Abstract
To reveal the putative cellular factors involved in SARS coronavirus replication, the helicase (Hel, nsp13) of SARS coronavirus was used to screen the cDNA library of rat pulmonary epithelial cells using the yeast two-hybrid system. Positively interacting proteins were further tested using a mammalian cell hybrid system and co-immunoprecipitation in the human A549 cell line, which has been shown to support SARS coronavirus replication. Out of the seven positive clones observed by yeast two-hybrid assay, only the Ddx5 (Asp-Glu-Ala-Asp box polypeptide 5) protein showed specific interaction with SARS-CoV helicase. When expression of DdX5 was knocked down by small interfering RNA (siRNA), SARS coronavirus replication was significantly inhibited in fetal rhesus kidney (FRhK-4) cells. Since Ddx5 is a multifunctional protein that plays important roles in transcriptional regulation, its interaction with SARS coronavirus helicase provides interesting clues for studying virus–host cell interactions in SARS-CoV infections.
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The worldwide epidemic outbreak of severe acute respiratory syndrome (SARS) in 2003 was caused by a novel coronovirus (CoV), designated SARS coronavirus (SARS-CoV). The 29.7-kb positive-strand RNA genome of this virus has been sequenced [1–3]. In the 5′-region, the viral replicase gene (21221nt) encodes two large replicative polyproteins: pp1a (486 kDa) and pp1ab (790 kDa).The pp1a and pp1ab polyproteins are autoproteolytically processed by the main proteinase (Mpro, or 3CLpro) to yield the functional components, including a single-stranded-RNA-binding protein (nsp9), an RNA-dependent RNA polymerase (RdRp, nsp12), a short primer for nsp12, a superfamily-1-like helicase (Hel, nsp13) and a uridylate-specific endoribonuclease (nsp15) [4]. Mpro, the RdRp and the Hel are all thought to be essential for the virus life cycle [5–7]. Coronavirus helicases are highly conserved, and the quaternary structure of SARS-CoV helicase has been predicted to possess two separate domains, i.e., the helicase domain (Hel) and a metal-binding domain (MBD) [8]. However, it remains unclear how the Hel and MBD are functionally related to one another and what implications this has for viral viability. Helicases have been targeted for the treatment of herpes simplex virus [9–11] and hepatitis C virus [12] infections, suggesting that the SARS-CoV helicase may also be a potential target in the search of new anti-SARS drugs [9, 11–14]. As an example, bananins have been shown recently to inhibit the SARS-CoV helicase in vitro [15].
Various human proteins interacting with different genes of SARS-CoV have been identified or predicted [16]. However, host proteins interacting with the helicase have not yet been identified. In this study, we first employed the yeast two-hybrid system to address this issue, which was further verified by mammalian two-hybrid assay and in vivo co-immunoprecipitation to reveal the cellular cofactors interacting with SARS-CoV helicase.
SARS-CoV strain Urbani (AY278741) was used in this study. After the virus was propagated in Vero-6 cells, viral RNA was extracted with TRIZOL (Invitrogen), and the full-length helicase gene, with a size of 1,800 bp, was amplified by one-step RT-PCR (Qiagen, Valencia, CA, USA). Using Y2H helicaseF primer and Y2H helicaseR primer (Supplementary Table 1), the Hel gene was amplified from the RT-PCR product and cloned into the yeast bait vector pGBKT7 (CLONTECH, NcoI and PstI) to generate construct pGBKT7-Hel. The construct was verified by sequencing. A rat lung cDNA library (Clontech, Japan) was used as the prey. The prey library was amplified according to the manual, and plasmids were prepared using the Qiagen Plasmid Mega extraction kit.
Expression of helicase was conducted by using the bait plasmid pGBKT7-Hel to transform the yeast strain AH109 through a small-scale transformation using lithium acetate. Transformants were lysed by urea/SDS (8 M urea, 5% SDS, 40 mM Tris–HCl, pH 6.8, 0.1 mM EDTA, 0.4 mg/ml bromophenol blue), the lysates were subjected to Western blotting, and the blots were probed with the GAL4 DNA-BD monoclonal antibody (Clontech). The colony-lift filter assay was used to measure the β-galactosidase activity of the reporter gene by helicase on Whatman 3 M filters using X-gal as substrate. pCL1 was used as a positive control, and pGBKT7-Lamin and pGBKT7 were used as negative controls. The successful expression of SARS-CoV helicase in yeast strain AH109 is shown in Fig. 1, and by colony-lift filter assay, the expression of SARS-CoV helicase in yeast strain AH109 was shown not to activate the MEL1 reporter gene (data not shown), which excluded self-activation.
