Rapamycin stimulates viral protein synthesis and augments the shutoff of host protein synthesis upon picornavirus infection.

The immunosuppressant drug rapamycin blocks progression of the cell cycle at G1 in mammalian cells and yeast. We recently showed that rapamycin inhibits both in vitro and in vivo cap-dependent, but not cap-independent, translation. This inhibition is causally related to reduced phosphorylation and consequent activation of 4E-BP1, a repressor of the function of the cap-binding protein, eIF4E. Two members of the picornavirus family, encephalomyocarditis virus and poliovirus, inhibit phosphorylation of 4E-BP1. Since translation of picornavirus mRNAs is cap independent, inhibition of phosphorylation of 4E-BP1 could contribute to the shutoff of host protein synthesis. Here, we show that rapamycin augments both the shutoff of host protein synthesis and the initial rate of synthesis of viral proteins in cells infected with encephalomyocarditis virus and poliovirus.     

Cytochalasin releases mRNA from the cytoskeletal framework and inhibits protein synthesis.

Cytochalasin D was shown to be a reversible inhibitor of protein synthesis in HeLa cells. The inhibition was detectable at drug levels typically used to perturb cell structure and increased in a dose-dependent manner. The drug also released mRNA from the cytoskeletal framework in direct proportion to the inhibition of protein synthesis. The released mRNA was unaltered in its translatability as measured in vitro but was no longer translated in the cytochalasin-treated HeLa cells. The residual protein synthesis occurred on polyribosomes that were reduced in amount but displayed a normal sedimentation distribution. The results support the hypothesis that mRNA binding to the cytoskeletal framework is necessary although not sufficient for translation. Analysis of the cytoskeletal framework, which binds the polyribosomes, revealed no alterations in composition or amount of protein as a result of treatment with cytochalasin D. Electron microscopy with embedment-free sections shows the framework in great detail. The micrographs revealed the profound reorganization effected by the drug but did not indicate substantial disaggregation of the cytoskeletal elements.     

The interaction between viral protein and host actin facilitates the virus infection to host

Although the virus-host interaction has attracted extensive studies, the host proteins essential for virus infection remain largely unknown. To address this issue, the shrimp Penaeus stylirostris densovirus (PstDNV), belonging to the family Parvoviridae, was characterized. PstDNV, a single-stranded DNA virus with a 3.9-kb genome, encoded only three open reading frames (ORFs). Among the three viral proteins, the PstDNV ORF2-encoded protein was discovered to interact with the shrimp actin, suggesting that the host actin played a very important role in virus infection. The RNAi assays revealed that the ORF2-encoded protein was required for the PstDNV infection. The confocal evidence demonstrated that the interaction between the ORF2-encoded protein and actin was essential for the virus infection. Therefore our study indicated that the manipulation of the host actin cytoskeleton was a necessary strategy for viral pathogens to invade host cells.     

A role for Rev in the association of HIV-1 gag mRNA with cytoskeletal β-actin and viral protein expression

Human immunodeficiency virus type-1 (HIV-1) Rev acts by inducing the specific nucleocytoplasmic transport of a class of incompletely spliced RNAs that encodes the viral structural proteins. The transfection of HeLA cells with a rev-defective HIV-1 expression plasmid, however, resulted in the export of overexpressed, intron-containing species of viral RNAs, possibly through a default process of nuclear retention. Thus, this system enabled us to directly compare Rev⁺ and Rev⁻ cells as to the usage of RRE-containing mRNAs by the cellular translational machinery. Biochemical examination of the transfected cells revealed that although significant levels of gag and env mRNAs were detected in both the presence and absence of Rev, efficient production of viral proteins was strictly dependent on the presence of Rev. A fluoroscence in situ hybridisation assay confirmed these findings and provided further evidence that even in the presence of Rev, not all of the viral mRNA was equally translated. At the early phase of RNA export in Rev⁺ cells, gag mRNA was observed throughout both the cytoplasm and nucleoplasm as uniform fine stippling. In addition, the mRNA formed clusters mainly in the perinuclear region, which were not observed in Rev⁻ cells. In the presence of Rev, expression of the gag protein was limited to these perinuclear sites where the mRNA accumulated. Subsequent staining of the cytoskeletal proteins demonstrated that in Rev⁺ cells gag mRNA is colocalized with β-actin in the sites where the RNA formed clusters. In the absence of Rev, in contrast, the gag mRNA failed to associate with the cytoskeletal proteins. These results suggest that in addition to promoting the emergence of intron-containing RNA from the nucleus, Rev plays an important role in the compartmentation of translation by directing RRE-containing mRNAs to the β-actin to form the perinuclear clusters at which the synthesis of viral structural proteins begins.     

