Nonsense-mediated mRNA decay of the ferric and cupric reductase mRNAs FRE1 and FRE2 in Saccharomyces cerevisiae.

The nonsense-mediated mRNA decay (NMD) pathway regulates mRNAs that aberrantly terminate translation. This includes aberrant mRNAs and functional natural mRNAs. Natural mRNA degradation by NMD is triggered by mRNA features and environmental cues. Saccharomyces cerevisiae encodes multiple proteins with ferric and cupric reductase activity. Here, we examined the regulation by NMD of two mRNAs, FRE1 and FRE2, encoding ferric and cupric reductases in S. cerevisiae. We found that FRE2 mRNAs are regulated by NMD under noninducing conditions and that the FRE2 3'-UTR contributes to the degradation of the mRNAs by NMD. Conversely, FRE1 mRNAs are not regulated by NMD under comparable conditions. These findings suggest that regulation of functionally related mRNAs by NMD can be differential and conditional.

The nonsense-mediated mRNA decay (NMD) pathway differentially regulates COX17, COX19 and COX23 mRNAs.

The differential regulation of COX17, COX19 and COX23 mRNAs by the nonsense-mediated mRNA decay (NMD) pathway was investigated. The NMD pathway regulates mRNAs that aberrantly terminate translation. This includes mRNAs harboring premature translation termination codons and natural mRNAs. Most natural mRNAs regulated by NMD encode fully functional proteins involved in various cellular processes. However, the cause and targeting of most of these mRNAs by the pathway is not understood. Analysis of a set of mRNAs involved in copper homeostasis showed that a subset of these mRNAs function in mitochondrial copper homeostasis. Here, we examined the regulation of COX17, COX19 and COX23 mRNAs by NMD. These mRNAs encode homologous mitochondrial proteins involved in metallation of cytochrome c oxidase. We found that COX17, COX19 and COX23 mRNAs are differentially regulated by NMD depending on environmental copper levels. A long 3'-UTR contributes to the direct regulation of COX19 mRNA by the pathway. Alternatively, COX23 mRNA contains a long 3'-UTR, but is indirectly regulated by the pathway under two conditions tested here. Analysis of the functionality of the NMD targeting features in COX23 mRNA showed that the COX23 3'-UTR is sufficient to trigger NMD. The regulation of mRNAs involved in mitochondrial copper metabolism by NMD is physiologically significant because excess copper enhances growth of NMD mutants on a non-fermentable carbon source. These findings suggest that regulation of mRNAs encoding homologous proteins by NMD can be differential depending on environmental copper levels. Furthermore, these findings suggest copper ion homeostatic mechanisms in the mitochondria occur at the mRNA level via the NMD pathway.

mRNAs involved in copper homeostasis are regulated by the nonsense-mediated mRNA decay pathway depending on environmental conditions.

The nonsense-mediated mRNA decay pathway (NMD) is an mRNA degradation pathway that degrades mRNAs that prematurely terminate translation. These mRNAs include mRNAs with premature termination codons as well as many natural mRNAs. In Saccharomyces cerevisiae a number of features have been shown to target natural mRNAs to NMD. However, the extent to which natural mRNAs from the same functional group are regulated by NMD and how environmental conditions influence this regulation is not known. Here, we examined mRNAs involved in copper homeostasis and are predicted to be sensitive to NMD. We found that the majority of these mRNAs have long 3'-UTRs that could target them for degradation by NMD. Analysis of one of these mRNAs, COX19, found that the long 3'-UTR contributes to regulation of this mRNA by NMD. Furthermore, we examined an additional mRNA, MAC1 under low copper conditions. We found that low copper growth conditions affect NMD sensitivity of the MAC1 mRNA demonstrating that sensitivity to NMD can be altered by environmental conditions. MAC1 is a copper sensitive transcription factor that regulates genes involved with high affinity copper transport. Our results expand our understanding of how NMD regulates mRNAs from the same functional group and how the environment influences this regulation.

