Project description:A codon usage consonant with the cellular tRNA pool is important for efficient translation. However, Mimivirus, a giant DNA virus, relies on the host translation system of amoeba yet exhibits a codon usage distinct from its host. How this virus copes with the mismatch between the demand and supply of tRNAs remains unknown. Here, we found that the virus generates a subcellular compartment to translate virus mRNAs efficiently. The combination of genome-wide Ribo-Seq and RNA-Seq reveals that ribosomes traversed along viral mRNAs without pausing, despite the codon usage incompatibility with the host mRNAs. Although the virus encodes tRNA genes in the genome, mim-tRNA-Seq shows that the expression does not impact the composition of the cellular tRNA pool during infection. Instead, we observed that through in situ labeling of newly synthesized proteins, viral protein synthesis locally occurs around the periphery region of the viral factory, likely creating a unique environment to facilitate viral translation. Our data provide a perspective on how local translation shapes viral replication overcoming the mismatch of tRNA supply and codon demand.

Project description:A codon usage consonant with the cellular tRNA pool is important for efficient translation. However, Mimivirus, a giant DNA virus, relies on the host translation system of amoeba yet exhibits a codon usage distinct from its host. How this virus copes with the mismatch between the demand and supply of tRNAs remains unknown. Here, we found that the virus generates a subcellular compartment to translate virus mRNAs efficiently. The combination of genome-wide Ribo-Seq and RNA-Seq reveals that ribosomes traversed along viral mRNAs without pausing, despite the codon usage incompatibility with the host mRNAs. Although the virus encodes tRNA genes in the genome, mim-tRNA-Seq shows that the expression does not impact the composition of the cellular tRNA pool during infection. Instead, we observed that through in situ labeling of newly synthesized proteins, viral protein synthesis locally occurs around the periphery region of the viral factory, likely creating a unique environment to facilitate viral translation. Our data provide a perspective on how local translation shapes viral replication overcoming the mismatch of tRNA supply and codon demand.

Project description:Human viruses rely on host translation resources, including the cellular tRNA pool, because they lack tRNA genes. Using tRNA sequencing, we profiled mature tRNAs during infections with human cytomegalovirus (HCMV) and SARS-CoV-2. HCMV-induced alterations in mature tRNA levels were predominantly virus-driven, with minimal influence from the cellular immune response. Certain post-transcriptional modifications correlated with tRNA stability and were actively manipulated by HCMV. By contrast, SARS-CoV-2 caused minimal changes in mature tRNA levels or modifications. Comparing viral codon usage with proliferation- versus differentiation-associated codon-usage signatures in human genes revealed striking divergence. HCMV genes aligned with differentiation codon usage, whereas SARS-CoV-2 genes matched proliferation codon usage. Structural and gene-expression genes in both viruses showed strong adaptation to host tRNA pools. Finally, a systematic CRISPR screen of human tRNA genes and tRNA-modifying enzymes identified specific tRNAs and enzymes that either enhanced or restricted HCMV infectivity and influenced cellular growth. Together, these data define a dynamic interplay between the host tRNA landscape and viral infection and illuminate mechanisms governing host–virus interactions.

Project description:Human viruses rely on host translation resources, including the cellular tRNA pool, because they lack tRNA genes. Using tRNA sequencing, we profiled mature tRNAs during infections with human cytomegalovirus (HCMV) and SARS-CoV-2. HCMV-induced alterations in mature tRNA levels were predominantly virus-driven, with minimal influence from the cellular immune response. Certain post-transcriptional modifications correlated with tRNA stability and were actively manipulated by HCMV. By contrast, SARS-CoV-2 caused minimal changes in mature tRNA levels or modifications. Comparing viral codon usage with proliferation- versus differentiation-associated codon-usage signatures in human genes revealed striking divergence. HCMV genes aligned with differentiation codon usage, whereas SARS-CoV-2 genes matched proliferation codon usage. Structural and gene-expression genes in both viruses showed strong adaptation to host tRNA pools. Finally, a systematic CRISPR screen of human tRNA genes and tRNA-modifying enzymes identified specific tRNAs and enzymes that either enhanced or restricted HCMV infectivity and influenced cellular growth. Together, these data define a dynamic interplay between the host tRNA landscape and viral infection and illuminate mechanisms governing host–virus interactions.

Project description:Human viruses rely on host translation resources, including the cellular tRNA pool, because they lack tRNA genes. Using tRNA sequencing, we profiled mature tRNAs during infections with human cytomegalovirus (HCMV) and SARS-CoV-2. HCMV-induced alterations in mature tRNA levels were predominantly virus-driven, with minimal influence from the cellular immune response. Certain post-transcriptional modifications correlated with tRNA stability and were actively manipulated by HCMV. By contrast, SARS-CoV-2 caused minimal changes in mature tRNA levels or modifications. Comparing viral codon usage with proliferation- versus differentiation-associated codon-usage signatures in human genes revealed striking divergence. HCMV genes aligned with differentiation codon usage, whereas SARS-CoV-2 genes matched proliferation codon usage. Structural and gene-expression genes in both viruses showed strong adaptation to host tRNA pools. Finally, a systematic CRISPR screen of human tRNA genes and tRNA-modifying enzymes identified specific tRNAs and enzymes that either enhanced or restricted HCMV infectivity and influenced cellular growth. Together, these data define a dynamic interplay between the host tRNA landscape and viral infection and illuminate mechanisms governing host–virus interactions.

