We describe a method for generating and amplifying genetically modified respiratory syncytial viruses (RSVs) and an optimized plaque assay for RSVs. We illustrate this protocol by creating two recombinant viruses that respectively allow quantification of RSV replication and live analysis of RSV inclusion bodies and inclusion bodies-associated granules dynamics.
The use of recombinant viruses has become crucial in basic or applied virology. Reverse genetics has been proven to be an extremely powerful technology, both to decipher viral replication mechanisms and to study antivirals or provide development platform for vaccines. The construction and manipulation of a reverse genetic system for a negative-strand RNA virus such as a respiratory syncytial virus (RSV), however, remains delicate and requires special know-how. The RSV genome is a single-strand, negative-sense RNA of about 15 kb that serves as a template for both viral RNA replication and transcription. Our reverse genetics system uses a cDNA copy of the human RSV long strain genome (HRSV). This cDNA, as well as cDNAs encoding viral proteins of the polymerase complex (L, P, N, and M2-1), are placed in individual expression vectors under T7 polymerase control sequences. The transfection of these elements in BSR-T7/5 cells, which stably express T7 polymerase, allows the cytoplasmic replication and transcription of the recombinant RSV, giving rise to genetically modified virions. A new RSV, which is present at the cell surface and in the culture supernatant of BSRT7/5, is gathered to infect human HEp-2 cells for viral amplification. Two or three rounds of amplification are needed to obtain viral stocks containing 1 x 106 to 1 x 107 plaque-forming units (PFU)/mL. Methods for the optimal harvesting, freezing, and titration of viral stocks are described here in detail. We illustrate the protocol presented here by creating two recombinant viruses respectively expressing free green fluorescent protein (GFP) (RSV-GFP) or viral M2-1 fused to GFP (RSV-M2-1-GFP). We show how to use RSV-GFP to quantify RSV replication and the RSV-M2-1-GFP to visualize viral structures, as well as viral protein dynamics in live cells, by using video microscopy techniques.
Human RSV is the leading cause of hospitalization for acute respiratory tract infection in infants worldwide1. In addition, RSV is associated with a substantial disease burden in adults comparable to influenza, with most of the hospitalization and mortality burden in the elderly2. There are no vaccines or specific antivirals available yet against RSV, but promising new drugs are in development3,4. The complexity and the heaviness of the techniques of quantification of RSV multiplication impede the search for antivirals or vaccines despite current considerable efforts. The quantification of RSV multiplication in vitro is generally based on laborious, time-consuming, and expensive methods, which consist mostly in the analysis of the cytopathic effect by microscopy, immunostaining, plaque reduction assays, quantitative reverse transcriptase (qRT)-polymerase chain reaction (PCR), and enzyme-linked immunosorbent assay tests. Viruses with modified genomes and expressing reporter genes, such as those coding for the GFP, are more suitable for such screenings. Coupled to the use of automated plate readers, reporter gene-carrying recombinant viruses can make these assays more suitable for standardization and high-throughput purposes.
RSV is an enveloped, nonsegmented negative-sense RNA virus that belongs to the Orthopneumovirus genus of the Pneumoviridae family, order Mononegavirales5. The RSV genome is a single-strand, negative-sense RNA of about 15 kb, which contains a noncoding region at the 3' and 5' extremities called Leader and Trailer and 10 transcriptional units encoding 11 proteins. The genes are ordered as follows: 3'-NS1, NS2, N, P, M, SH, G, F, M2 (encoding for M2-1 and M2-2 proteins) and L-5'. The genomic RNA is tightly packaged by the nucleoprotein N. Using the encapsidated genomic RNA as a template, viral RNA-dependent RNA polymerase (RdRp) will ensure transcription and replication of the viral RNA. Viral RdRp is composed of the large protein L which carries the nucleotide polymerase activity per se, its mandatory cofactor the phosphoprotein P and the M2-1 protein which functions as a viral transcription factor6. In infected cells, RSV induces the formation of cytoplasmic inclusions called inclusion bodies (IBs). Morphologically similar cytoplasmic inclusions have been observed for several Mononegavirales7,8,9,10. Recent studies on rabies virus, vesicular stomatitis virus (VSV), Ebola virus, and RSV showed that viral RNA synthesis occurs in IBs, which can thus be regarded as viral factories8,9,11,12. The virus factories concentrate the RNA and viral proteins required for viral RNA synthesis and also contain cellular proteins13,14,15,16,17. IBs exhibit a functional subcompartment called IB-associated granules (IBAGs), which concentrate the newly synthetized nascent viral mRNA together with the M2-1 protein. The genomic RNA and the L, P, and N are not detected in IBAGs. IBAGs are small dynamic spherical structures inside IBs that exhibit the properties of liquid organelles12. Despite the central role of IBs in viral multiplication, very little is known about the nature, internal structure, formation, and operation of these viral factories.
