Translation of Globin Messenger RNA in a Heterologous Cell-free System

MESSENGER-SPECIFIC initiation factors, capable of discriminating between classes of messenger RNAs (mRNAs) or different cistrons in viral RNA, have been implicated in the regulation of protein synthesis in bacteria^1–5. Comparable but less detailed observations have also been made in eukaryotic systems^6–10. For example, RNA extracted from a mammalian virus (encephalomyocarditis virus, EMC) cannot be translated in a reticulocyte cell-free system unless the system is fortified with an extract from responsive cells—in this case, Krebs II ascites cells⁶. Such results imply the existence of tissue-specific factors and lead to questions whether this incompatibility is reciprocated by an inability of the Krebs II ascites cell system to respond to the mRNA for globin.     

Genomic RNA of mengovirus V. Recognition of common features by ribosomes and eucaryotic initiation factor 2.

Binding of ribosomes to the 32P-labeled genomic RNA of mengovirus was studied in lysates of mouse L929 and Krebs ascites cells under conditions for initiation of translation. Upon total digestion with RNase T1, the 32P-labeled RNA protected in either 40S or 80S initiation complexes yielded four unique, large oligonucleotides. Each of these oligonucleotides occurred once in the viral RNA molecule. The same four oligonucleotides were recovered from 80S initiation complexes formed in lysates in which unlabeled mengovirus RNA had been translated extensively, indicating that recognition by ribosomes was not modulated detectably by a viral translation product. The recognition of intact, 32P-labeled mengovirus RNA by eucaryotic initiation factor 2 (eIF-2) was examined by direct complex formation. Fingerprint analysis of the RNA protected by eIF-2 against RNase T1 digestion yielded three T1 oligonucleotides that were identical to three of the four oligonucleotides protected in either 40S or 80S initiation complexes. A physical map of the large T1 oligonucleotides of the mengovirus RNA molecule was constructed, and the four protected oligonucleotides were found to map internally, within the region between the polycytidylate tract and the 3' end. For either ribosomes or eIF-2, the protected oligonucleotides could not be arranged in a continuous sequence, suggesting that they constitute at least two widely separated domains. These results show that ribosomes recognize and blind to more than a single sequence in mengovirus RNA, located internally in regions that are far removed from the 5' end of the molecule. eIF-2 itself binds with high specificity to mengovirus RNA, recognizing apparently three of the four sequences recognized by ribosomes.     

Host-Dependent Restriction of Mengovirus Replication

Mengovirus infection of a restrictive cell line, Maden's bovine kidney (MDBK), results in a virus yield 1,000-fold less than that obtained from productively infected cell lines such as L cells or Ehrlich ascites tumor cells (EAT). Cells of both types of host systems are infected with comparable efficiencies and are completely killed as a consequence of infection. Infective center assays, coupled with the observation of total cell killing, suggest that comparable numbers of cells synthesize viral antigen and release virus in both types of host system. Viral-specific ribonucleic acid (RNA) synthesis is initiated and proceeds in an identical fashion for approximately 4 hr after the infection of MDBK, EAT, or L-cells. At this time, viral RNA synthesis in MDBK ceases, whereas viral RNA synthesis in EAT and L-cells continues at a linear rate. These results indicate that none of the early viral events leading to the initiation of viral-specific RNA synthesis constitutes the primary site of mengovirus restriction in MDBK. Rather it appears that the cessation of viral RNA synthesis in restrictive cells constitutes the primary limiting event. Based on its delayed interaction with mengovirus RNA synthesis, it appears that the host-related restrictive agent is initially compartmentalized and then released as a consequence of infection subsequent to those early events in mengovirus infection leading to the initiation and continued synthesis of viral RNA.     

Stability and function of mengovirus RNA in cell-free protein synthesis

Cell-free protein synthesis utilizing mengovirus RNA as message occurs on large (200S) polyribosomes similar in size to polyribosomes formed by viral message in intact Ehrlich ascites tumor (EAT) cells. However, most viral RNA in the cell-free system is not associated with rapidly sedimenting structure, but rather sediments in a 40S peak.As measured by function, viral RNA is remarkably stable to incubation in the cell lysate. Message function is preserved for over 30 min under conditions where synthesis is reversibly blocked by lack of ATP and GTP. However, 40% of added radioactively-labeled viral RNA is rapidly adsorbed onto the incubation vessel. These results indicate that viral RNA as isolated may seem homogenous by sedimentation, yet be functionally heterogenous, as measured by stability and by involvement in protein synthesis.     

