An Active Role for the Ribosome in Determining the Fate of Oxidized mRNA

Simms, Carrie L.; Hudson, Benjamin H.; Mosior, John; Rangwala, Ali S.; Zaher, Hani

doi:10.1016/j.celrep.2014.10.042

Cited by 179 publications

(210 citation statements)

References 40 publications

Supporting

Mentioning

191

Contrasting

Unclassified

Order By: Relevance

“…This finding, together with the finding that the kinetics of tRNA decay upon amino acid starvation are similar in wild-type E. coli and a relA mutant, suggests that tRNA instability is not a unique consequence of the stringent response, but may occur as a general response to stresses that reduce translation. 14 The argument is supported by a recent report of extensive tRNA degradation during oxidative stress, 30 which causes stalling of ribosomes at 8-oxoG residues in the mRNA 31 and thereby also limits the pool of functionally intact mRNA available for translation. Since the capacity to synthesize new protein is severely reduced during amino acid starvation, a tRNA-degradation mechanism that depends on synthesis of new protein may not be feasible.…”

Section: A Demand-based Model For Trna Degradationmentioning

confidence: 94%

Transfer RNA instability as a stress response inEscherichia coli: Rapid dynamics of the tRNA pool as a function of demand

2018

View full text Add to dashboard Cite

Production of the translation apparatus of E. coli is carefully matched to the demand for protein synthesis posed by a given growth condition. For example, the fraction of RNA polymerases that transcribe rRNA and tRNA drops from 80% during rapid growth to 24% within minutes of a sudden amino acid starvation. We recently reported in Nucleic Acids Research that the tRNA pool is more dynamically regulated than previously thought. In addition to the regulation at the level of synthesis, we found that tRNAs are subject to demand-based regulation at the level of their degradation. In this point-of-view article we address the question of why this phenomenon has not previously been described. We also present data that expands on the mechanism of tRNA degradation, and we discuss the possible implications of tRNA instability for the ability of E. coli to cope with stresses that affect the translation process.

show abstract

Section: A Demand-based Model For Trna Degradationmentioning

confidence: 94%

Transfer RNA instability as a stress response inEscherichia coli: Rapid dynamics of the tRNA pool as a function of demand

2018

View full text Add to dashboard Cite

show abstract

“…Whatever the mechanism, it is clear that m 6 G at the second position slows translation at least 1000-fold. Such a strong roadblock would likely engage the ribosomal rescue pathways (tmRNA in bacteria and No-Go Decay in eukaryotes) (Doma and Parker 2006;Moore and Sauer 2007;Tsuboi et al 2012) as we have observed recently for mRNAs containing the oxidation adduct 8-oxo-G (Simms et al 2014). Further study will be necessary to delineate how m 6 G at the second position stalls translation and to assess what effect this would have on cellular fitness.…”

Section: Discussionmentioning

confidence: 99%

“…Dipeptide products were then resolved by electrophoretic TLC and the overall efficiency of peptide-bond formation assessed by quantifying the amount of dipeptide products relative to unreacted fMet (Youngman et al 2004). This approach has been recently used by our laboratory to monitor the efficiency of incorporation of every single amino acid and, importantly, recapitulates to a large extent the level of fidelity measured in vivo (Simms et al 2014).…”

Section: Effects Of Mmentioning

confidence: 99%

“…Reporter mRNAs with m 6 G were synthesized using RNA ligation as described previously (Simms et al 2014). Briefly, an upstream RNA encoding a 3 ′ hammerhead ribozyme was PCR amplified and transcribed with T7 RNA polymerase and then purified by denaturing PAGE.…”

Section: Reagentsmentioning

confidence: 99%

“…However, it is clear from the limited studies that the ribosomal response to damaged mRNA does not always recapitulate the responses of DNA polymerases to damaged DNA. For instance, our laboratory has recently shown that the oxidized base 8-oxoguanosine, which mispairs with A during DNA replication, instead stalls the translation machinery (Simms et al 2014).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

O6-Methylguanosine leads to position-dependent effects on ribosome speed and fidelity

Hudson

Zaher

2015

RNA

View full text Add to dashboard Cite

Nucleic acids are under constant assault from endogenous and environmental agents that alter their physical and chemical properties. O6-methylation of guanosine (m 6 G) is particularly notable for its high mutagenicity, pairing with T, during DNA replication. Yet, while m 6 G accumulates in both DNA and RNA, little is known about its effects on RNA. Here, we investigate the effects of m 6 G on the decoding process, using a reconstituted bacterial translation system. m 6 G at the first and third position of the codon decreases the accuracy of tRNA selection. The ribosome readily incorporates near-cognate aminoacyltRNAs (aa-tRNAs) by forming m 6 G-uridine codon-anticodon pairs. Surprisingly, the introduction of m 6 G to the second position of the codon does not promote miscoding, but instead slows the observed rates of peptide-bond formation by >1000-fold for cognate aa-tRNAs without altering the rates for near-cognate aa-tRNAs. These in vitro observations were recapitulated in eukaryotic extracts and HEK293 cells. Interestingly, the analogous modification N6-methyladenosine (m 6 A) at the second position has only a minimal effect on tRNA selection, suggesting that the effects on tRNA selection seen with m 6 G are due to altered geometry of the base pair. Given that the m6G:U base pair is predicted to be nearly indistinguishable from a WatsonCrick base pair, our data suggest that the decoding center of the ribosome is extremely sensitive to changes at the second position. Our data, apart from highlighting the deleterious effects that these adducts pose to cellular fitness, shed new insight into decoding and the process by which the ribosome recognizes codon-anticodon pairs.

show abstract

Profiling the Nucleobase and Structure Selectivity of Anticancer Drugs and other DNA Alkylating Agents by RNA Sequencing

Sauter

Gillingham

2018

ChemBioChem

View full text Add to dashboard Cite

Drugs that covalently modify DNA are components of most chemotherapy regimens, often serving as first-line treatments. Classically, the reactivity and selectivity of DNA alkylating agents has been determined in vitro with short oligonucleotides. A statistically sound analysis of sequence preferences of alkylating agents is untenable with serial analysis methods because of the combinatorial explosion of sequence possibilities. Next-generation sequencing (NGS) is ideally suited for the broad characterization of sequence or structure selectivities because it analyzes many sequences at once. Herein, NGS is used to report on the chemoselectivity of alkylating agents on RNA and this technology is applied to the previously uncharacterized alkylating agent trimethylsilyl diazomethane.

show abstract

An Active Role for the Ribosome in Determining the Fate of Oxidized mRNA

Cited by 179 publications

References 40 publications

Transfer RNA instability as a stress response inEscherichia coli: Rapid dynamics of the tRNA pool as a function of demand

Transfer RNA instability as a stress response inEscherichia coli: Rapid dynamics of the tRNA pool as a function of demand

O6-Methylguanosine leads to position-dependent effects on ribosome speed and fidelity

Profiling the Nucleobase and Structure Selectivity of Anticancer Drugs and other DNA Alkylating Agents by RNA Sequencing

Contact Info

Product

Resources

About