The expression of the genome of a poliovirus from a cDNA enabled the production of the first infectious viral clone in 198118. For single-stranded negative RNA viruses, it was not until 1994 that the production of a first rabies virus following transfection of plasmids into cells19 took place. The first plasmid-based reverse genetic system for RSV was published in 199520. Reverse genetics have led to major advances in the field of virology. The possibility of introducing specific modifications into the viral genome has provided critical insights into the replication and pathogenesis of RNA viruses. This technology has also greatly facilitated the development of vaccines by allowing specific attenuation through targeted series of modifications. Genome modifications allowing a rapid quantification of viral multiplication greatly improved the antiviral screening and study of their mode of action.
Although previously described, obtaining genetically modified RSVs remains delicate. Here, we detail a protocol to create two types of recombinant HRSV, respectively expressing RSV-GFP or RSV-M2-1-GFP. In this protocol, we describe the transfection conditions needed to rescue the new recombinant viruses, as well as their amplification to obtain viral stocks with high titer, suitable for reproducible experimentations. The construction of the reverse genetics' vectors per se is not described here. We do describe methods for the optimal harvesting and freezing of viral stocks. The most accurate method to quantify viral infectious particles remains plaque assay. Cells are infected with serial dilutions of the analyzed suspension and incubated with an overlay that prohibits the diffusion of free viral particles in the supernatant. In such conditions, the virus will only infect contiguous cells forming a "plaque" for each initial infectious particle. In the conventional RSV titration assay, plaques are revealed by immunostaining and counted under microscopic observation. This method is expensive and time-consuming. Here we described a very simple protocol for an RSV plaque assay using microcrystalline cellulose overlay that enables the formation of plaques visible to the naked eye. We show how RSV-GFP can be used to measure RSV replication and, thus, to quantify the impact of antivirals. Combining reverse genetics and live imaging technology, we demonstrate how RSV-M2-1-GFP allows scientists to visualize M2-1 in live cells and to follow the dynamics of intracellular viral structures, such as IBs.
1. Material Preparation
2. Rescue and First Passage of Recombinant Virus
NOTE: Perform all the following steps in a sterile environment, using a class II safety cabinet.
3. Amplification of the Rescued Viruses
NOTE: The following protocol describes the amplification of the rescued viruses in a 75 cm2 flask. Adapt the flask size to the volume needed and the required multiplicity of infection (MOI). Table 1 indicates volumes for different flasks. Perform all the following steps in a sterile environment in a class II safety cabinet.
4. Plaque Titration Assay
5. The Use of HRSV-GFP Recombinant Virus to Monitor Viral Replication in Cells Treated with Small Interfering RNA or Antivirals
NOTE: Perform all steps except 5.1 and 5.2.5 in a sterile environment using a class II safety cabinet.
6. Characterization of M2-1 Localization In Vivo with the RSV-M2-1-GFP Recombinant Virus
NOTE: Perform steps 6.1 and 6.2 in a sterile environment, using a class II safety cabinet.
