Inhibition of the intracellular transport of influenza viral RNA by actinomycin D

Efficient, green, and rapid strategy for separating actinomycin D and X2 using supercritical fluid chromatography

Actinomycin D has long been used as a first-line antitumor drug in clinical practice. Actinomycin X₂, a new drug lead, is often isolated along with actinomycin D. The minor differences between the two actinomycin analogs pose a daunting challenge in separation. In this study, supercritical fluid chromatography (SFC) was successfully utilized for the purification of actinomycin X₂ and actinomycin D from a marine derived Streptomyces sp. DQS-5. After one-step SFC purification, the purities of these two compounds were determined to be 97.3 % and 97.8 %, respectively. This method provides a green alternative for the separation of these pharmacologically important actinomycin antibiotics. This study also demonstrated the development of a simple and rapid method for the separation of natural products based on SFC.

Cathepsin B plays a key role in optimal production of the influenza A virus

Background

Influenza A virus (IAV) is the etiologic agent of the febrile respiratory illness, commonly referred to as 'flu'. The lysosomal protease cathepsin B (CTSB) has shown to be involved in the lifecycle of various viruses. Here, we examined the role of CTSB in the IAV lifecycle.

Methods

CTSB-deficient (CTSB^-/-) macrophages and the human lung epithelial cell line A549 cells treated with CA-074Me were infected with the A/Puerto Rico/8/34 strain of IAV (IAV-PR8). Viral entry and propagation were measured through quantitative real-time RT-PCR; production and localization of hemagglutinin (HA) protein in the infected host cells were analysed by Western blots, flow cytometry and confocal microscopy; production of progeny viruses were measured by a hemagglutination assay.

Results

CTSB^-/- macrophages and CA-074Me-treated A549 cells had no defects in incorporating IAV-PR8 virions and permitting viral RNA synthesis. However, these cells produced significantly lower amounts of HA protein and progeny virions than wild-type or untreated cells.

Conclusion

These data indicate that CTSB is involved in the expression of IAV-PR8 HA protein and subsequent optimal production of IAV-PR8 progeny virions. Targeting CTSB can be a novel therapeutic strategy for treating IAV infection.

Progress of small molecular inhibitors in the development of anti-influenza virus agents

The influenza pandemic is a major threat to human health, and highly aggressive strains such as H1N1, H5N1 and H7N9 have emphasized the need for therapeutic strategies to combat these pathogens. Influenza anti-viral agents, especially active small molecular inhibitors play important roles in controlling pandemics while vaccines are developed. Currently, only a few drugs, which function as influenza neuraminidase (NA) inhibitors and M2 ion channel protein inhibitors, are approved in clinical. However, the acquired resistance against current anti-influenza drugs and the emerging mutations of influenza virus itself remain the major challenging unmet medical needs for influenza treatment. It is highly desirable to identify novel anti-influenza agents. This paper reviews the progress of small molecular inhibitors act as antiviral agents, which include hemagglutinin (HA) inhibitors, RNA-dependent RNA polymerase (RdRp) inhibitors, NA inhibitors and M2 ion channel protein inhibitors etc. Moreover, we also summarize new, recently reported potential targets and discuss strategies for the development of new anti-influenza virus drugs.

Nuclear functions of the influenza A and B viruses NS1 proteins: do they play a role in viral mRNA export?

Although it is known for decades that influenza viruses replicate and transcribe their genome in the nucleus of the host cell, there is little knowledge about the cellular and viral factors mediating the nuclear transport of viral mRNA transcripts to the cytoplasm. Efficient export of mature cellular mRNA is coupled to their synthesis by the RNA polymerase II and subsequent processing events such as splicing. This linkage necessitated influenza viruses to evolve a strategy to integrate their unspliced mRNAs generated by the viral polymerase into a cellular mRNA export pathway. Recent findings suggest that the major cellular mRNA export receptor Tap/NXF1 promotes the influenza virus mRNA export. Here, we review functions of the NS1 proteins of influenza A and B viruses and discuss the emerging evidence supporting a role of these viral factors in the export of viral mRNAs.