Yeast two-hybrid screening was performed using a sequential transformation method as described in the MATCHMAKER GAL4 Two-Hybrid System 3 & Libraries User Manual (Clontech). Briefly, the bait plasmid pGBKT7-Hel (TRP1) was first introduced into the haploid yeast strain AH109 using a small-scale transformation procedure, and the prey plasmids pACT2-X (LEU2) were sequentially introduced into AH109 [pGBKT7-Hel] using a large-scale procedure. The final AH109 transformants were re-suspended in YPDA medium and plated on SD/-Trp/-Leu/–His/-Ade/X-α-Gal selective plates (Quardruple dropout = QDO, high-stringency plates for screening the expression of ADE2, HIS3, and MEL1) containing 1.25 mM 3-AT to inhibit background growth. The control plasmids used were pGBKT7-Lamin, pGBKT7-53, pGADT7-T, pGBKT7 and pACT2. One hundred thirty-three colonies that grew on the QDO plates were re-streaked on the selective plates in triplicate. Blue colonies were further assayed for β-galactosidase activity within 8 h on Whatman 3 M filters using X-gal as substrate, and pCL1 (Clontech) was used as a positive control in the β-gal assay.
To isolate the bait and AD/library plasmids and sort colonies to eliminate duplicates, purified plasmid DNA extracted from the positive yeast colonies was introduced by transformation into E. coli strain DH5α, and the AD/library plasmids were digested separately with AluI and BglII. To retest individual protein interactions in yeast, the AD/library plasmids were transformed into AH109 and the bait plasmid into Y187. Each β-galactosidase-negative AH109 transformant was mated with Y187 transformants to select for true positive diploids. Finally, the sequences of the inserts in the true positive AD/library plasmids were analyzed using the 3′ AD Sequencing Primer and T7 Sequencing Primer (Clontech). By colony sorting (AluI and BglII digestion), a total of 47 clones were selected among the 133 clones that grew on SD/QDO/X-α-Gal/3-AT plates. Five out of the 47 clones showed autoactivation and were discarded. The other 42 clones were individually tested by mating with Y187 (pGBKT7-Hel) or Y187 (empty pGBKT7 vector). An interaction was considered to be a “true positive” only if it fulfilled the following criteria: (1) Diploids of the prey plasmid mating with pGBKT7-Hel grew on QDO plates. (2) Diploids of the prey plasmid mating with empty vector pGBKT7 did not grow on QDO plates. (3) The ORF of inserts matched the protein coding region(s) in BLASTP search. Only seven colonies, i.e., #28, #37, #42, #44, #77, #91, and #123 fulfilled these criteria (Table 1).
Since post-translational processing in yeast may be different from that in mammalian cells, the mammalian two-hybrid system was further used to verify the findings from the yeast two-hybrid assay. A549 cells (human, Caucasian, lung, carcinoma), which have been shown to support the growth of SARS-CoV, were used in mammalian two-hybrid studies followed by in vivo co-immunoprecipitation. The mammalian expression vector pBIND (Promega) and the co-immunoprecipitation vector pCMV-HA (Clontech) were used to generate constructs harboring the helicase gene of SARS-CoV. The two constructs were verified by sequencing and named pBIND-Hel and pCMV-HA-Hel, respectively. The primers used for cloning are listed in Supplementary Table 1.
Mammalian two-hybrid assays were performed following the instruction of the CheckMate™ Mammalian Two-Hybrid System (Promega). The genes of interest, including those of #28, #37, #42, #44, #77, #91, and #123, were amplified separately by PCR and cloned into pACT (Promega) to generate fusion proteins with the activation domain of VP16 (the primers used are listed in Supplementary Table 1). Co-transfection of A549 cells with the seven constructs (#28, #37, #42, #44, #77, #91, and #123) along with the reporter plasmid pG5luc, which encodes firefly luciferase, was performed using Lipofectamine 2000 reagent (Invitrogen). Paired plasmids pBIND-Id and pACT-MyoD were used as positive controls, and the empty plasmids pBIND and pACT were used as negative controls. Each co-transfection was repeated five times. Firefly luciferase activity and Renilla luciferase activity were measured using the Dual-Luciferase® Reporter Assay System (Promega). Renilla luciferase activity was used to normalize the differences in transfection efficiencies. As showed in Table 2, by comparing the relative intracellular firefly luciferase activity of each co-transfected clone with its background control, among the seven clones that were previously positive in the yeast two-hybrid assay, only clone #42, encoding Ddx5, was found to be positive in the mammalian two-hybrid assay. The relative intracellular firefly luciferase activity cotransfected with clone #42, encoding Ddx5, was significantly higher than that of the corresponding background controls (P < 0.001). These results suggested that SARS-CoV helicase could interact with Ddx5 in A549 cells.