In this work, we described a detailed protocol to produce recombinant RSV viruses expressing a fluorescent protein (Figure 2). In pRSV-GFP, the GFP gene was introduced between the P and M genes, as described for the Cherry gene in previously published work21. In the pRSV-M2-1-GFP, the M2 gene was left untouched and an additional gene coding for M2-1-GFP was inserted between SH and G genes12. The first step, corresponding to the rescue of the virus in BSRT7/5 cells, is shown in Figure 2A. Small clusters of green fluorescent cells were visible 72 h posttransfection in wells corresponding to RSV-GFP and RSV-M2-1-GFP rescue. The fluorescent signal could be observed in both cytoplasm and nuclei in RSV-GFP-infected cells, corresponding to the expression of the free GFP. In contrast, in the RSV-M2-1-GFP rescue, small fluorescent cytoplasmic dots could be observed, corresponding to M2-1-GFP accumulation in IBs. Usually no CPE (syncytia, detached cells) is observed at this step. Conversely, during the second step, corresponding to virus amplification (first passage) on HEp-2 cells, the CPE was visible in infected cells at 72 h p.i. (Figure 2B). Figure 3A,B shows the strong CPE of the RSV infection, characterized by large syncytia, detached or not, and many floating cells. Syncytia and cells both exhibited bright green fluorescence. Figure 3A shows the evolution of the cytopathic effect between 24 and 72 h p.i. in cells infected with the RSV-M2-1-GFP virus. A few scattered fluorescent cells were visible at 24 h p.i. without a detectable CPE. Small syncytia (cluster of fluorescent cells) and a few detached cells/syncytia started to appear at 48 h p.i. Large fluorescent syncytia and floating cells were clearly visible at 72 h p.i.
Pictures of plaque titration assay and viral titers corresponding to the whole process of RSV production are shown in Figure 5. Performing the plaque assay on the negative control, transfected with only the expression plasmids of N, P, L, and M2-1, revealed no plaque at the lowest dilution. The titers obtained from the transfected cells were expected to be above 100 PFU/mL if the rescue was efficient, as shown in Figure 5. Then, the titers increased over the passages, to reach 106–107 PFU/mL at passage 1 or 2. Note that the viral titers were similar between the two recombinant viruses.
Cells were transfected with siRNA targeting the mRNA of a viral protein (N) or of two cellular proteins (inosine-5'-monophosphate dehydrogenase [IMPDH] and glyceraldehyde 3'-phosphate dehydrogenase [GAPDH]). Cells were also transfected with nontargeting siRNA. Figure 6 shows the monitoring of RSV multiplication using RSV-GFP virus on siRNA-treated cells. A strong GFP signal was observed (Figure 6A) and measured (Figure 6B) on control cells transfected with nontargeting siRNA or cells transfected with siRNA against GAPDH mRNA. In contrast, the GFP expression was decreased in infected cells expressing siRNA targeting N or IMPDH. Note that we verified that the GFP fluorescent signal in RSV-GFP-infected cells at 48h p.i. was correlated with the viral dose as previously demonstrated for a similar recombinant RSV expressing Cherry (RSV-Cherry)21. To assess drug efficiency on RSV multiplication, HEp-2 cells were infected with RSV-GFP for 48 h in the presence of various drug concentrations. We observed a strong decrease of the GFP signal, which reached the background noise (there was a signal observed on uninfected cells), in the presence of an increased drug concentration, as shown in Figure 7. The observed IC50 for AZD4316 was about 4 nM, similar to the published EC50 of about 2–40 nM against different HRSV strains23. The analysis of the dynamics of IBs and IBAGs in living cells, thanks to RSV-M2-1-GFP, are shown in Figure 8 and Figure 9 (and Movie 1 and Movie 2). IBs appear as mobile spherical structures able to fuse, forming a larger spherical inclusion. IBAGs are very dynamic. They undergo continuous assembly-disassembly cycles with the formation of small IBAGs that grow, fuse into large IBAGs, and then disappear.
Plate or flask | HEp-2 cells to be seeded the day before | Medium volume (mL) | Virus Inoculum volume (mL) |
150 cm2 flask | 15 x 106 | 30 | 5 |
75 cm2 flask | 7.5 x 106 | 15 | 3 |
25 cm2 flask | 2.5 x 106 | 5 | 1 |
6-well plate | 1 x 106 | 2 | 0.5 |
Table 1: The number of cells and inoculum volume to use in different flasks.
