Project description:Tremella fuciformis is a popular edible fungus with fruiting bodies that can be produced in large quantities at low costs, while it is easy to transform and cultivate as yeast. This makes it an attractive potential bioreactor. Enhanced heterologous gene expression through codon optimization would be useful, but until now codon usage preferences in T. fuciformis remain unknown. The only available genome of a species in the genus Tremella was that of Tremella mesenterica. To precisely determine the preferred codon usage of T. fuciformis we sequenced the genome of strain Tr26 resulting in a 24.5 Mb draft genome with 10,040 predicted genes. 3288 of the derived predicted proteins matched the UniProtKB/Swiss-Prot databases with 40% or more similarity. Corresponding gene models of this subset were subsequently optimized trough repetitive comparison of alternative start codons and selection of best length matching gene models. For experimental confirmation of gene models, 96 random clones from an existing T. fuciformis cDNA library were sequenced, generating 80 complete CDSs. Calculated optimal codons (RSCU and RFCU values) for the 3288 predicted and the 80 cloned CDSs were highly similar, indicating sufficient accuracy of predicted gene models for codon usage analysis. T. fuciformis showed a strong preference for C and then G (C+G; 66.4 %) at the third base pair position of used codons, while average GC content of predicted genes was slightly higher (58.5 %) than he total genome sequence average (55.9%). Most frequently used codons (optimal codons) all ended in C or G except for one (Ter; AGU), and an increased frequency of C ending codons was observed in genes with higher expression levels. Surprisingly, the preferred codon usage in T. fuciformis strongly differed from T. mesenterica (same genus) and C. neoformans (same family). Instead, optimal codon usage was similar to more distant related species such as Ustilago maydis and Neurospora crassa. Despite much higher overall sequence homology between T. fuciformis and T. mesenterica only 7 out of 21 optimal codons were equal, whereas T. fuciformis shared up to 20 out 21 optimal codons with other species. Clearly, codon usage in Tremella can differ largely and should be estimated for individual species. The precise identification of optimal and high expression related codons is therefore an important step in the development of T. fuciformis as a bioreactor system. Using the Total RNA was extracted from yeast-like cells of T. fuciformis Tr21 in their exponential growth stage, and double-stranded cDNA was synthesized for tag library construction and digital gene expression tag (DGE) sequencing at BGI Tech Solutions Co., Ltd (Shenzhen, China). Image analysis, base calling, extraction of tags, and tag counting were conducted using the Illumina pipeline. Clean tags were mapped to predicted gene models of the draft genome with a mismatch tolerance of 1bp. The number of tags for each CDS was calculated and then normalized to TPM (number of transcripts per million clean tags) digital gene expression (DGE)

Project description:Codon usage bias is a universal feature of eukaryotic and prokaryotic genomes and has been proposed to regulate translation efficiency, accuracy and protein folding based on the assumption that codon usage affects translation dynamics. The role of codon usage in regulating translation, however, is not clear and has been challenged by recent ribosome profiling studies. Here we used a Neurospora cell-free translation system to directly monitor the velocity of mRNA translation. We demonstrated that the use of preferred codons enhances the rate of translation elongation, whereas non-optimal codons slow translation. In addition, codon usage regulates ribosome traffic on the mRNA. These conclusions were supported by ribosome profiling results in vitro and in vivo with substrate mRNAs manipulated to increase signal over background noise. We further show that codon usage plays an important role in regulating protein function by affecting co-translational protein folding. Together, these results resolve a long-standing fundamental question and demonstrate the importance of codon usage on protein folding.

Project description:Usage of synonymous codons represents a characteristic pattern of preference in each organism. It has been inferred that such bias of codon usage has evolved as a result of adaptation for efficient synthesis of proteins. Here we examined synonymous codon usage in genes of the fission yeast Schizosaccharomyces pombe, and compared codon usage bias with expression levels of the gene. In this organism, synonymous codon usage bias was correlated with expression levels of the gene; the bias was most obvious in two-codon amino acids. A similar pattern of the codon usage bias was also observed in Saccharomyces cerevisiae, Arabidopsis thaliana, and Caenorhabditis elegans, but was not obvious in Oryza sativa, Drosophila melanogaster, Takifugu rubripes and Homo sapiens. As codons of the highly expressed genes have greater influence on translational efficiency than codons of genes expressed at lower levels, it is likely that codon usage in the S. pombe genome has been optimized by translational selection through evolution. Relative amounts of mRNA for each ORF were measured by DNA microarray using genomic DNA as a reference, and the copy number of mRNA was calculated using an estimate of the total mRNA number in the cell as 100,000 copies.