Evidence that all SC-35 domains contain mRNAs and that transcripts can be structurally constrained within these domains

A fundamental question of mRNA metabolism concerns the spatial organization of the steps involved in generating mature transcripts and their relationship to SC-35 domains, nuclear compartments enriched in mRNA metabolic factors and poly A+ RNA. Because poly A+ RNA in SC-35 domains remains after transcription inhibition, a prevailing view has been that most or all SC-35 domains do not contain protein-encoding mRNAs but stable RNAs with nuclear functions and thus that these compartments do not have direct roles in mRNA synthesis or transport. However, the transcription, splicing, and transport of transcripts from a specific gene have been shown to occur in association with two of these 15-30 nuclear compartments. Here we show that virtually all SC-35 domains can contain specific mRNAs and that these persist in SC-35 domains after treatment with three different transcription-inhibitory drugs. This suggests perturbation of an mRNA transport step that normally occurs in SC-35 domains and is post-transcriptional but still dependent on ongoing transcription. Finally, even after several hours of transcription arrest, these transcripts do not disperse from SC-35 domains, indicating that they are structurally constrained within them. Our findings importantly suggest a spatially direct role for all SC-35 domains in the coupled steps of mRNA metabolism and transport.

Effect of actinomycin D on simian rotavirus (SA11) replication in cell culture

Rotaviruses are the major cause of viral diarrhea in humans and animals. Actinomycin D (Act D) is an antibiotic that intercalates DNA and therefore inhibits DNA-dependent transcription. The current study was carried out to assess the influence of Act D on the replication of simian rotavirus (SA11) in cell culture. Virus-infected MA-104 cell cultures were studied in the presence of Act D at concentrations of 1.25 and 2.5 microg/ml. Treatment of rotavirus-infected cells with 2.5 microg/ml Act D 48 h post-infection reduced the cytoplasmic metachromasia after staining with acridine orange by 25%. Viral RNA labeled with 3H-uridine in the presence of the drug was separated by polyacrylamide gel electrophoresis. Viral RNA replication was not affected by Act D, but increased 3H-uridine uptake was demonstrable by infected cells in the presence of the drug. This possibly was due to the inhibition of cellular RNA synthesis by Act D, which thus enhances incorporation of the radionuclide into the viral RNA. Act D reduced the number of infected cells presenting virus-specific fluorescence 48 h post-infection by more than 50%. These data suggest that Act D may have complexed with viral RNA and prevented newly synthesized mRNA from being translated, but may not have prevented early replication.

The nucleoskeleton: a permanent structure of cell nuclei regardless of their transcriptional activity

Nuclear matrix or nucleoskeleton is thought to provide structural basis for intranuclear order. However, the nature of this structure is still uncertain because of numerous technical difficulties in its visualization. To reveal the "real" morphology of the nucleoskeleton, and to identify possible sources of structural artifacts, three methods of nucleoskeleton preparations were compared. The nucleoskeleton visualized by all these techniques consists of identical elements: nuclear lamina and an inner network comprising core filaments and the "diffuse" nucleoskeleton. We then tested if the nucleoskeleton is a stable structure or a transient transcription-dependent structure. Incubation with transcription inhibitors (alpha-amanitin, actinomycin D, and DRB) for various periods of time had no obvious effect on the morphology of the nucleoskeleton. A typical nucleoskeleton structure was observed also in a physiological model-in transcriptionally inactive mouse 2-cell embryos and in active 8- to 16-cell embryos. Our data suggest that the nucleoskeleton is a permanent structure of the cell nucleus regardless of the nuclear transcriptional state, and the principal architecture of the nucleoskeleton is identical throughout the interphase.

The mechanism of actinomycin D-mediated increase of Borna disease virus (BDV) RNA in cells persistently infected by BDV

