Project description:Viruses package host RNAs in their virions which are associated with a range of functions in the viral life cycle. Previous transcriptomic profiling on host RNA packaging were mostly focused on retroviruses. Which host RNAs are packaged in other viruses at the transcriptome level has not been thoroughly examined. Here we apply both small RNA and large RNA sequencing of SARS-CoV-2 virions from six individual isolates in Vero cell cultures to profile packaging of host RNAs in a coronavirus and to explore SARS-CoV-2 genomic RNA modifications. We find selective packaging of specific tRNAs, tRNA fragments and signal recognition particle RNA into SARS-CoV-2 virions. Virions from all individual clones package the same set of host RNAs, suggesting a common mechanism of selective packaging. We estimate that a SARS-CoV-2 virion contains up to 1 SRP RNA and 4 tRNA molecules. We identify tRNA modification differences between the virion-packaged tRNAs and those in the uninfected host cells. Furthermore, we find subgenomic viral RNAs in the virions, and uncharacterized candidate modifications in the SARS-CoV-2 genomic RNA. Our results reveal an under-explored aspect of viral-host interaction that may be explored for viral therapeutics.

Project description:To associate the amount of tRNAs with codon usage, we perform hydro-tRNA sequencing (Gogakos et al. 2017) and quantify tRNA expression in HEK293 and HeLa cells.

Project description:ϕXacN1 is a novel jumbo myovirus infecting the causative agent of Asian citrus canker, Xanthomonas citri. Its linear 384,670 bp double-stranded DNA genome encodes 592 predicted protein coding genes and shows 65,875 bp direct terminal repeats (DTRs), so far the longest DTRs among sequence phage genomes. The DTRs harbor 56 tRNA genes, corresponding to all 20 amino acids. This is the highest number of tRNA genes reported in a phage genome. Codon usage analyses revealed a propensity that the phage encoded tRNAs target codons that are highly used by the phage but less frequently by its host. The existence of these tRNA genes, additional seven translation-related genes as well as a chaperonin gene found in the ϕXacN1 genome suggests an increased level of independence of phage replication on host molecular machinery and a wide host range. Consistently, ϕXacN1 showed a wider host range than other X. citri phages in an infection test against a panel of X. citri strains. Phylogenetic analyses revealed a clade of phages composed of ϕXacN1 and ten other jumbo phages showing an evolutionary stability in their large genome sizes.

Project description:Although messenger RNA (mRNA) vaccines have been employed to prevent the spread of COVID-19, they are critically limited by instability and low translation capacity. Alterations in tRNA abundance and modification, associated with codon optimality, impact mRNA stability and protein output in a codon-dependent manner, implying tRNA as a potential translation enhancer. Here, we report a strategy named tRNA-plus to augment translation based on artificially modulating the tRNA availability. We demonstrated that overexpression of specific tRNAs enhanced the stability and translation efficiency of SARS-CoV-2 Spike mRNA, resulting in substantial improvements in protein levels by up to 4.7-fold. In addition, chemically synthesized tRNAs bearing multiple site-specific modifications, particularly at the anticodon loop and TΨC-loop, exhibited an average of ~4-fold higher decoding efficacy than unmodified tRNA, along with increased stability and reduced immune toxicity. We further leveraged an optimized lipid nanoparticles (LNP) system for codelivery of Spike mRNA vaccine and tRNA, which elicited enhanced spike-specific humoral and cellular immune responses in vivo. The methods presented here may become a general approach for elevating mRNA translation potency, which can be applied to various translation-based fields.

Project description:Although messenger RNA (mRNA) vaccines have been employed to prevent the spread of COVID-19, they are critically limited by instability and low translation capacity. Alterations in tRNA abundance and modification, associated with codon optimality, impact mRNA stability and protein output in a codon-dependent manner, implying tRNA as a potential translation enhancer. Here, we report a strategy named tRNA-plus to augment translation based on artificially modulating the tRNA availability. We demonstrated that overexpression of specific tRNAs enhanced the stability and translation efficiency of SARS-CoV-2 Spike mRNA, resulting in substantial improvements in protein levels by up to 4.7-fold. In addition, chemically synthesized tRNAs bearing multiple site-specific modifications, particularly at the anticodon loop and TΨC-loop, exhibited an average of ~4-fold higher decoding efficacy than unmodified tRNA, along with increased stability and reduced immune toxicity. We further leveraged an optimized lipid nanoparticles (LNP) system for codelivery of Spike mRNA vaccine and tRNA, which elicited enhanced spike-specific humoral and cellular immune responses in vivo. The methods presented here may become a general approach for elevating mRNA translation potency, which can be applied to various translation-based fields.

