditions is exemplified during the differentiation of C2C12 myoblasts to myotubes: The efficiency of SMD increases and the efficiency of NMD decreases, consistent with our finding that more STAU1 but less UPF2 bind UPF1 in myotubes compared with myoblasts. Moreover, an increase in the cellular level of UPF3X during myogenesis results in an increase in the efficiency of an alternative NMD pathway that, unlike classical NMD, is largely insensitive to UPF2 down-regulation. We discuss the remarkable balance between SMD and the two types of NMD in view of data indicating that PAX3 mRNA is an SMD target whose decay promotes myogenesis whereas myogenin mRNA is a classical NMD target encoding a protein required for myogenesis.     

In vitro functional studies of naturally occurring pathogenic PRKAR1A mutations that are not subject to nonsense mRNA decay

Patients presenting with primary pigmented nodular adrenocortical disease (PPNAD), Carney complex (CNC), or sporadic tumors were previously found to carry germline mutations in the human type Ialpha regulatory subunit (RIalpha) of adenosine 3',5'-cyclic monophosphate (cyclic AMP [cAMP])-dependent protein kinase (PKA; PRKAR1A). Although about 90% of disease-causing PRKAR1A mutations lead to premature stop codon generation and subsequent degradation of the mutant message by nonsense-mediated mRNA decay (NMD), here we describe seven PRKAR1A mutations whose mRNAs do not seem to undergo NMD and instead result in an expressed mutant RIalpha protein. The expressed mutations (p.Ser9Asn, p.Glu60_Lys116del [Delta-exon 3], p.Arg74Cys, p.Arg146Ser, p.Asp183Tyr, p.Ala213Asp, and p.Gly289Trp) were spread over all the functional RIalpha domains, and all of them exhibited increased PKA activity, which we attribute to decreased binding to cAMP and/or the catalytic subunit. Our data further corroborate the previous finding that altered PRKAR1A function, not only haploinsufficiency, is enough to elevate PKA activity which is apparently associated with tumorigenesis in tissues affected by CNC. In some cases, as with the Delta-exon 3 mutation, we may even conclude that the presence of a mutant PRKAR1A protein may be more harmful than allelic loss.     

Dendritic transport element of human arc mRNA confers RNA degradation activity in a translation‐dependent manner

Localization of mRNA in neuronal cells is a critical process for spatiotemporal regulation of gene expression. Cytoplasmic localization of mRNA is often conferred by transport elements in 3′ untranslated region (UTR). Activity‐regulated cytoskeleton‐associated protein (arc) mRNA is one of the localizing mRNAs in neuronal cells, and its localization is mediated by dendritic targeting element (DTE). As arc mRNA has introns in its 3′ UTR, it was thought that arc mRNA is a natural target of nonsense‐mediated mRNA decay (NMD). Here, we show that DTE in human arc 3′ UTR has destabilizing activity of RNA independent of NMD pathway. DTE alone was able to cause instability of the reporter mRNA and this degradation was dependent on translation. Our results indicate that DTE has dual activity in mRNA transport and degradation, which suggests the novel spatiotemporal regulation mechanism of activity‐dependent degradation of the mRNA.