Kevin J. Sokoloski

The 3′ Untranslated Region of Sindbis Virus Represses Deadenylation of Viral Transcripts in Mosquito and Mammalian Cells

ABSTRACT The positive-sense transcripts of Sindbis virus (SINV) resemble cellular mRNAs in that they possess a 5′ cap and a 3′ poly(A) tail. It is likely, therefore, that SINV RNAs must successfully overcome the cytoplasmic mRNA decay machinery of the cell in order to establish an efficient, productive infection. In this study, we have taken advantage of a temperature-sensitive polymerase to shut off viral transcription, and we demonstrate that SINV RNAs are subject to decay during a viral infection in both C6/36 (Aedes albopictus) and baby hamster kidney cells. Interestingly, in contrast to most cellular mRNAs, the decay of SINV RNAs was not initiated by poly(A) tail shortening in either cell line except when most of the 3′ untranslated region (UTR) was deleted from the virus. This block in deadenylation of viral transcripts was recapitulated in vitro using C6/36 mosquito cell cytoplasmic extracts. Two distinct regions of the 319-base SINV 3′ UTR, the repeat sequence elements and a U-rich domain, were shown to be responsible for mediating the repression of deadenylation of viral mRNAs. Through competition studies performed in parallel with UV cross-linking and functional assays, mosquito cell factors—including a 38-kDa protein—were implicated in the repression of deadenylation mediated by the SINV 3′ UTR. This same 38-kDa protein was also implicated in mediating the repression of deadenylation by the 3′ UTR of another alphavirus, Venezuelan equine encephalitis virus. In summary, these data provide clear evidence that SINV transcripts do indeed interface with the cellular mRNA decay machinery during an infection and that the virus has evolved a way to avoid the major deadenylation-dependent pathway of mRNA decay.

Dephosphorylation of HuR Protein during Alphavirus Infection Is Associated with HuR Relocalization to the Cytoplasm

Background: Sindbis virus RNAs bind the cellular HuR protein and cause its relocalization to the cytoplasm. Results: HuR relocalization occurs with other alphaviruses but not with several unrelated RNA viruses. It is associated with altered protein phosphorylation. Conclusion: HuR relocalization is alphavirus-selective and appears to be distinct from other types of HuR shuttling. Significance: This has potential therapeutic and diagnostic implications for alphavirus infections. We have demonstrated previously that the cellular HuR protein binds U-rich elements in the 3′ untranslated region (UTR) of Sindbis virus RNA and relocalizes from the nucleus to the cytoplasm upon Sindbis virus infection in 293T cells. In this study, we show that two alphaviruses, Ross River virus and Chikungunya virus, lack the conserved high-affinity U-rich HuR binding element in their 3′ UTRs but still maintain the ability to interact with HuR with nanomolar affinities through alternative binding elements. The relocalization of HuR protein occurs during Sindbis infection of multiple mammalian cell types as well as during infections with three other alphaviruses. Interestingly, the relocalization of HuR is not a general cellular reaction to viral infection, as HuR protein remained largely nuclear during infections with dengue and measles virus. Relocalization of HuR in a Sindbis infection required viral gene expression, was independent of the presence of a high-affinity U-rich HuR binding site in the 3′ UTR of the virus, and was associated with an alteration in the phosphorylation state of HuR. Sindbis virus-induced HuR relocalization was mechanistically distinct from the movement of HuR observed during a cellular stress response, as there was no accumulation of caspase-mediated HuR cleavage products. Collectively, these data indicate that virus-induced HuR relocalization to the cytoplasm is specific to alphavirus infections and is associated with distinct posttranslational modifications of this RNA-binding protein.

The preparation and applications of cytoplasmic extracts from mammalian cells for studying aspects of mRNA decay.

HeLa S100 cytoplasmic extracts have been shown to effectively recapitulate many aspects of mRNA decay. Given their flexibility and the variety of applications readily amenable to extracts, the use of such systems to probe questions relating to the field of RNA turnover has steadily increased over time. Cytoplasmic extract systems have contributed greatly to the field of RNA decay by allowing valuable insight into RNA-protein interactions involving both the decay machinery and stability/instability factors. A significant advantage of these systems is the ability to assess the behaviors of several transcripts within an identical static environment, reducing errors within experimental replications. The impact of the cytoplasmic extract/in vitro RNA decay technology may be further advanced through manipulations of the extract conditions or the environment of the cells from which it is made. For instance, an extract may be produced from cells after depletion of a specific factor by RNAi, giving insight into the role of that factor in a particular process. The goals of this chapter are threefold. First, we will familiarize the reader with the process of producing high-quality, reliable HeLa-Cell cytoplasmic extracts. Second, a method for the standardization of independent extracts is described in detail to allow for dependable extract-to-extract comparisons. Finally, the use and application of cytoplasmic extracts with regard to assaying several aspects of mRNA turnover are presented. Collectively these procedures represent an important tool for the mechanistic analysis of RNA decay in mammalian cells.

Virus-mediated mRNA decay by hyperadenylation

Degradation of cellular mRNAs during Kaposis sarcoma-associated herpesvirus infection is associated with hyperadenylation of transcripts and a relocalization of cytoplasmic poly(A)-binding proteins to the nucleus.