Figure 1: Schematic representation of the rescue and amplification steps. Transfection of the expression vector of N, P, L, M2-1, and RSV antigenomic RNA into BSRT5/7 cells (Rescue). Expression of the antigenomic RSV RNA and of the mRNA of N, P, L and M2-1, by the T7 RNA polymerase. The N, P, L, and M2-1 proteins replicate and transcribe the genomic RNA, initiating a viral multiplication cycle. New viral particles are produced and multiply, giving rise to the P0. The virus harvested from the rescue (P0) is then amplified on HEp-2 cells to produce a higher titer viral suspension (P1) (Amplification). This is then amplified to obtain viral stocks. Please click here to view a larger version of this figure.
Figure 2: CPE and the pattern of fluorescence observed during the rescue of RSV-GFP and RSV-M2-1-GFP. (A) BSRT5/7 cells were transfected with the reverse genetics' vectors as indicated, and phase-contrast and fluorescence images were taken at 72 h posttransfection. The negative control (Neg Ctrl) corresponds to cells transfected with the expression vectors of N, P, L, and M2-1 without the reverse genetic vector. (B) HEp-2 cells were infected with the virus harvested from the transfected BSRT5/7 cells (the zero passage, 72 h posttransfection) and images were taken 72 h postinfection. The images shown are of representative fields; Scale bar = 100 µm. The boxed area encloses cells shown in magnification; Scale bar = 20 µm. Please click here to view a larger version of this figure.
Figure 3: Evolution of the CPE and the fluorescence observed during the amplification of recombinant RSV. HEp-2 cells were infected at a MOI of 0.01 PFU/cells for 72 h with the first passage of (A) RSV-M2-1-GFP or (B) RSV-GFP. Phase-contrast and fluorescence images were taken at 24 h, 48 h, and 72 h postinfection. The images shown are of a representative field; Scale bar = 100 µm. The boxed area encloses cells shown in magnification; Scale bar = 20 µm. Please click here to view a larger version of this figure.
Figure 4: Determination of RSV titer using the plaque assay. (A) Results of the plaque titration assay in a 12-well plate. The six wells infected with serial dilutions of one viral stock are shown. Dilutions are indicated in a base-10 logarithm. Cells infected with the three first dilutions are all detached. The plaque numbers observed with the 10-4, 10-5, and 10-6 dilutions are consistent. (B) Illustration of the plaque enumeration (yellow numbers). The green star indicates scratches on the cell layer. Please click here to view a larger version of this figure.
Figure 5: Titration of a rescued and amplified virus. Plaque phenotypes of the RSV-GFP and RSV-M2-1-GFP at the different passages assayed on HEp-2 cells in a 12-well plate (the images show the entirety of the wells). The titers of the subsequent passages are shown in the table. Representative data are shown. Dilutions of the viral stocks are indicated in a base-10 logarithm. Please click here to view a larger version of this figure.
Figure 6: Inhibition of the RSV-GFP expression by siRNA targeting RSV N or IMPDH. A549 cells were treated with control nontargeting siRNA (NT) (light blue bar) or siRNA targeting GAPDH (blue bar), RSV N (orange bar), or IMPDH2 (green bar) for 48 h and then infected with RSV-GFP at an MOI of 0.05 PFU/cell. The green fluorescence was read at 48 h postinfection. (A) Representative images of the RSV-GFP-infected cells at 48h p.i., treated with siRNA as seen on the pictures. Scale bar = 100 µm. (B) Data are the mean ± SD of two independent experiments performed in triplicate. Please click here to view a larger version of this figure.
Figure 7: Inhibition of RSV-GFP multiplication by AZD4136 compound. HEp-2 cells in 96-well plates were infected with RSV-GFP at an MOI of 0.05 PFU/cell in the presence of serial dilutions of AZD4316 compound or control DMSO. The green fluorescence was read at 48 h p.i. Data are the mean ± SD of two independent experiments performed in triplicate. Please click here to view a larger version of this figure.
