Regulation of mRNA Decay in S. cerevisiae by the Sequence-specific RNA-binding Protein Vts1

Rendl, Laura

23 February 2010

Vts1 is a member of the Smaug protein family, a group of sequence-specific RNA-binding proteins that regulate mRNA translation and degradation by binding to consensus stem-loop structures in target mRNAs. Using RNA reporters that recapitulate Vts1-mediated decay in vivo as well as endogenous mRNA transcripts, I show that Vts1 regulates the degradation of target mRNAs in Saccharomyces cerevisiae. In Chapter Two, I focus on the mechanism of Vts1-mediated mRNA decay. I demonstrate that Vts1 initiates mRNA degradation through deadenylation mediated by the Ccr4-Pop2-Not deadenylase complex. I also show that Vts1 interacts with the Ccr4-Pop2-Not deadenylase complex suggesting that Vts1 recruits the deadenylase machinery to target mRNAs, resulting in transcript decay. Following poly(A) tail removal, Vts1 target transcripts are decapped and subsequently degraded by the 5’-to-3’ exonuclease Xrn1. Taken together these data suggest a mechanism of mRNA degradation that involves recruitment of the Ccr4-Pop2-Not deadenylase to target mRNAs. Previous work in Drosophila melanogaster demonstrated that Smg interacts with the Ccr4-Pop2-Not complex to regulate mRNA stability, suggesting Smaug family members employ a conserved mechanism of mRNA decay. In Drosophila, Smg also regulates mRNA translation through a separate mechanism involving the eIF4E-binding protein Cup. In Chapter Three, I identify the eIF4E-associated protein Eap1 as a component of Vts1-mediated mRNA decay in yeast. Interestingly Cup and Eap1 share no significant homology outside of the seven amino acid eIF4E-binding motif. In eap1 cells mRNAs accumulate as deadenylated capped species, suggesting that Eap1 stimulates mRNA decapping. I demonstrate that the Eap1 eIF4E-binding motif is required for efficient degradation of Vts1 target mRNAs and that this motif enables Eap1 to mediate an interaction between Vts1 and eIF4E. Together these data suggest Vts1 influences multiple steps in the mRNA decay pathway through interactions with the Ccr4-Pop2-Not deadenylase and the decapping activator Eap1.

mRNA decay

0487

Regulation of mRNA Decay in S. cerevisiae by the Sequence-specific RNA-binding Protein Vts1

Rendl, Laura

23 February 2010

Vts1 is a member of the Smaug protein family, a group of sequence-specific RNA-binding proteins that regulate mRNA translation and degradation by binding to consensus stem-loop structures in target mRNAs. Using RNA reporters that recapitulate Vts1-mediated decay in vivo as well as endogenous mRNA transcripts, I show that Vts1 regulates the degradation of target mRNAs in Saccharomyces cerevisiae. In Chapter Two, I focus on the mechanism of Vts1-mediated mRNA decay. I demonstrate that Vts1 initiates mRNA degradation through deadenylation mediated by the Ccr4-Pop2-Not deadenylase complex. I also show that Vts1 interacts with the Ccr4-Pop2-Not deadenylase complex suggesting that Vts1 recruits the deadenylase machinery to target mRNAs, resulting in transcript decay. Following poly(A) tail removal, Vts1 target transcripts are decapped and subsequently degraded by the 5’-to-3’ exonuclease Xrn1. Taken together these data suggest a mechanism of mRNA degradation that involves recruitment of the Ccr4-Pop2-Not deadenylase to target mRNAs. Previous work in Drosophila melanogaster demonstrated that Smg interacts with the Ccr4-Pop2-Not complex to regulate mRNA stability, suggesting Smaug family members employ a conserved mechanism of mRNA decay. In Drosophila, Smg also regulates mRNA translation through a separate mechanism involving the eIF4E-binding protein Cup. In Chapter Three, I identify the eIF4E-associated protein Eap1 as a component of Vts1-mediated mRNA decay in yeast. Interestingly Cup and Eap1 share no significant homology outside of the seven amino acid eIF4E-binding motif. In eap1 cells mRNAs accumulate as deadenylated capped species, suggesting that Eap1 stimulates mRNA decapping. I demonstrate that the Eap1 eIF4E-binding motif is required for efficient degradation of Vts1 target mRNAs and that this motif enables Eap1 to mediate an interaction between Vts1 and eIF4E. Together these data suggest Vts1 influences multiple steps in the mRNA decay pathway through interactions with the Ccr4-Pop2-Not deadenylase and the decapping activator Eap1.