Regulation of protein synthesis by mRNA structure

In addition to the m⁷G cap structure, the length of the 5 UTR and the position and context of the AUG initiator codon (which have been discussed elsewhere in this volume), higher order structures within mRNA represent a critical parameter for translation. The role of RNA structure in translation initiation will be considered primarily, although structural elements have also been found to affect translation elongation and termination. We will first describe the different effects of higher order RNA structuresper se, and then consider specific examples of RNA structural elements which control translation initiation by providing binding sites for regulatory proteins.     

Influence of cytoplasmic heat shock protein 70 on viral infection of Nicotiana benthamiana

The accumulation of heat shock protein 70 (Hsp70) generally occurs in plants infected with viruses. However, the effect of Hsp70 accumulation on plant viral infection and pathogenesis remains elusive. In this study, the expression of six Hsp70 genes was found to be induced by the four diverse RNA viruses, Tobacco mosaic virus, Potato virus X (PVX), Cucumber mosaic virus and Watermelon mosaic virus, in Nicotiana benthamiana. Heat treatment enhanced the accumulation and systemic infection of these viruses. Similar results were obtained for viral infection in plants heterologously expressing an Arabidopsis cytoplasmic Hsp70 through either a PVX vector or Agrobacterium infiltration. In contrast, viral infection was compromised in cytoplasmic NbHsp70c‐1 gene‐silenced plants. These data demonstrate that the cytoplasmic Hsp70s can enhance the infection of N. benthamiana by diverse viruses.     

病毒感染影响宿主细胞代谢研究进展

作为专性的细胞内寄生物,病毒没有独立代谢的能力,因此完全依赖于宿主细胞的代谢机制。病毒利用宿主细胞代谢网络提供的能量和生物合成前体物质来驱动其复制、装配和释放。因此,病毒挟持宿主细胞代谢以实现自身的复制和增殖。此外,病毒还可以通过编码辅助代谢基因(auxiliary metabolic genes,AMGs)调控宿主的细胞代谢,影响碳、氮、磷、硫循环,参与微生物驱动的生物地球化学循环。本文主要从细胞葡萄糖代谢、谷氨酰胺代谢、脂肪酸代谢、病毒AMGs调控宿主代谢影响生物地球化学循环4个方面总结病毒感染对宿主核心代谢途径影响的研究,以期为深入理解病毒-宿主相互作用提供参考,也将为通过代谢干预治疗病毒性疾病提供一定的理论依据。     

Glial shape and cytoskeletal protein synthesis

We investigated whether the shape of astroglial derived cells influences the expression of cytoskeletal proteins. In reaggregating cultures GFAP, vimentin and actin synthesis was approximately 52%, 50% and 37% the level found in monolayer cultures, respectively. Monolayer cultures consisted of polygonal shaped cells adhering to plastic, while reaggregating cultures were comprised of round cells growing in a suspension like culture. Additionally, human glioma cells induced to grow as round cells on poly-2-hydroxyethyl methacrylate (polyhema) coated plastic exhibited a level of GFAP synthesis that was approximately 20% the level displayed by polygonal shaped cells grown on uncoated plastic. Glioma cells initially grown on a polyhema surface and replated onto uncoated plastic were capable of reinitiating GFAP synthesis. Thus, aterations in the synthesis of GFAP and other cytoskeletal proteins can occur when astrocytes change their shape.     

Interaction of protein synthesis initiation factors with the mRNA cap structure.

The mechanism of mRNA recognition by proteins interacting with the mRNA cap structure was investigated by photochemical cross-linking of proteins with 32P-labelled reoviral RNAs. Using ribosomal washes as a source of eukaryotic protein synthesis initiation factors, we identified the well-known cap binding proteins eIF-4B and -4E, but eIF-2 and eIF-3 as well. The interplay of purified eIF-4A, -4B, and -4F was studied in relation to ATP dependence and cap analogue sensitivity of cap binding. Next to their well-known roles in the initiation process, eIF-2 and eIF-3 also cross-linked to the 5' cap. eIF-2 stimulated eIF-4B and -4E cross-linking, an observation that has been previously described more extensively. The interaction of eIF-2 with the 5' end of mRNA was extremely sensitive to K(+)-ions and was resistant to a high concentration of Mg(2+)-ions; this influence of mono- and divalent ions was in contrast with the cross-linking of eIF-4B and -4E. Optimal interaction of these factors was obtained at moderate K+ concentration and low Mg(2+)-ion concentrations. eIF-2 cross-linking was sensitive to high protein to mRNA ratios indicating a weak affinity as compared to eIF-4E and -4B. The interaction of eIF-3 with the cap of mRNA is also weak as it was counteracted by all other cap binding proteins, leading to an inability to detect the cross-linking of this protein in crude eIF preparations. Time kinetics of formation of complexes suggested eIF-2 to be one of the first factors to interact with mRNA. Preformed RNA-protein complexes were dissociated after cap analogue addition, suggesting reversible interactions between RNA and proteins.     

