Project description:Upon initiation at an AUG start codon, the ribosome must maintain the correct reading frame for hundreds of codons in order to produce functional proteins. Although some sequence elements are able to trigger programmed ribosomal frameshifting (PRF), very little is known how the ribosome normally prevents spontaneous frameshift errors. Using high resolution ribosome profiling data sets, we discovered that the translating ribosome uses the 3’ end of 18S rRNA to scan the AUG-like codons after the decoding process. The internal mRNA:rRNA interaction not only contributes to predominant translational pausing, but also provides a post-decoding mechanism to safeguard the ribosome in the correct reading frame. Partially eliminating the AUG-like “sticky” codons in the reporter message leads to increased +1 frameshift errors. Remarkably, mutating the highly conserved CAU triplet of 18S rRNA globally changes codon “stickiness”. Further supporting the role of “sticky” sequences in reading frame maintenance, the codon composition of open reading frames is highly optimized across eukaryotic genomes by minimizing the appearance of AUG-like codons in the frame 2. These results suggest an important layer of information embedded within the protein coding sequences that instructs the ribosome to ensure reading frame fidelity during translation.

Project description:Diphthamide (DPH) is a conserved amino acid modification on eukaryotic translation elongation factor eEF2. We show that loss of DPH increases -1 ribosomal frameshifting at both programmed, including in SARS-CoV-2, and non-programmed sites. Ribosome profiling of yeast and mammalian cells lacking DPH reveals increased ribosomal drop-off during elongation. The drop-off defect on the long yeast MDN1 gene was suppressed by eliminating out-of-frame stop codons. Our data reveal that loss of DPH impairs the fidelity of translocation during translation elongation resulting in increased rates of ribosomal frameshifting and premature termination at out-of-frame stop codons.

Project description:Ribosomal frameshifting refers to the process that ribosomes slip into +1 or -1 reading frame, thus produce chimeric trans-frame proteins. In viruses and bacteria, programmed ribosomal frameshifting can produce essential trans-frame proteins for viral replication or regulation of other biological processes. In humans, however, functional trans-frame protein derived from ribosomal frameshifting is scarcely documented. Combining multiple assays, we show that short codon repeats could act as cis-acting elements that stimulate ribosomal frameshifting in humans, abbreviated as CRFS hereafter. Using proteomic analyses, we identified many putative CRFS events from 32 normal human tissues supported by trans-frame peptides positioned at codon repeats. Finally, we show a CRFS-derived trans-frame protein (HDAC1-FS) functions by antagonizing the activities of HDAC1, thus affecting cell migration and apoptosis. These data suggest a novel type of translational recoding associated with codon repeats, which may expand the coding capacity of mRNA and diversify the regulation in human.

Project description:Ribosomal frameshifting refers to the process that ribosomes slip into +1 or -1 reading frame, thus produce chimeric trans-frame proteins. In viruses and bacteria, programmed ribosomal frameshifting can produce essential trans-frame proteins for viral replication or regulation of other biological processes. In humans, however, functional trans-frame protein derived from ribosomal frameshifting is scarcely documented. Combining multiple assays, we show that short codon repeats could act as cis-acting elements that stimulate ribosomal frameshifting in humans, abbreviated as CRFS hereafter. Using proteomic analyses, we identified many putative CRFS events from 32 normal human tissues supported by trans-frame peptides positioned at codon repeats. Finally, we show a CRFS-derived trans-frame protein (HDAC1-FS) functions by antagonizing the activities of HDAC1, thus affecting cell migration and apoptosis. These data suggest a novel type of translational recoding associated with codon repeats,which may expand the coding capacity of mRNA and diversify the regulation in human.

Project description:Ribosome profiling (Ribo-Seq) and RNA-Seq analysis of mouse neuroblastoma (Neuro2a) cells infected with Japanese Encephalitis Virus (JEV) P20778 Vellore strain. At 18 h post infection (p.i.), infected cells were treated with either cycloheximide (translation elongation inhibitor) or in combination with harringtonine (translation initiation inhibitor). Ribo-Seq libraries were prepared using a broad range of fragment lengths (25 to 70 nucleotides) and deep sequenced. This allowed for estimation of ribosomal frameshifting efficiency and discovery of a novel upstream open reading frame (uORF) in JEV along with perturbations in ribosome-associated tRNA levels upon JEV infection.

Project description:In eukaryotic cells, many mRNAs possess upstream open reading frames (uORFs) in addition to the main coding region. After uORF translation, the ribosome could either recycle at the stop codon or resume scanning for downstream start codons in a process known as reinitiation. Accumulating evidence suggests that some initiation factors, including eIF3, linger on the early elongating ribosome, forming an eIF3-80S complex. Very little is known how the eIF3 is carried along with the 80S during elongation and its implications in subsequent translation reinitiation. Here we report that eIF3a undergoes dynamic O-GlcNAc modification in response to nutrient starvation. Stress-induced de-O-GlcNAcylation promotes eIF3 retention on the elongating ribosome and facilitates reinitiation at downstream start codons. Eliminating the modification site from eIF3a via genome editing induces ATF4 reinitiation under the nutrient rich condition. Our findings illustrate a mechanism in balancing ribosome recycling and reinitiation, thereby linking integrated stress response and translational reprogramming.