mRNA decay

0487

Analysis of Processing Bodies Assembly and mRNA Decay

YOON, JE-HYUN

January 2011

Translation and mRNA degradation are tightly regulated upon stress where protein synthesis and mRNA decay are modulated to optimize the stress response. However, the mechanisms that regulate mRNA decay and translation during stress are not fully understood. In this thesis, I show that Dcp2, a major decapping enzyme, undergoes phosphorylation by Ste20 kinase during stress and promotes stabilization of ribosomal protein mRNAs as well as Dcp2 accumulation in Processing bodies (P-bodies) in Saccharomyces cerevisiae. In addition, I have analyzed the role of P-bodies by examining how alterations in P-body assembly factors affect the transcriptome. Interestingly, I observe that Edc3, a component of P-bodies that promotes their assembly, can either stabilize or destabilize specific subsets of yeast mRNAs. I also show that Lsm4, a P-body component that mediates the assembly of P-bodies along with Edc3, promotes mRNA decay via its aggregation domain. These results argue that P-bodies can function as sites of mRNA degradation and storage for a subset of mRNAs by the localized accumulation of specific factors.

mRNA decay

P-bodies

phosphorylation

STM1 IS A NOVEL REGULATOR OF MESSENGER RNA TRANSLATION AND DEGRADATION IN SACCHAROMYCES CEREVISIAE

Balagopal, Vidya

January 2010

In eukaryotes, regulation of translation and decay of messenger RNA are critical for fine-tuned control of gene expression. An important point of control is the key transition where mRNAs exit translation and assemble into a non-translating mRNP state that can accumulate in cytoplasmic granules such as P bodies and/or Stress granules. In the budding yeast Saccharomyces cerevisiae , the activators of decapping Dhh1 and Pat1 appear to promote the exit of mRNAs from translation. In my work, summarized below, I describe a new regulator of translation repression and mRNA degradation, Stm1, and its novel mode of action. First, I identified Stm1 as a novel regulator of translation repression and mRNA decay. Stm1 shows several genetic interactions with Pat1 and Dhh1, in a manner consistent with Stm1 promoting the function of Dhh1. This suggests that Stm1 has a role to play in translation repression and/or activation of mRNA decay. stm1 δ strains are defective in the degradation of a subset of mRNAs that include EDC1 and COX17 . These results strongly argue that Stm1 is a novel addition to the mRNA degradation machinery. Second, I have shown that Stm1, a known ribosome-associated protein, can bind and stall 80S ribosomes to repress translation and promote decay. Stm1 is able to repress translation and stall an 80S complex in vitro . Several mutations were identified in the protein, which link the in vitrophenotype to its biological functionin vivo. The analysis of different steps in translation reveals Stm1 functions in a novel manner to inhibit translation after the formation of an 80S complex. Since most of the regulation of translation is thought to happen at the stage of initiation, this study reveals a novel mode of translation regulation. These results also provide a direct and mechanistic link between ribosome function, inhibition of translation and the degradation of messenger RNAs.