Identification of Interactions between Sindbis Virus Capsid Protein and Cytoplasmic vRNA as Novel Virulence Determinants

Alphaviruses are arthropod-borne viruses that represent a significant threat to public health at a global level. While the formation of alphaviral nucleocapsid cores, consisting of cargo nucleic acid and the viral capsid protein, is an essential molecular process of infection, the precise interactions between the two partners are ill-defined. A CLIP-seq approach was used to screen for candidate sites of interaction between the viral Capsid protein and genomic RNA of Sindbis virus (SINV), a model alphavirus. The data presented in this report indicates that the SINV capsid protein binds to specific viral RNA sequences in the cytoplasm of infected cells, but its interaction with genomic RNA in mature extracellular viral particles is largely non-specific in terms of nucleotide sequence. Mutational analyses of the cytoplasmic viral RNA-capsid interaction sites revealed a functional role for capsid binding early in infection. Interaction site mutants exhibited decreased viral growth kinetics; however, this defect was not a function of decreased particle production. Rather mutation of the cytoplasmic capsid-RNA interaction sites negatively affected the functional capacity of the incoming viral genomic RNAs leading to decreased infectivity. Furthermore, cytoplasmic capsid interaction site mutants are attenuated in a murine model of neurotropic alphavirus infection. Collectively, the findings of this study indicate that the identified cytoplasmic interactions of the viral capsid protein and genomic RNA, while not essential for particle formation, are necessary for genomic RNA function early during infection. This previously unappreciated role of capsid protein during the alphaviral replication cycle also constitutes a novel virulence determinant.

Viruses: Overturning RNA Turnover

It is becoming clear that viruses interface with the mRNA decay machinery in a variety of ways during an infection. First, RNA viruses in particular must evade the mRNA decay machinery long enough to replicate and establish infection. Second, many viruses usurp or augment cellular mRNA decay pathways to regulate or selectively express their own genes, often inducing massive decay of the host transcriptome. Finally, temporal progression of a viral infection can depend on regulated decay of specific viral transcripts. Therefore, in order to fully understand viral biology, we must take into account the interactions between viruses and the mRNA decay machinery. This approach gives insights into regulatory mechanisms of cellular mRNA decay, as well as revealing novel ways to influence the outcome of viral infections.

Development of an In Vitro mRNA Decay System in Insect Cells

Cytoplasmic extracts have proven to be a versatile system for assaying the mechanisms and interactions of RNA metabolism. Using Aedes albopictus (C6/36) cells adapted to suspension culture, we have been able to faithfully reproduce and manipulate all aspects of mRNA decay in vitro. Described in this chapter are the processes for both producing an active cytoplasmic extract and the subsequent applications of the extract with respect to mRNA decay. The following protocol for the production of cytoplasmic extracts from C6/36 cells can be altered to encompass a wide variety of cell types, including mammalian cell lines. In addition, a method for designing and implementing an in vitro transcription template to produce specific products are described in detail. Applications of the in vitro transcripts, specifically the deadenylation and exosome assays by which the decay of reporter transcripts is observed, are also examined in detail.

Increasing the Capping Efficiency of the Sindbis Virus nsP1 Protein Negatively Affects Viral Infection

Alphaviruses are arthropod-borne RNA viruses that are capable of causing severe disease and are a significant burden to public health. Alphaviral replication results in the production of both capped and noncapped viral genomic RNAs, which are packaged into virions during the infections of vertebrate and invertebrate cells. However, the roles that the noncapped genomic RNAs (ncgRNAs) play during alphaviral infection have yet to be exhaustively characterized. Here, the importance of the ncgRNAs to alphaviral infection was assessed by using mutants of the nsP1 protein of Sindbis virus (SINV), which altered the synthesis of the ncgRNAs during infection by modulating the protein’s capping efficiency. Specifically, point mutants at residues Y286A and N376A decreased capping efficiency, while a point mutant at D355A increased the capping efficiency of the SINV genomic RNA during genuine viral infection. Viral growth kinetics were significantly reduced for the D355A mutant relative to wild type infection, whereas the Y286A and N376A mutants showed modest decreases in growth kinetics. Overall genomic translation and nonstructural protein accumulation was found to correlate with increases and decreases in capping efficiency. However, genomic, minus strand, and subgenomic viral RNA synthesis was largely unaffected by the modulation of alphaviral capping activity. In addition, translation of the subgenomic vRNA was found to be unimpacted by changes in capping efficiency. The mechanism by which decreased presence of ncgRNAs reduced viral growth kinetics was through the impaired production of viral particles. Collectively, these data illustrate the importance of ncgRNAs to viral infection and suggests that they play in integral role in the production of viral progeny. Importance Alphaviruses have been the cause of both localized outbreaks and large epidemics of severe disease. Currently, there are no strategies or vaccines which are either safe or effective for preventing alphaviral infection or treating alphaviral disease. This deficit of viable therapeutics highlights the need to better understand the mechanisms behind alphaviral infection in order to develop novel antiviral strategies for alphaviral disease. In particular, this study details a previously uncharacterized aspect of the alphaviral life cycle, the importance of noncapped genomic viral RNAs to alphaviral infection. This offers new insights into the mechanisms of alphaviral replication and the impact of the noncapped genomic RNAs on viral packaging.