Project description:Although messenger RNA (mRNA) vaccines have been employed to prevent the spread of COVID-19, they are critically limited by instability and low translation capacity. Alterations in tRNA abundance and modification, associated with codon optimality, impact mRNA stability and protein output in a codon-dependent manner, implying tRNA as a potential translation enhancer. Here, we report a strategy named tRNA-plus to augment translation based on artificially modulating the tRNA availability. We demonstrated that overexpression of specific tRNAs enhanced the stability and translation efficiency of SARS-CoV-2 Spike mRNA, resulting in substantial improvements in protein levels by up to 4.7-fold. In addition, chemically synthesized tRNAs bearing multiple site-specific modifications, particularly at the anticodon loop and TΨC-loop, exhibited an average of ~4-fold higher decoding efficacy than unmodified tRNA, along with increased stability and reduced immune toxicity. We further leveraged an optimized lipid nanoparticles (LNP) system for codelivery of Spike mRNA vaccine and tRNA, which elicited enhanced spike-specific humoral and cellular immune responses in vivo. The methods presented here may become a general approach for elevating mRNA translation potency, which can be applied to various translation-based fields.

Project description:Protein translation depends on mRNA-specific initiation, elongation, and termination rates. While the regulation of ribosome elongation is well studied in bacteria and yeast, less is known in higher eukaryotes. Here, we combined ribosome and tRNA profiling to investigate the relations between ribosome elongation rates, (aminoacyl-) tRNA levels and codon usage in mammals. We modeled codon-specific ribosome dwell times and translation fluxes from ribosome profiling, considering pair-interactions between ribosome sites. In mouse liver, the model revealed site and codon specific dwell times, as well as codon pair-interactions clustering by amino acids. While translation fluxes varied significantly across diurnal time and feeding regimen, codon dwell times were highly stable, and conserved in human. Fasting had no effect on codon dwell times in mouse liver. Profiling of total and aminoacylated tRNAs revealed highly heterogeneous levels with specific isoacceptor patterns and a correlation with codon usage. tRNAs for isoleucine, asparagine, aspartate and arginine were lowly loaded and conserved in fasted mice. Finally, codons with low levels of charged tRNAs and high codon usage relative to tRNA abundance exhibited long dwell times. Together, these analyses pave the way towards understanding the complex relation between tRNA loading, codon usage and ribosome dwell times in mammals.

Project description:Protein translation depends on mRNA-specific initiation, elongation, and termination rates. While the regulation of ribosome elongation is well studied in bacteria and yeast, less is known in higher eukaryotes. Here, we combined ribosome and tRNA profiling to investigate the relations between ribosome elongation rates, (aminoacyl-) tRNA levels and codon usage in mammals. We modeled codon-specific ribosome dwell times and translation fluxes from ribosome profiling, considering pair-interactions between ribosome sites. In mouse liver, the model revealed site and codon specific dwell times, as well as codon pair-interactions clustering by amino acids. While translation fluxes varied significantly across diurnal time and feeding regimen, codon dwell times were highly stable, and conserved in human. Fasting had no effect on codon dwell times in mouse liver. Profiling of total and aminoacylated tRNAs revealed highly heterogeneous levels with specific isoacceptor patterns and a correlation with codon usage. tRNAs for isoleucine, asparagine, aspartate and arginine were lowly loaded and conserved in fasted mice. Finally, codons with low levels of charged tRNAs and high codon usage relative to tRNA abundance exhibited long dwell times. Together, these analyses pave the way towards understanding the complex relation between tRNA loading, codon usage and ribosome dwell times in mammals.

Project description:Respiratory viruses such as SARS-CoV-2 are pathogens that can reach pandemic proportions. The early human response to respiratory viruses are in the nasal cavity and nasopharyngeal regions. Defining biomarkers of disease trajectory at the time of a positive test is important for opting for treatment and monitoring decisions. We hypothesize that the nasopharyngeal tRNA profiles can be used to predict symptom severity resulting from SARS-CoV-2 infection. We carried out multiplex small RNA sequencing (MSR-seq) on nasopharyngeal swaps to measure the human tRNA response to SARS-CoV-2 infection. Our result simultaneously measured full-length tRNA abundance, tRNA modifications, and tRNA fragmentation among individuals that went on to develop no/mild or severe symptoms. We identified distinct tRNA signatures that can predict the clinical outcome of SARS-CoV-2 infected individual at the time of a positive test. These results highlight the utility of using host tRNA properties as biomarkers for clinical applications.

Project description:The severe acute respiratory syndrome (SARS) epidemic was characterized by increased pathogenicity in the elderly due to an early exacerbated innate host response. SARS-CoV is a zoonotic pathogen that entered the human population through an intermediate host like the palm civet. To prevent future introductions of zoonotic SARS-CoV strains and subsequent transmission into the human population, heterologous disease models are needed to test the efficacy of vaccines and therapeutics against both late human and zoonotic isolates. Here we show that both human and zoonotic SARS-CoV strains can infect cynomolgus macaques and resulted in radiological as well as histopathological changes similar to those seen in mild human cases. Viral replication was higher in animals infected with a late human phase isolate compared to a zoonotic isolate. Host responses to the three SARS-CoV strains were similar and only apparent early during infection with the majority of genes associated with interferon signalling pathways.This study characterizes critical disease models in the evaluation and licensure of therapeutic strategies against SARS-CoV for human use 4 strains, time course, lungs