The transcriptional mechanism of Borna disease virus (BDV) has been poorly understood. We have analyzed transcription of the virus upon various stimuli in Madin-Darby canine kidney cells which were persistently infected by BDV (MDCK/BDV). Treatment with actinomycin D (ActD) increased the level of BDV RNA, shifting the size of RNA from 1.9 kb to 2.3 kb beginning 5 hr after the treatment. To understand the mechanism of this unique modulation of BDV RNA, we conducted several experiments. The RNA increase occurred at the stage in which synthesis of cellular intrinsic mRNA was intact, suggesting BDV does not compete with cellular transcriptional machinery for intrinsic RNA polymerase II. The BDV transcription was also enhanced by cycloheximide treatment, indicating that newly synthesized viral or cellular proteins are not necessary for viral transcription. However, a shift in the RNA size was not observed for cycloheximide-induced BDV RNA. The increase in viral transcription persisted during the cellular apoptotic process consequent to p53 gene accumulation beginning 1 hr after ActD treatment. Caspase inhibitors Z-VAD and DEVD-CHO repressed the apoptotic process but failed to block the increase in BDV transcription. In addition, adenovirus-mediated transduction of wild-type p53 did not alter the BDV transcription, indicating that the increase in BDV transcription was independent of the p53-mediated apoptotic process. Other various stimuli that evoke cellular signal transductions failed to alter BDV transcription. Agents inhibitory to topoisomerase except adriamycin failed to enhance BDV transcription, indicating that the increase in BDV transcription is not mediated by an inhibitory action to the topoisomerase II of ActD. Adriamycin showed an increase and size-shift of BDV RNA similar to ActD. These results suggest that intercalation of the viral genome itself with ActD is related to the stabilization of viral RNA and alteration of RNA size rather than secondary host cell changes.

Selective inhibition of splicing at the avian sarcoma virus src 3' splice site by direct-repeat posttranscriptional cis elements

The direct-repeat elements (dr1) of avian sarcoma virus (ASV) and leukosis virus have the properties of constitutive transport elements (CTEs), which facilitate cytoplasmic accumulation of unspliced RNA. It is thought that these elements represent binding sites for cellular factors. Previous studies have indicated that in the context of the avian sarcoma virus genome, precise deletion of both ASV dr1 elements results in a very low level of virus replication. This is characterized by a decreased cytoplasmic accumulation of unspliced RNA and a selective increase in spliced src mRNA. Deletion of either the upstream or downstream dr1 results in a delayed-replication phenotype. To determine if the same regions of the dr1 mediate inhibition of src splicing and unspliced RNA transport, point mutations in the upstream and downstream elements were studied. In the context of viral genomes with single dr1 elements, the effects of the mutations on virus replication and increases in src splicing closely paralleled the effects of the mutations on CTE activity. For mutants strongly affecting CTE activity and splicing, unspliced RNA but not spliced RNA turned over in the nucleus more rapidly than wild-type RNA. In the context of wild-type virus containing two dr1 elements, mutations of either element that strongly affect CTE activity caused a marked delay of virus replication and a selective increase in src splicing. However, the turnover of the mutant unspliced RNA as well as the spliced mRNA species did not differ significantly from that of the wild type. These results suggest the dr1 elements in ASV act to selectively inhibit src splicing and that both elements contribute to the fitness of the wild-type virus. However, a single dr1 element is sufficient to stabilize unspliced RNA.

The 5' ends of Thogoto virus (Orthomyxoviridae) mRNAs are homogeneous in both length and sequence

Thogoto (THO) virus is a tick-borne member of the Orthomyxoviridae whose genome consists of six segments of linear, negative sense, single-stranded RNA. To gain insight into the mechanism by which viral mRNA transcripts are initiated, poly(A)+ RNA isolated from THO virus-infected cells was characterized by (i) primer extension experiments, (ii) immunoprecipitation studies with an anticap monoclonal antibody, (iii) direct sequencing analysis of the isolated RNA, and (iv) cloning and sequencing of individual mRNA molecules. The results indicated that THO virus mRNAs are capped and homogeneous in both length and sequence at their 5' end. These findings contrast with the situation found in all other segmented, negative sense or ambisense, single-stranded RNA viruses so far analyzed in which the 5' ends of viral mRNAs are heterogeneous in length and sequence. These results are discussed in terms of the mechanism used by THO virus to initiate mRNA synthesis.

Thogoto and Dhori virus replication is blocked by inhibitors of cellular polymerase II activity but does not cause shutoff of host cell protein synthesis

Tick-transmitted Thogoto and Dhori viruses share structural and genetic properties with the influenza viruses. Here, we compare different steps of their replication cycle in mammalian cells in comparison with influenza A virus. Viral antigens of both viruses accumulated in the nuclei of infected cells, suggesting a nuclear phase of viral replication. Furthermore, as observed with influenza viruses, transcription of Thogoto and Dhori viruses was inhibited by alpha-amanitin and actinomycin D, suggesting a dependence of viral transcription on cellular RNA polymerase II activity. In contrast to influenza viruses, Thogoto and Dhori virus infection did not lead to down-regulation of cellular protein synthesis indicating marked differences regarding the fate of infected cells.