Figure 8: Analysis of the dynamics of IBs by tracking the fluorescent protein M2-1-GFP in HEp-2-infected cells by time lapse microscopy. At 18 h p.i., cells were imaged every 5 min for 5 h with a fluorescence microscope, in a chamber heated at 37 °C. The IBs are fluorescent (green) because they host M2-1-GFP, and nuclei are stained with Hoechst (blue). The white arrows indicate IBs undergoing fusion. Scale bar = 10 µm. Please click here to view a larger version of this figure.
Figure 9: Analysis of the dynamics of IBAGs in RSV-M2-1-GFP-infected cells by time lapse microscopy. At 18 h p.i., cells were imaged with a fluorescence microscope, in a chamber heated at 37 °C. The M2-1-GFP protein was visualized by green fluorescence. The white arrows indicate IBs undergoing a fusion of IBAGs. Scale bar = 5 µm. Please click here to view a larger version of this figure.
Movie 1: In vivo analysis of the dynamics of IBs in RSV-M2-1-GFP in HEp-2-infected cells. At 18 h p.i., cells were imaged every 5 min for 5 h with fluorescence microscope, in a chamber heated at 37 °C. Scale bar = 10 µm. The resulting movie shows 7 frames/s (fps). Please click here to view this video. (Right-click to download.)
Movie 2: In vivo analysis of the dynamics of IBAGs in RSV-M2-1-GFP-infected cells. At 18 h p.i., cells were imaged every 5 min for 3 h and 40 min with fluorescence microscope, in a chamber heated at 37 °C. Scale bar = 2 µm. The resulting movie shows 4 fps. Please click here to view this video. (Right-click to download.)
Here we present a method of rescue of recombinant RSVs from five plasmids, and their amplification. The ability to manipulate the genome of viruses has revolutionized virology research to test mutations and express an additional gene or a tagged viral protein. The RSV we have described and used as an example in this article is a virus expressing a reporter gene, the RSV-GFP (unpublished), and expresses an M2-1 protein fused to a GFP tag12. RSV rescue is challenging and requires practice. The transfection efficiency is critical, depending on a wise selection of the transfection reagent and a prior optimization of the transfection protocol. The use of cells expressing the bacteriophage T7 pol is mandatory because the viral cDNA is placed downstream the T7 pol promoter in most of the reverse genetic vector. An alternative is to express the T7 pol from a vaccinia helper virus. However, the use of cells stably expressing the T7 pol avoids the necessity of separating the two viruses and prevents possible interference of vaccinia with the rescue. It is important to perform the first passage of the reverse genetic (P0 to P1) without freezing the inoculum to ensure maximal rescue efficiency. This implies that the MOI is not controlled. However, at this step, the titers remain very low, resulting in a low MOI for the first passage. To obtain RSV stocks with high infectious titers (106–107 PFU/mL), it is important to wait for a strong CPE and to scrape the cells to gather the viral particles attached to the cells. In this study, titers did not increase after 96 h p.i. The fast cooling of the viral suspension is important to maintain high titers. Instead of by an immersion in alcohol precooled at -80 °C, this may also be achieved by immersion in a dry ice/ethanol mix or in liquid nitrogen. The addition of the conservation solution will ensure a longer stability of the virus suspension at -80 °C. The storage at -80 °C is critical, since the virus will quickly loss its infectivity when stored at -20 °C or in liquid nitrogen. We described the RSV amplification on HEp-2 cells, which is the most popular cell line to grow RSV, but it is also able to grow efficiently on numerous other cell lines in vitro. Note, however, that growth on Vero cells may result in an alteration in G expression24.
