Olaf Isken scite author profile

Cells routinely make mistakes. Some mistakes are encoded by the genome and may manifest as inherited or acquired diseases. Other mistakes occur because metabolic processes can be intrinsically inefficient or inaccurate. Consequently, cells have developed mechanisms to minimize the damage that would result if mistakes went unchecked. Here, we provide an overview of three quality control mechanisms-nonsense-mediated mRNA decay, nonstop mRNA decay, and no-go mRNA decay. Each surveys mRNAs during translation and degrades those mRNAs that direct aberrant protein synthesis. Along with other types of quality control that occur during the complex processes of mRNA biogenesis, these mRNA surveillance mechanisms help to ensure the integrity of protein-encoding gene expression.Cellular RNAs are generally subject to quality control or surveillance pathways that guard against defects in gene expression (for recent reviews, see Dimaano

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Upf1 Phosphorylation Triggers Translational Repression during Nonsense-Mediated mRNA Decay

Isken

Kim

Hosoda

et al. 2008

Cell

265

292

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In mammalian cells, nonsense-mediated mRNA decay (NMD) generally requires that translation terminates sufficiently upstream of a post-splicing exon junction complex (EJC) during a pioneer round of translation. The subsequent binding of Upf1 to the EJC triggers Upf1 phosphorylation. We provide evidence that phospho-Upf1 functions after nonsense codon recognition during steps that involve the translation initiation factor eIF3 and mRNA decay factors. Phospho-Upf1 interacts directly with eIF3 and inhibits the eIF3-dependent conversion of 40S/Met-tRNA(i)(Met)/mRNA to translationally competent 80S/Met-tRNA(i)(Met)/mRNA initiation complexes to repress continued translation initiation. Consistent with phospho-Upf1 impairing eIF3 function, NMD fails to detectably target nonsense-containing transcripts that initiate translation independently of eIF3 from the CrPV IRES. There is growing evidence that translational repression is a key transition that precedes mRNA delivery to the degradation machinery. Our results uncover a critical step during NMD that converts a pioneer translation initiation complex to a translationally compromised mRNP.

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The multiple lives of NMD factors: balancing roles in gene and genome regulation

2008

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Nonsense-mediated mRNA decay (NMD) largely functions to ensure the quality of gene expression. However, NMD is also crucial to regulating appropriate expression levels for certain genes and for maintaining genome stability. Furthermore, just as NMD serves cells in multiple ways, so do its constituent proteins. Recent studies have clarified that UPF and SMG proteins, which were originally discovered to function in NMD, also have roles in other pathways, including specialized pathways of mRNA decay, DNA synthesis and cell-cycle progression, and the maintenance of telomeres. These findings suggest a delicate balance of metabolic events — some not obviously related to NMD — that can be influenced by the cellular abundance, location and activity of NMD factors and their binding partners.

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The Pioneer Round of Translation: Features and Functions

Maquat

Tarn

Isken

2010

Cell

205

218

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In mammalian cells, newly synthesized mRNAs undergo a pioneer round of translation that is important for mRNA quality control. Following maturation of messenger ribonucleoprotein particles during and after the pioneer round, steady-state cycles of mRNA translation generate most of the cell’s proteins. Translation factors, RNA binding proteins and targets of signaling pathways that are particular to newly synthesized mRNAs regulate critical functions of the pioneer round.

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Nuclear factors are involved in hepatitis C virus RNA replication

Isken¹,

Baroth²,

Grassmann³

et al. 2007

RNA

146

171

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Unraveling the molecular basis of the life cycle of hepatitis C virus (HCV), a prevalent agent of human liver disease, entails the identification of cell-encoded factors that participate in the replication of the viral RNA genome. This study provides evidence that the so-called NF/NFAR proteins, namely, NF90/NFAR-1, NF110/NFAR-2, NF45, and RNA helicase A (RHA), which mostly belong to the dsRBM protein family, are involved in the HCV RNA replication process. NF/NFAR proteins were shown to specifically bind to replication signals in the HCV genomic 59 and 39 termini and to promote the formation of a looplike structure of the viral RNA. In cells containing replicating HCV RNA, the generally nuclear NF/NFAR proteins accumulate in the cytoplasmic viral replication complexes, and the prototype NFAR protein, NF90/NFAR-1, stably interacts with a viral protein.HCV replication was inhibited in cells where RNAi depleted RHA from the cytoplasm. Likewise, HCV replication was hindered in cells that contained another NF/NFAR protein recruiting virus. The recruitment of NF/NFAR proteins by HCV is assumed to serve two major purposes: to support 59-39 interactions of the viral RNA for the coordination of viral protein and RNA synthesis and to weaken host-defense mechanisms.

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Olaf Isken

Quality control of eukaryotic mRNA: safeguarding cells from abnormal mRNA function

Upf1 Phosphorylation Triggers Translational Repression during Nonsense-Mediated mRNA Decay

The multiple lives of NMD factors: balancing roles in gene and genome regulation

The Pioneer Round of Translation: Features and Functions

Nuclear factors are involved in hepatitis C virus RNA replication

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