Thiouracil Cross-Linking Mass Spectrometry: a Cell-Based Method To Identify Host Factors Involved in Viral Amplification

Eukaryotic RNA viruses are known to utilize host factors; however, the identity of these factors and their role in the virus life cycle remain largely undefined. Here, we report a method to identify proteins bound to the viral RNA during amplification in cell culture: thiouracil cross-linking mass spectrometry (TUX-MS). TUX-MS relies on incorporation of a zero-distance cross-linker into the viral RNA during infection. Proteins bound to viral RNA are cross-linked prior to cell lysis, purified, and identified using mass spectrometry. Using the TUX-MS method, an unbiased screen for poliovirus (PV) host factors was conducted. All host and viral proteins that are known to interact with the poliovirus RNA were identified. In addition, TUX-MS identified an additional 66 host proteins that have not been previously described in poliovirus amplification. From these candidates, eight were selected and validated. Furthermore, we demonstrate that small interfering RNA (siRNA)-mediated knockdown of two of these uncharacterized host factors results in either a decrease in copy number of positive-stranded RNA or a decrease in PV translation. These data demonstrate that TUX-MS is a robust, unbiased method to identify previously unknown host cell factors that influence virus growth. This method is broadly applicable to a range of RNA viruses, such as flaviviruses, alphaviruses, picornaviruses, bunyaviruses, and coronaviruses.     

Effect of polyadenylic acid on the functional half-life of encephalomyocarditis virus RNA during translation.

The translation of poly(A)-rich and poly(A)-poor populations of Encephalomyocarditis viral RNA was studied in Ehrlich ascites cell-free extracts. The poly(A)-rich viral RNA was translated 2–3 times more efficiently than the poly(A)-poor RNA. Both viral RNA populations were found to be similar with respect to susceptibility to nuclease attack as well as their ability to initiate and carry out protein synthesis early in the translation reaction. Later in the reaction, however, translation of the poly(A)-poor RNA was markedly reduced whereas translation of the poly(A)-rich RNA continued. These results are consistent with the hypothesis that poly(A) plays a role in the re-utilization and longevity of mRNA.     

Encephalomyocarditis virus RNA. II. Polyadenylic acid requirement for efficient translation.

Differentially polyadenylated subpopulatons of encephalomyocarditis (EMC) viral RNA were isolated by affinity chromatography on oligodeoxythymidylic acid-cellulose. Translation of these RNA fractions in several in vitro protein-synthesizing systems, isolated from Ehrlich ascites tumor cells, demonstrated that poly(A)+EMC viral RNA was translated two to three times more efficiently than poly(A)-EMC viral RNA. Sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis of the polypetides synthesized by the in vitro system in response to the different RNAs showed no detectable differences in the size or relative amount- of the translational products. mRNA saturation curves indicated that the in vitro systems were stimulated maximally by equivalent amounts of RNA, wheter it be poly(A)-or poly(A)+ EMC viral RNA. Time course experiments showed that the differences in translatability were more pronounced late in the reaction when reinitiation was required, and that by eliminating reinitiation with high salt the apparent effect of poly(A) on translation was diminished. Together, these results suggest that poly(A) may be required for efficient initiation and reinitiation of protein synthesis in the cell-free systems. This interpretation is discussed relative to earlier data.     

Plant virus transport: motions of functional equivalence

Plant virus cell-to-cell movement and subsequent systemic transport are governed by a series of mechanisms involving various virus and plant factors. Specialized virus encoded movement proteins (MPs) control the cell-to-cell transport of viral nucleoprotein complexes through plasmodesmata. MPs of different viruses have diverse properties and each interacts with specific host factors that also have a range of functions. Most viruses are then transported via the phloem as either nucleoprotein complexes or virions, with contributions from host and virus proteins. Some virus proteins contribute to the establishment and maintenance of systemic infection by inhibiting RNA silencing-mediated degradation of viral RNA. In spite of all the different movement strategies and the viral and host components, there are possible functional commonalities in virus-host interactions that govern viral spread through plants.     

Cellular protein synthesis shutoff by mengovirus: translation of nonviral and viral mRNA''s in extracts from uninfected and infected Ehrlich ascites tumor cells.