We described a very simple protocol of plaque titration of RSV using a microcrystalline cellulose overlay. As for all titration assays, it is sensitive to contamination with high titer suspensions, requiring careful manipulation. Conventional RSV titration assays use agarose or carboxymethyl cellulose (CMC) overlays and require immunostaining and microscopic observations for titer determination. A protocol using immunodiffusion grade agarose has been described enabling the direct visualization of plaques without immunostaining25. However, HEp-2 cells are very sensitive to a heated agar overlay, which makes this protocol difficult to use for multiple virus titrations (e.g., a too hot overlay destroys the cell layer); on the other hand, when it is not hot enough, it solidifies after the first plate distribution. The use of microcrystalline cellulose for a plaque assay has been first described by Matrosovich et al. for an influenza A virus titration assay26. Thanks to its low viscosity, the microcrystalline cellulose overlay is easy to dispense and to remove from plate wells, making it compatible with 96-well plates. It is, thus, particularly adaptable to serological studies and drug sensitivity analyses. Note that since microcrystalline cellulose does not need to be heated, the drugs may be easily incorporated in the overlay. It is, however, important that the plates remain perfectly still during the incubation; otherwise, large comet-shaped foci will form instead of round plaques. Plaque revelation using crystal violet is cheap and simple, but this solution is toxic and has to be properly disposed of. The recycling of the solution limits waste production. Moreover, this method is sensitive to cell monolayer damage that would appear as false white spots that are not viral plaques. One example is shown in Figure 4 (green star). To prevent this bias, 1) cells have to be handled with caution to avoid scratching or flushing the cell monolayer, 2) aspiration and dispensing always have to made at the same spot to circumscribe the damage to one known area, and 3) false white spots may be identified thanks to their shape (not spherical), their sharp edges, and their position. We first used Avicel RC 581, as previously published21,26. However, the RC 581 is no longer available, and we successfully replaced it by RC 591. To adapt this assay to other cell/virus couples, the concentration of microcrystalline cellulose has to be determined depending on the virus and the cells. Too much microcrystalline cellulose may be toxic for cells and lead to small plaques, too little will lead to the diffusion of the virus in the medium.
We described two examples of use of the RSV-GFP virus to monitor RSV multiplication: in the presence of an antiviral drug or when silencing a cellular protein. We demonstrated that the GFP signal is correlated with viral multiplication. The method presented here allows the effortless evaluation of viral multiplication in real-time. It enables scientists to easily determine the IC50 of an antiviral drug, as shown in Figure 7. Importantly, this measurement is adaptable for use in medium or broadband, especially for the screening of chemical libraries. This reporter-expressing virus may also be useful to assess the effect on virus multiplication of a modulation of cellular protein expression. RNA interference is a biological process whereby a specific mRNA is degraded following its specific recognition by siRNA, thus reducing or, ideally, abolishing the expression of the corresponding protein27. In the example given here, by monitoring GFP signal intensity in RSV-GFP-infected cells, we assessed the impact of the silencing of the viral nucleocapsid (N) mRNA or the host IMPDH mRNA on RSV multiplication. IMPDH2 is a purine biosynthetic enzyme that catalyzes a rate-limiting step towards the de novo biosynthesis of guanine nucleotides from IMP28. It is thus a regulator of the intracellular guanine nucleotide pool. IMPDH inhibitors, such as ribavirin, exert inhibitory effects on RNA viruses, including RSV infection29,30,31. As shown in Figure 6, the inhibition of IMPDH expression impairs viral multiplication as indicated by the reduction of the GFP signal, mimicking the effects of ribavirin on RSV growth. Likewise, the viral multiplication is almost abolished in the presence of siRNA targeting the viral N protein. This result was expected since siRNA targeting the N protein was expected to prevent viral nucleocapsid assembly and has proven to strongly impair viral replication32. The administration of these siRNA by nebulization inhibited the subsequent infection by RSV in healthy adults33. The effect of N or IMPDH siRNA is specific since the inhibition of the GAPDH expression, chosen as a control gene, does not impair viral multiplication as compared to the nontargeting siRNA. Note that no cell toxicity was detected in any conditions. Taken together, these results validate the strategy presented here, which could be up scaled to high-throughput screening using siRNA libraries or other knockout methods, such as CRISPR-Cas9 technology34.
Recombinant viruses expressing a fusion fluorescent protein represent powerful tools to study viral proteins and viral structures dynamics. RSV expressing a fluorescent M2-1 protein enables the observation of the dynamics of IBs and of IBAGs. IBs, which may be considered as RSV viral factories, appear as spherical dynamic structures. They are able to fuse together to form larger spherical structures (Figure 8 and Movie 1). These data suggest that RSV IBs are liquid organelles, similar to what has been described for rabies virus35. IBAGs represent a subcompartment inside IBs, in which viral mRNA and M2-1 protein concentrate, such as the genomic RNA, the nucleocapsid, and the polymerase, are only present in the rest of the IBs12. Video microscopy experiments reveal that IBAGs are very dynamic structures exhibiting liquid properties (Figure 9 and Movie 2). They may be considered as liquid compartments resulting from liquid-liquid phase transition.