Dhh1

mRNA decay

Ribosome

Stm1

Translation

Novel Roles for Ribonucleic Acids in Programmed Cell Death

Thomas, Marshall Peter

01 June 2015

Apoptosis is a tightly coordinated program to shut down and dismantle a cell, characterized by mitochondrial outer membrane permeabilization (MOMP), caspase activation to cleave hundreds of proteins, DNA fragmentation, and blocked translation. Little is known about the fate of RNA as cells die, even though apoptosis has been intensively studied for decades. Here I show that mRNAs, but not noncoding RNAs (ncRNAs), are rapidly and globally degraded during apoptosis. The decay occurs in many cell types responding to diverse apoptotic stimuli. mRNA decay is triggered early in apoptosis, preceding membrane lipid scrambling, genomic DNA fragmentation and modifications to translation initiation factors that might cause translational arrest. mRNA decay depends on MOMP and is amplified by effector caspase activity. 3' truncated mRNA decay intermediates with nontemplated uridylate-rich tails are generated during apoptosis and degraded by the 3' to 5' exonuclease DIS3L2. Knockdown of DIS3L2 reduces apoptotic mRNA decay and partially rescues cell death. I propose that global mRNA decay is a new hallmark of apoptosis caused by the concerted action of several nucleases. I also report a new role for RNA and DNA in directing cytotoxic leukocyte proteases to their substrates. When cytotoxic lymphocytes recognize and attack infected or cancerous cells, they deliver the granzyme (Gzm) serine proteases into the target cell. The Gzms cleave diverse protein substrates to orchestrate cell death. RNA binding proteins are highly enriched in unbiased proteomic screens of Gzm protein substrates. I hypothesized that the Gzms are guided to nucleic acid binding protein targets via direct binding to RNA or DNA. Using fluorescence polarization, I show that the Gzms and related leukocyte proteases bind to RNA and DNA with low nanomolar affinity. Nucleic acid binding by the Gzms facilitates their cleavage of RNA and DNA binding proteins, and guides them into target cell nuclei and onto neutrophil extracellular traps. Nucleic acid binding provides an elegant mechanism to confer protease substrate specificity for cleavage of nucleic acid-binding proteins that play essential roles in cellular gene expression and cell proliferation.

Molecular biology

Cellular biology

apoptosis

mRNA decay

Assembly of mRNP Complexes During Stress and Nonsense-Mediated mRNA Decay Quality Control in Saccharomyces cerevisiae

Swisher, Kylie

January 2011

In eukaryotes, mRNA is in constant flux between an actively translating state and translationally repressed states. Specifically, mRNA degradation and repression factors compete with translation factors to direct mRNAs out of translation for storage or decay. This process often leads to formation of cytoplasmic aggregates. P-bodies are granules that contain mRNA and degradation factors, suggesting they are sites of mRNA decay or storage. Stress granules form in response to stress conditions and contain mRNAs and translation factors.P-bodies and stress granules consist of mRNPs of different compositions, believed to mature and transition between the states. It is proposed that mRNAs transition between the two granules. In the work described below, we use <italic>Saccharomyces cerevisiae</italic> to demonstrate that a decay factor, Dhh1 is capable of existing in both P-body and stress granule mRNPs. This suggests that a decay factor can be part of two different mRNP complexes. Additionally, we identify two novel components of the stress granule mRNPs, Pbp4 and Lsm12, and determine that they are not essential for stress granule formation. Lastly, we show that the stress granule mRNP factor, Pab1, is not absolutely required for stress granule formation.An important aspect of cytoplasmic mRNA regulation is mRNA quality control. One example of this is nonsense-mediated mRNA decay (NMD), whereby aberrant mRNAs containing premature termination codons are targeted for decay, and can be localized to P-bodies. Upf1-3 and the mRNA decapping complex, Dcp2/Dcp1 are essential for NMD, which requires Upf1 interaction with stalled ribosomal/mRNA complexes to target aberrant mRNA for decapping and degradation. How Dcp2/Dcp1 is recruited to aberrant mRNA is poorly understood.Here, we show by yeast two-hybrid assays that an interaction between Dcp2 and Upf1 is mediated by the decapping stimulator Edc3. Interestingly, Edc3 and Upf2 share overlapping binding sites on the Upf1 N-terminal domain. The decapping stimulator, Pat1, also interacts on the Upf1 N-terminus, but Edc3 and Pat1 are not essential for NMD. Surprisingly, the Upf1-Edc3 interaction does not promote or negatively regulate NMD. Thus, the Upf1-Edc3 and Upf1-Pat1 interactions likely regulate a subset of mRNA transcripts, or are essential for proper NMD under different environmental conditions.

mRNA decay

mRNA regulation

NMD

Saccharomyces cerevisiae

stress granules

The Functional Relationship between the Nonsense-Mediated mRNA Decay Pathway and the Prematurely Terminating Ribosome

Serdar, Lucas D.

23 May 2019

No description available.

Molecular Biology

Regulation of Mammalian Messenger RNA Stability via the Open Reading Frame

Forrest, Megan E.

29 May 2020

No description available.

Genetics

Molecular Biology

mRNA decay

gene expression

translation

genetic code

Decay of Beta-Globin mRNA in Erythroid Cells

Dougherty, Julie Ann

02 September 2014

No description available.

Molecular Biology

Biochemistry

REGULATION OF DROSOPHILA mRNA STABILITY BY DEADENYLATION ELEMENTS AND miRNAs

Trinh, Tat To

04 September 2015

No description available.

Biochemistry