To confirm that the protein interaction between SARS-CoV helicase and Ddx5 occurred in vivo, co-immunoprecipitation was performed in cell culture. The Ddx5 gene was amplified (see Supplementary Table 1 for primers) and cloned into the plasmid pCMV-Myc (Clotech), and A549 cells were co-transfected with the construct pCMV-Myc-Ddx5 and plasmid pCMV-HA-Hel. Cells were harvested and lysed 48 h post-transfection, and cell lysates were first precleared by treatment with Protein A-Agarose (Invitrogen), followed by precipitation with rabbit polyclonal anti-HA IgG (Sigma). The precipitated complexes were separated by sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) and transferred onto PVDF membranes. The blots were first reacted with anti-c-Myc monoclonal antibodies (1:200, Clontech) as the primary antibodies and were subsequently detected using alkaline-phosphatase-conjugated secondary antibodies. Visualization of the immunoreactive proteins was shown by using CDP STAR reagents (Roche, Germany). As shown in Fig. 2a, the Myc-Ddx5 protein was detected by the anti-HA Ab, while the co-immunoprecipitation of Ddx5 with Hel from SARS-CoV was detected by anti-c-Myc Ab (Fig. 2b, lane 4). The results indicate that the Ddx5 protein interacted with helicase during immunoprecipitation. Importantly, no interactions were detected between the Ddx5 protein with lysates from the A549 cells co-transfected with the controls, which included pCMV-Myc plus HA-Hel (Fig. 2b, lane 2), pCMV-HA plus Myc-Ddx5 (Fig. 2b, lane 3), and pCMV-Myc plus pCMV-HA (both were empty vectors, Fig. 2b, lane 1).
To determine the effect of Ddx5 on SARS-CoV replication, the expression of Ddx5 was knocked down by siRNA targeting Ddx5 mRNA, and the viral load and titers were evaluated. Briefly, small interfering RNA (siRNA) oligonucleotides (Ddx5-1144, 5′-GGUUCUAAAUGAAUUCAAATT-3′) targeting mRNA of Ddx5 (accession number NM_004396.2) and control unrelated siRNA (5′-UUCUCCGAACGUGUCACGUTT-3′) were synthesized (GenePharma, Shanghai, China). Fetal rhesus kidney (FRhK-4) cells were transfected with 1.5 μM siRNAs using LipofectamineTM RNAiMAX (Invitrogen, USA) in six-well plates, and the expression levels of Ddx5 were detected by western blot analysis (1: 100, anti-p68 RNA helicase, Santa Cruz) 72 h post-transfection. As shown in Fig. 3a, the expression of Ddx5 was dramatically reduced in FRhK-4 cells treated with Ddx5-specific siRNA, but not with control unrelated siRNA. After the FRhK-4 cells were transfected with siRNAs (1.5 μM) for 16–18 h in 96-well plates in duplicate, the transfected cells were infected with 100 TCID50 of SARS-CoV strain GZ-50 [17]. Supernatants were collected 72 h after viral infection to detect viral load by real-time RT-PCR and viral titers by back-titration as described previously [18–20]. The experiments were repeated twice. As shown in Fig. 3b, the viral RNA copy was inhibited by 70%, and the viral titer of SARS-CoV strain GZ-50 was reduced by 97%.The results showed that SARS coronavirus replication was significantly inhibited in FRhK-4 cells transfected with Ddx5-specific siRNA.
The roles of helicase of SARS-CoV in virus replication have been extensively studied [8, 21]. Ivanov et al. [22] have characterized the enzymatic activities of a recombinant form of the SARS-CoV helicase (nsp13) and reported that nsp13 has both RNA and DNA duplex unwinding activity. A recent study on intraviral protein–protein interactions revealed that nsp8 interacts with a number of replicase proteins, including nsp13 [16]. By reverse genetic studies, ORF1ab proteins were shown to be involved in cellular signaling and modification of cellular gene expression, which might be related to viral virulence [23]. