Upon viral infection of a host cell, each virus starts a program to generate many progeny viruses. Although viruses interact with the host cell in numerous ways, one critical step in the virus life cycle is the expression of viral proteins, which are synthesized by the host ribosomes in conjunction with host translation factors. Here we review different mechanisms viruses have evolved to effectively seize host cell ribosomes, the roles of specific ribosomal proteins and their posttranslational modifications on viral RNA translation, or the cellular response to infection. We further highlight ribosomal proteins with extra‐ribosomal function during viral infection and put the knowledge of ribosomal proteins during viral infection into the larger context of ribosome‐related diseases, known as ribosomopathies.
This article is categorized under:
Translation > Translation Mechanisms
Translation > Translation Regulation
Ribosomal defects perturb stem cell differentiation, causing diseases called ribosomopathies. How ribosome levels control stem cell differentiation is not fully known. Here, we discovered three RNA helicases are required for ribosome biogenesis and for Drosophila oogenesis. Loss of these helicases, which we named Aramis, Athos and Porthos, lead to aberrant stabilization of p53, cell cycle arrest and stalled GSC differentiation. Unexpectedly, Aramis is required for efficient translation of a cohort of mRNAs containing a 5′-Terminal-Oligo-Pyrimidine (TOP)-motif, including mRNAs that encode ribosomal proteins and a conserved p53 inhibitor, Novel Nucleolar protein 1 (Non1). The TOP-motif co-regulates the translation of growth-related mRNAs in mammals. As in mammals, the La-related protein co-regulates the translation of TOP-motif containing RNAs during Drosophila oogenesis. Thus, a previously unappreciated TOP-motif in Drosophila responds to reduced ribosome biogenesis to co-regulate the translation of ribosomal proteins and a p53 repressor, thus coupling ribosome biogenesis to GSC differentiation.
By using ligation-mediated PCR products from mealybug DNA as tester and biotinylated fly DNA as driver, we recovered a fraction of the tester that remains hybridized to driver following high-stringency washing conditions. This fraction is expected to contain mealybug sequences conserved in the fly (MCF). Reciprocal experiments enabled the isolation of fly sequences conserved in the mealybug (FCM). Coding sequences among MCF show amino acid identities >40% with fly proteins, allowing a reliable identification of orthologs. Three sequences from the fly cytogenetic positions 98–99 were hybridized onto mealybug chromosomes and the results identified differences in synteny between the two species. Taken together, our results present a method for direct isolation of sequences conserved between an ‘orphan’ (mealybug) genome and a ‘reference’ (fly) genome and showed that these sequences can be used to study chromosome synteny in the mealybug.
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