Project description:Codon usage bias, which refers to uneven use of synonymous codons, was shown to associate with mRNA stability from yeast to human. However, the underlying molecular basis is largely unknown. With bioinformatic analyses we unexpectedly found that codon usage bias is inversely correlated to density of out-of-frame stop codons (hidden stop codon or HSC). To understand the physiological function of HSCs, we use the frequency gene of Neurospora crassa to examine the role of HSCs in circadian rhythm. We show that deleting HSCs in the upstream of frequency (frq) open reading frame without altering FRQ sequence resulted in loss of circadian rhythm. Further analyses revealed that HSC deletion of frq resulted in elevated stability of frq mRNA, which consequently causes higher FRQ protein level. Combined various methods, we showed that rare codons in the upstream frq region generates significant amount of aberrant translation at +1 frame, possibly via ribosomal frameshifting. Consistently, at genome wide we showed that both in N. crassa and S. cerevisiae, the codon usage bias combined with numbers of HSC are inversely correlated to mRNA stability. Together, these data indicate that HSCs might act as an intrinsic mechanism to terminate aberrant ribosomal frameshifting events triggered by non-optimal codons, thus fine-tune mRNA stability.

Project description:Ribosome profiling provides an opportunity to not only assess how the relative abundance of ribosome association with mRNAs changes in different conditions, but to look more closely at where along mRNAs those ribosomes bind. Here, we used ribosome profiling to calculate the ribosome polarity scores and changes in ribosome footprint read density in both aggregate and gene-specific ways. We profiled a time course of acute glucose starvation followed by glucose readdition and a multi-day growth course through the diauxic shift into stationary phase. We found that ribosome polarity became positive in postdiauxic shift conditions relative to log phase. In acute starvation, polarity shifted positive at our earliest time points but did not continue to do so at later time points. This is consistent with a read density analysis which demonstrated increased density on the 3’ half of genes after glucose starvation. Additionally, we performed ribosome profiling in samples that had glucose added back following acute starvation and observed a wave of new ribosome movement near the start codon and approximately 2,000 nucleotides downstream on open reading frames after one and five minutes of readdition, respectively. Our ribosome profiling analysis suggested that elongation slows during starvation which leads to a buildup of ribosomes on the 3’ halves of mRNAs. Further, it also indicated ribosomes previously built up can resume translation upon glucose readdition. We used reporter assays to corroborate these findings in vivo. Together, these results demonstrate how yeast regulate translation in response to glucose starvation.

Project description:We characterize non-annotated protein alt-RPL36 which is encoded by RPL36 transcript isoform 2 and overlaps with the RPL36 open reading frame. Its function is examined by specific CRISPR deletion of the GTG start codon located 5' to the RPL36 ATG initiation site. Overall changes in transcript expression are evaluated by comparison with wild type HEK293T cells. RPL36 protein expression is not affected by the altRPL36 start codon deletion.

Project description:Proline-rich antimicrobial peptide apidaecin (Api) inhibits bacterial protein synthesis in a distinctive way. In vitro biochemical and structural studies showed that Api binds in the nascent peptide exit tunnel of the ribosome that has completed translation of the gene and has released the newly-synthesized protein. Once in the tunnel, Api traps the release factors on the post-termination ribosome leading to cessation of translation. The mode of Api action in the bacterial cell, however, had remained unknow. By analyzing distribution of ribosomes on mRNAs in Api-treated cells using Ribo-seq approach we uncovered a range of effects that stem from the unique mechanism of Api action. Exposure of bacterial cells to Api results in arrest of translation at stop codons, likely in a post-release state, due to the immediate Api action, as well as in a pre-release state due to the depletion of available release factors. In addition, arrest of translation at the end of the open reading frame (ORF) leads to a pronounced queuing of the translating ribosomes behind the one arrested at the stop codon. One of the major consequences of the Api action is a dramatically increased stop codon bypass by the ribosomes paused in a pre-release state, leading to accumulation of proteins with C-terminal extensions, as confirmed by whole-cell proteomics analysis. Stop codon bypass, that occurs either in 0-frame, by misincorporation of a near-cognate aminoacyl-tRNA at the stop codon, or via frameshifting allows for a fraction of the translating ribosomes to reach the 3’ ends of mRNA transcripts. The pervasive stalling of pre-release ribosomes at the stop codons and at the RNA transcripts ends triggers activation of the cellular ribosome rescue systems which, likely due to Api action as well, remain ineffective. While major Api effects are directed towards the ribosome at the end of the ORFs, cells exposed to Api show a somewhat increased ribosome occupancy of the start codons. Understanding the unique mode of Api to inhibit translation termination in the cell can help envisioning the development of treatments for genetic diseases and research tools for genome exploration.