Project description:Human viruses rely on host translation resources, including the cellular tRNA pool, because they lack tRNA genes. Using tRNA sequencing, we profiled mature tRNAs during infections with human cytomegalovirus (HCMV) and SARS-CoV-2. HCMV-induced alterations in mature tRNA levels were predominantly virus-driven, with minimal influence from the cellular immune response. Certain post-transcriptional modifications correlated with tRNA stability and were actively manipulated by HCMV. By contrast, SARS-CoV-2 caused minimal changes in mature tRNA levels or modifications. Comparing viral codon usage with proliferation- versus differentiation-associated codon-usage signatures in human genes revealed striking divergence. HCMV genes aligned with differentiation codon usage, whereas SARS-CoV-2 genes matched proliferation codon usage. Structural and gene-expression genes in both viruses showed strong adaptation to host tRNA pools. Finally, a systematic CRISPR screen of human tRNA genes and tRNA-modifying enzymes identified specific tRNAs and enzymes that either enhanced or restricted HCMV infectivity and influenced cellular growth. Together, these data define a dynamic interplay between the host tRNA landscape and viral infection and illuminate mechanisms governing host–virus interactions.

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:Ribosomes are highly abundant cellular machines that perform the essential task of translating the genetic code into proteins. Cellular translation activity is finely tuned and proteostasis insults, such as those incurred upon viral infection, activate stress signaling pathways that result in translation reprogramming. Viral infection selectively shuts down host mRNA while redistributing ribosomes for selective translation of viral mRNAs. The intricacies of this selective ribosome shuffle from host to viral mRNAs are poorly understood. Here, we uncover a role for the ribosome associated quality control (RQC) factor ZNF598, a sensor for collided ribosomes, as a critical factor for vaccinia virus mRNA translation. Collided ribosomes are sensed by ZNF598, which ubiquitylates 40S subunit proteins uS10 and eS10 and thereby initiates RQC-dependent nascent chain degradation and ribosome recycling. We show that vaccinia infection in human cells enhances uS10 ubiquitylation indicating an increased burden on RQC pathways during viral propagation. Consistent with an increased RQC demand, we demonstrate that vaccinia virus replication is impaired in cells which either lack ZNF598 or contain a ubiquitylation deficient version of uS10. Using SILAC-based proteomics and concurrent RNAseq analysis, we determine that host translation of vaccinia virus mRNAs is compromised in cells that lack RQC activity as compared to control cells whereas there was little evidence of differences in host or viral transcription. Additionally, vaccinia virus infection resulted in a loss of cellular RQC activity, suggesting that ribosomes engaged in viral protein production recruit ZNF598 away from its function in host translation. Thus, co-option of ZNF598 by vaccinia virus plays a critical role in translational reprogramming that is needed for optimal viral propagation.

Project description:Viral infection both activates stress signaling pathways and redistributes ribosomes away from host mRNAs to translate viral mRNAs. The intricacies of this ribosome shuffle from host to viral mRNAs are poorly understood Here, we uncover a role for the ribosome associated quality control (RQC) factor, ZNF598, during vaccinia virus mRNA translation. ZNF598 acts on collided ribosomes to ubiquitylate 40S subunit proteins uS10 and eS10 initiating RQC-dependent nascent chain degradation and ribosome recycling We show that vaccinia infection in human cells enhances uS10 ubiquitylation indicating an increased burden on RQC pathways during viral propagation. Consistent with an increased RQC demand, we demonstrate that vaccinia virus replication is impaired in cells which either lack ZNF598 or express a ubiquitylation deficient version of uS10 Using SILAC-based proteomics and concurrent RNAseq analysis, we determine that translation and not transcription of vaccinia virus mRNAs is compromised in cells with deficient RQC activity. Additionally, vaccinia virus infection reduces cellular RQC activity, suggesting that co-option of ZNF598 by vaccinia virus plays a critical role in translational reprogramming that is needed for optimal viral propagation.

Project description:Embryogenesis entails dramatic shifts in mRNA translation and turnover to account for gene expression differences during proliferation and cellular differentiation. Codon identity modulates mRNA stability during early vertebrate embryogenesis, but how the composition of tRNA pools adapts to the embryo s translational demand is unknown. By quantitatively profiling the tRNA repertoires of zebrafish embryos during the maternal-to-zygotic transition, here we find that maternal and zygotic tRNA pools are distinct. We show that translational activation during embryogenesis and tRNA gene derepression are temporally coordinated by TORC1 activity, which increases at gastrulation and inactivates the RNA polymerase III repressor Maf1a/b in vivo. Reshaping of tRNA pools results in differential tRNA anticodon supply, but these changes do not alter decoding rates in zebrafish embryos. Instead, our data indicate that tRNA repertoires reflect the inherent codon bias of the zebrafish mRNA transcriptome, and tRNA levels are boosted at gastrulation to ensure efficient translation as embryos enter differentiation.