The possibility of genetically manipulating viruses remains a tool of choice to study both the mechanisms of their multiplication and their sensitivity to drugs. Reverse genetics might be considered now as part of the "classical" techniques of virology. However, it remains arduous for some viruses, like RSV. This is why this protocol describes in detail the steps to successfully rescue and amplify recombinant RSVs.
The authors have nothing to disclose.
The authors thank Dr. Qin Yu from AstraZeneca R&D Boston, MA, USA, for providing the AZD4316 drug. The authors are grateful to the Cymages platform for access to the ScanR Olympus microscope, which was supported by grants from the region Ile-de-France (DIM ONE HEALTH). The authors acknowledge support from the INSERM and the Versailles Saint-Quentin University.
35mm µ dish for live cell imaging | Ibidi | 81156 | |
A549 | ATCC | ATCC CCL-185 | |
Avicel RC-591 | FMC BioPolymer | Avicel RC-591 | Technical and other information on Avicels is available at http://www.fmcbiopolymer.com. Store at room temperature. Protocol in step 4 is optimized for this reagent. |
BSRT7/5 | not commercially available | See ref 22. Buchholz et al, 1999 | |
Crystal violet solution | Sigma | HT90132 | |
Fluorescence microscope for observations | Olympus | IX73 Olympus microscope | |
Fluorescence microscope for videomicroscopy | Olympus | ScanR Olympus microscope | |
HEp-2 | ATCC | ATCC CCL-23 | |
HEPES ≥99.5% | Sigma | H3375 | |
L-Glutamine (200 mM) | ThermoFisher Scientific | 25030024 | |
LIPOFECTAMINE 2000 REAGENT | ThermoFisher Scientific | 11668019 | Protocol in step 2.3. is optimized for this reagent. |
MEM (10X), no glutamine | ThermoFisher Scientific | 11430030 | |
MEM, GlutaMAX Supplement | ThermoFisher Scientific | 41090-028 | |
MgSO4 ReagentPlus, ≥99.5% | Sigma | M7506 | |
Opti-MEM I Reduced Serum Medium | ThermoFisher Scientific | 51985-026 | |
Paraformaldehyde Aqueous Solution, 32%, EM Grade | Electron Microscopy Sciences | 15714 | |
Penicillin-Streptomycin (10,000 U/mL) | ThermoFisher Scientific | 15140122 | |
Plasmids | not commercially available | see ref 21. Rameix-Welti et al, 2014 | |
See Saw Rocker | VWR | 444-0341 | |
Si RNA GAPDH | Dharmacon | ON-TARGETplus siRNA D-001810-10-05 |
SMARTpool and 3 of 4 individual siRNAs designed by Dharmacon. |
Si RNA IMPDH2 | Dharmacon | ON-TARGETplus siRNA IMPDH2 Pool- Human L-004330-00-0005 |
SMARTpool of 4 individual siRNAs designed by Dharmacon. Individual references and sequences J-004330-06: GGAAAGUUGCCCAUUGUAA; J-004330-07: GCACGGCGCUUUGGUGUUC; J-004330-08: AAGGGUCAAUCCACAAAUU; J-004330-09: GGUAUGGGUUCUCUCGAUG; |
Si RNA RSV N | Dharmacon | ON-TARGETplus custom siRNA | UUCAGAAGAACUAGAGGCUAU and UUUCAUAAAUUCACUGGGUUA |
SiRNA NT | Dharmacon | ON-TARGETplus Non-targeting Pool | |
SiRNA transfection reagent | Dharmacon | DharmaFECT 1 Ref: T-2001-03 | Protocol in steps 5.1.and 5.1.2 are optimized for this reagent. |
Sodium Bicarbonate 7.5% solution | ThermoFisher Scientific | 25080094 | |
Spectrofluorometer | Tecan | Tecan infinite M200PRO |