Measurement of mRNA decay rates in Saccharomyces cerevisiae using rpb1-1 strains.

mRNA steady state levels vary depending on environmental conditions. Regulation of the steady state accumulation levels of an mRNA ensures that the correct amount of protein is synthesized for the cell's specific growth conditions. One approach for measuring mRNA decay rates is inhibiting transcription and subsequently monitoring the disappearance of the already present mRNA. The rate of mRNA decay can then be quantified, and an accurate half-life can be determined utilizing several techniques. In S. cerevisiae, protocols that measure mRNA half-lives have been developed and include inhibiting transcription of mRNA using strains that harbor a temperature sensitive allele of RNA polymerase II, rpb1-1. Other techniques for measuring mRNA half-lives include inhibiting transcription with transcriptional inhibitors such as thiolutin or 1,10-phenanthroline, or alternatively, by utilizing mRNAs that are under the control of a regulatable promoter such as the galactose inducible promoter and the TET-off system. Here, we describe measurement of S. cerevisiae mRNA decay rates using the temperature sensitive allele of RNA polymerase II. This technique can be used to measure mRNA decay rates of individual mRNAs or genome-wide.

Regulation of CTR2 mRNA by the nonsense-mediated mRNA decay pathway.

The nonsense-mediated mRNA decay (NMD) pathway was originally identified as a pathway that degrades mRNAs with premature termination codons; however, NMD is now known to regulate natural mRNAs as well. Natural mRNAs are degraded by NMD due to the presence of specific NMD targeting features. An atypically long 3'-UTR is one of the features that has been shown to induce the rapid degradation of mRNAs by NMD in Saccharomyces cerevisiae and other organisms. S. cerevisiae CTR2 mRNAs have long 3'-UTRs and are sensitive to NMD, although the extent by which these long 3'-UTRs target the CTR2 mRNAs to the pathway is unknown. Here, we investigated the sequence elements that induce NMD of the CTR2 mRNAs and determined that the long CTR2 3'-UTR is sufficient to target an NMD-insensitive mRNA to the pathway. We also found that, although the CTR2 3'-UTR contributes to NMD-induced degradation, CTR2 mRNAs contain additional NMD-inducing features that function cooperatively with the atypically long 3'-UTR to trigger mRNA degradation. Lengthening the CTR2 ORF abrogates NMD and renders the mRNAs immune to the NMD pathway. Moreover, we found that transcription of CTR2 driven by the GPD promoter, which is not identical to the CTR2 promoter, affects degradation of the transcripts by NMD.

Regulation of natural mRNAs by the nonsense-mediated mRNA decay pathway.

The nonsense-mediated mRNA decay (NMD) pathway is a specialized mRNA degradation pathway that degrades select mRNAs. This pathway is conserved in all eukaryotes examined so far, and it triggers the degradation of mRNAs that prematurely terminate translation. Originally identified as a pathway that degrades mRNAs with premature termination codons as a result of errors during transcription, splicing, or damage to the mRNA, NMD is now also recognized as a pathway that degrades some natural mRNAs. The degradation of natural mRNAs by NMD has been identified in multiple eukaryotes, including Saccharomyces cerevisiae, Drosophila melanogaster, Arabidopsis thaliana, and humans. S. cerevisiae is used extensively as a model to study natural mRNA regulation by NMD. Inactivation of the NMD pathway in S. cerevisiae affects approximately 10% of the transcriptome. Similar percentages of natural mRNAs in the D. melanogaster and human transcriptomes are also sensitive to the pathway, indicating that NMD is important for the regulation of gene expression in multiple organisms. NMD can either directly or indirectly regulate the decay rate of natural mRNAs. Direct NMD targets possess NMD-inducing features. This minireview focuses on the regulation of natural mRNAs by the NMD pathway, as well as the features demonstrated to target these mRNAs for decay by the pathway in S. cerevisiae. We also compare NMD-targeting features identified in S. cerevisiae with known NMD-targeting features in other eukaryotic organisms.