The mechanism whereby picornaviruses inhibit host protein synthesis while their own synthetic processes proceed unabated has remained elusive. One of our approaches to this problem was to study the ability of cell-free extracts derived from uninfected and mengovirus-infected Ehrlich ascites tumor cells to translate viral and nonviral mRNA's under various conditions of incubation. Our results indicate that viral messengers (from mengovirus and encephalomyocarditis virus) and cellular messengers [L cell and Ehrlich ascites tumor poly(A)-containing mRNA's, rabbit globin mRNA, and chicken embryo lens crystallin mRNA] are translated equally well in both extracts. We also examined the simultaneous translation of viral and nonviral mRNA's in extracts from uninfected Ehrlich ascites tumor cells. Our results indicate that under certain conditions mengovirus RNA can suppress completely the translation of globin mRNA. The significance of these results in terms of the shutoff of host protein synthesis is discussed.     

Selective translation of mengovirus RNA over Host mRNA in homologous, fractionated, cell-free translational systems from Ehrlich-ascites-tumor cells.

The selective translation of viral RNA in mengovirus-infected Ehrlich ascites tumor cells was investigated using fractionated translational systems whose macromolecular components were derived entirely from uninfected or virus-infected cells. Both systems translate host mRNA from uninfected cells, host mRNA from virus-infected cells, and mengovirus RNA. In competition experiments, where viral RNA and host mRNA were translated together in systems from uninfected cells, the relative amounts of virus-specific and host-specific proteins synthesized were proportional to the relative concentrations of the RNA templates. In systems whose components were obtained from virus-infected cells, mengovirus RNA was preferentially translated. 70% of the selectivity found in the translational systems derived from infected cells was due to the initiation factor fraction, the remaining 30% to components of the pH 5 enzyme fraction. In addition, host mRNA isolated after virus infection is translated in vitro to a lower extent in the presence of mengovirus RNA than is host mRNA from uninfected cells.     

Functional characterization of cleavage-defective mutants of encephalomyocarditis virus.

We characterized seven temperature-sensitive capsid cleavage (cleavage-defective) mutants of encephalomyocarditis virus. Our experimental approach was to monitor in vitro proteolysis reactions of either wild-type or cleavage-defective mutant capsid precursors mixed with cell-free translation products (containing the viral protease) of either wild-type or mutant viral RNA. The cell-free translation reactions and in vitro proteolysis reactions were done at 38 degrees C, because at this temperature cleavage of the capsid precursors was restricted in reactions containing cleavage-defective mutant viral RNA as the message, relative to those reactions containing wild-type viral RNA as the message. Wild-type or cleavage-defective mutant capsid precursors were prepared by adding cycloheximide to cell-free translation reactions primed with wild-type or mutant viral RNA, respectively, 12 min after the initiation of translation. In vitro proteolysis of wild-type capsid precursors with cell-free translation products of either wild-type or cleavage-defective mutant viral RNA led to similar products at 38 degrees C, indicating that the cleavage-defective mutant viral protease was not temperature sensitive. As a corollary to this, at 38 degrees C cleavage-defective mutant capsid precursors were not cleaved as completely as were wild-type capsid precursors by products of cell-free translation of wild-type viral RNA. The results from these in vitro proteolysis experiments indicate that all seven of the cleavage-defective mutants have capsid precursors with a temperature-sensitive configuration.     

Differential effects on RNA translation by a KC1 extract of reticulocyte ribosomes: characteristics of an inhibitory fraction

A KCl extract of rabbit reticulocyte ribosomes has been demonstrated to markedly stimulate the translation of various messenger RNAs in a cell-free system from Krebs II ascites tumor cells. In contrast, the translation of encephalomyocarditis viral RNA is strongly inhibited by the same extract. Fractionation of the KCl extract allows the separation of these inhibitory and stimulatory activities. The inhibitory activity has been shown to be the consequence of an unusual endonuclease, associated with ribosomes, that produces approximately 4 S products from the degradation of globin mRNA and viral RNA.     

Strand-specific RNA synthesis defects in a poliovirus with a mutation in protein 3A

Substitution of a methionine residue at position 79 in poliovirus protein 3A with valine or threonine caused defective viral RNA synthesis, manifested as delayed onset and reduced yield of viral RNA, in HeLa cells transfected with a luciferase-containing replicon. Viruses containing these same mutations produced small or minute plaques that generated revertants upon further passage, with either wild-type 3A sequences or additional nearby compensating mutations. Translation and polyprotein processing were not affected by the mutations, and 3AB proteins containing the altered amino acids at position 79 showed no detectable loss of membrane-binding activity. Analysis of individual steps of viral RNA synthesis in HeLa cell extracts that support translation and replication of viral RNA showed that VPg uridylylation and negative-strand RNA synthesis occurred normally from mutant viral RNA; however, positive-strand RNA synthesis was specifically reduced. The data suggest that a function of viral protein 3A is required for positive-strand RNA synthesis but not for production of negative strands.