Project description:How viruses, such as the emerging mosquito-borne Chikungunya virus (CHIKV), express their genomes at high levels despite an enrichment in suboptimal codons remains a puzzling question. By integrating subcellular fractionation and transcriptome-wide analyses of translation in CHIKV-infected human cells, we demonstrate an unanticipated virus-induced reprogramming of the host translation machinery to favor translation of viral RNA over cellular genes featuring optimal codon usage. This reprogramming was specifically apparent at the endoplasmic reticulum (ER), the preferred translation compartment of CHIKV RNA, and it is mediated by the wobble uridine 34 tRNA modification enzyme KIAA1456 whose expression is enhanced upon viral infection. Since KIAA1456 itself is encoded by a CHIKV-like codon usage, infection triggers a positive feed-back loop that ensures efficient virus protein production. Our findings demonstrate an unprecedented interplay of viruses with the host tRNA epitranscriptome to favor viral protein expression.

Project description:While the “universal” genetic code is now known not to be universal, and stop codons can have multiple meanings, one regularity remains, namely that for a given sense codon there is a unique translation. Examining CUG usage in yeasts that have transferred CUG away from leucine, we here report the first example of dual coding: Ascoidea asiatica stochastically encodes CUG as both serine and leucine. This is deleterious as evidenced by CUG codons being rare, never at conserved serine/leucine residues and predominantly in lowly expressed genes. Related yeasts solve the problem by loss-of-function of one of the two tRNAs. This dual-coding is consistent with the tRNA-loss driven codon reassignment hypothesis and provides a unique example of a proteome that cannot be deterministically predicted.

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:Usage of synonymous codons represents a characteristic pattern of preference in each organism. It has been inferred that such bias of codon usage has evolved as a result of adaptation for efficient synthesis of proteins. Here we examined synonymous codon usage in genes of the fission yeast Schizosaccharomyces pombe, and compared codon usage bias with expression levels of the gene. In this organism, synonymous codon usage bias was correlated with expression levels of the gene; the bias was most obvious in two-codon amino acids. A similar pattern of the codon usage bias was also observed in Saccharomyces cerevisiae, Arabidopsis thaliana, and Caenorhabditis elegans, but was not obvious in Oryza sativa, Drosophila melanogaster, Takifugu rubripes and Homo sapiens. As codons of the highly expressed genes have greater influence on translational efficiency than codons of genes expressed at lower levels, it is likely that codon usage in the S. pombe genome has been optimized by translational selection through evolution.

Project description:Saccahromycopsis schoenii belongs to a genus of yeasts that have the ability to attack and kill other yeast and fungi. De novo genomic sequencing and genome assembly suggests that S. schoenii might belong to the CTG clade. To examine whether it translated CTG codons to leucine (standard codon usage) or serine (alternative codon usage), we analysed its proteome during growth on full media. To see if translation is changed during nutritional stress or during predation on a prey cell (Saccharomyces cerevisiae), we analysed and quantified its proteome during these conditions compared to its proteomic expression in full media.

Project description:MAGE-seq amplicon data from the paper RNA structural determinants of optimal codons revealed by MAGE-seq in Cell Systems 2016 by Kelsic, Chung, Cohen, Park, Wang & Kishony. Data contains read counts for PCR amplicons of the Escherichia coli gene infA: 1) Single codon mutants tiling along the entire gene, with timepoints from growth doublings in rich and minimal medias. 2) Codon pair mutants for positions at the beginning of the gene with timepoints for growth doublings in rich media. 3) Mutations in a hairpin of the 5' UTR for growth in rich media.

Project description:A major determinant of mRNA half-life is the codon-dependent rate of translational elongation. How the processes of translational elongation and mRNA decay communicate is unclear. In this study we establish that the DEAD-box helicase Dhh1p is the sensor of codon optimality (i.e. translational elongation rate) that targets an mRNA for decay. First, we find that mRNAs whose translation elongation rate is slowed by inclusion of non-optimal codons are specifically degraded in a DHH1-dependent manner. Biochemical experiments show that Dhh1p is preferentially associated with mRNAs with suboptimal codon choice. We find that these effects on mRNA decay are sensitive to the number of slow moving ribosomes on an mRNA. Using a tethering system, we establish that non-optimal mRNAs become preferentially saturated with ribosomes when Dhh1p is bound. Moreover, over-expression of Dhh1p leads to the accumulation of ribosomes specifically on mRNAs with low codon optimality in ribosome profiling experiments. Lastly, Dhh1p physically interacts with ribosomes in vivo. Together, these data argue that Dhh1p is a sensor for ribosome speed, targeting an mRNA for repression and subsequent decay.