mRNA association with the cytoskeletal framework likely represents a physiological binding event.

A multitude of studies has indicated that the vast majority of mRNA and polyribosomes is associated with the detergent-resistant cytoskeletal framework (CSK). However, the nature and purpose of this association remain unclear. To begin unraveling the factors which may mediate this phenomenon, we examined the extent of association of four mRNAs (tubulin, vimentin, actin, and histone mRNA) with the CSKs of NIH 3T3 cells over a wide range of salt concentrations. Results indicate that the vast majority (greater than 90%) of each of these mRNAs remains associated with the CSK after detergent extraction of cells in low ionic strength buffer (25 mM NaCl). This association is manifest under conditions that cause the complete depolymerization of microtubules but that leave microfilaments and intermediate filaments intact. Even after extensive washing in buffer of approximately physiological ionic strength (150 mM NaCl), 75-85% of these mRNAs still remain associated with the CSK. However, at least 50% of each of these mRNAs can be eluted from the CSK by washing with buffer containing 250 mM NaCl. Not all the mRNAs, though, display the same elution profile. This suggests that different binding sites and/or different binding affinities may exist for different mRNAs. Surprisingly, close to 50% of the polyribosome population remains bound to the CSK despite washing in as much as 1.0 M NaCl. These adherent polyribosomes appear to be of the same size as those that are eluted, allaying the possibility that they are retained by the CSK simply due to size exclusion. Collectively, these data strongly imply that mRNAs are neither weakly adsorbed to the CSK nor physically trapped within the meshwork of cytoskeletal filaments.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of protein synthesis inhibitors on viral mRNA''s synthesized early in adenovirus type 2 infection.

Viral mRNA species synthesized early in adenovirus type 2 infection in the presence of cycloheximide were compared with those synthesized in the absence of drug or in the presence of the DNA synthesis inhibitor 1-beta-D-arabinofuranosylcytosine. Cycloheximide caused approximately a 10-fold stimulation in the accumulation of [3H]uridine into early viral mRNA species. The only exception was a 24s mRNA transcribed from the transforming end of the genome; in the presence of cycloheximide, accumulation of this mRNA species was stimulated no more than 2-fold. Treatment with cycloheximide also resulted in the accumulation of polyadenylated RNAs transcribed from EcoRI-C that are heterogeneous and smaller than the 20S mRNA. Other translation inhibitors were shown to have similar effects, suggesting that inhibition of protein synthesis early after infection induces alterations in the metabolism of specific RNA sequences.     

The involvement of mRNA secondary structure in protein synthesis

Translation initiation in eukaryotes is a complex process involving many factors. A key step in this process is the binding of mRNA to the 43S preinitiation complex. This is generally the rate-limiting step in translation initiation and consequently a major determinant of mRNA translational efficiency. The primary and secondary structure of the mRNA 5' noncoding region have been implicated in modulating translational efficiency. Translational efficiency was shown to be inversely proportional to the degree of secondary structure at the mRNA 5' noncoding region. Furthermore, it was shown that cap-binding proteins that interact with the 5' cap structure (m7GpppN) of eukaryotic mRNAs are involved in the "unwinding" of the mRNA secondary structure, in an ATP hydrolysis mediated event, to facilitate ribosome binding. Thus, cap-binding proteins can potentially regulate mRNA translation. Here, we discuss the available data supporting the notion that eukaryotic 5' mRNA secondary structure plays an important role in translation initiation and the possible regulation of this process.     

Effect of DNA repair protein Rad18 on viral infection

Host factors belonging to the DNA repair machineries are assumed to aid retroviruses in the obligatory step of integration. Here we describe the effect of DNA repair molecule Rad18, a component of the post-replication repair pathway, on viral infection. Contrary to our expectations, cells lacking Rad18 were consistently more permissive to viral transduction as compared to Rad18(+/+) controls. Remarkably, such susceptibility was integration independent, since retroviruses devoid of integration activity also showed enhancement of the initial steps of infection. Moreover, the elevated sensitivity of the Rad18(-/-) cells was also observed with adenovirus. These data indicate that Rad18 suppresses viral infection in a non-specific fashion, probably by targeting incoming DNA. Furthermore, considering data published recently, it appears that the interactions between DNA repair components with incoming viruses, often result in inhibition of the infection rather than cooperation toward its establishment.     

Adenovirus core protein synthesis in the absence of viral DNA synthesis late in infection.

The acid extraction of the adenovirus type 5 core proteins V, VII, and pVII (the precursor to VII) from infected cells and the subsequent electrophoresis on a 15% acrylamide-2.5 M urea-0.9 N acetic acid (pH 2.7) gel, revealed that peptide VII has a similar electrophoretic mobility to that of histone H1. The core proteins, which are coded by late adenovirus mRNA, continued to be synthesized late in infection when viral DNA synthesis was inhibited either by cytosine arabinoside in wild-type infections or by shifting adenovirus H5 ts 125-infected cells to the nonpermissive temperature (40 degree C). Only the initiation, not the continuation, of viral DNA replication was essential for core protein synthesis. The synthesis of viral core proteins continued for over 8 h after the cassation of DNA synthesis. This was in contrast to the rapid shutdown of cellular histone synthesis in the absence of cellular DNA synthesis.     

Effect of parathyroid hormone and forskolin on cytoskeletal protein synthesis in cultured mouse osteoblastic cells

Parathyroid hormone (PTH) has been shown to cause transient cell shape changes in bone cells. We have examined the effects of parathyroid hormone and forskolin on the organization and expression of cytoskeletal proteins in cultured mouse endosteal osteoblastic cells. Analysis of [³⁵S]methionine-labeled cytoskeletal proteins isolated on two-dimensional gel electrophoresis showed that PTH treatment (24 h) stimulated the de novo biosynthesis of actin, vimentin and tubulins in confluent cells, whereas forskolin had a minor effect despite a huge stimulation of cAMP production. This PTH-induced stimulation was associated with cell respreading following a mild and transitory cell retraction. PTH increased the synthesis of monomeric subunits of action and β-tubulins in subconfluent bone cells, whereas both monomeric and polymeric levels of β-tubulins were increased in confluent osteoblasts. Under conditions reducing cell spreading, osteoblastic cells had initially high levels of unpolymerized subunits. In these poorly spread cells, parathyroid hormone or forskolin had no effect on the de novo synthesis of cytoskeletal proteins despite a marked elevation in intracellular cAMP levels. It is concluded that PTH affects the biosynthesis of cytoskeletal proteins in osteoblastic cells and that cAMP production does not seem to be directly involved. In addition, the effect of PTH is modulated by cell spreading and by the initial pool of cytoskeletal subunits.     

Effect of parathyroid hormone and forskolin on cytoskeletal protein synthesis in cultured mouse osteoblastic cells

Parathyroid hormone (PTH) has been shown to cause transient cell shape changes in bone cells. We have examined the effects of parathyroid hormone and forskolin on the organization and expression of cytoskeletal proteins in cultured mouse endosteal osteoblastic cells. Analysis of [35S]methionine-labeled cytoskeletal proteins isolated on two-dimensional gel electrophoresis showed that PTH treatment (24 h) stimulated the de novo biosynthesis of actin, vimentin and tubulins in confluent cells, whereas forskolin had a minor effect despite a huge stimulation of cAMP production. This PTH-induced stimulation was associated with cell respreading following a mild and transitory cell retraction. PTH increased the synthesis of monomeric subunits of actin and beta-tubulins in subconfluent bone cells, whereas both monomeric and polymeric levels of beta-tubulins were increased in confluent osteoblasts. Under conditions reducing cell spreading, osteoblastic cells had initially high levels of unpolymerized subunits. In these poorly spread cells, parathyroid hormone or forskolin had no effect on the de novo synthesis of cytoskeletal proteins despite a marked elevation in intracellular cAMP levels. It is concluded that PTH affects the biosynthesis of cytoskeletal proteins in osteoblastic cells and that cAMP production does not seem to be directly involved. In addition, the effect of PTH is modulated by cell spreading and by the initial pool of cytoskeletal subunits.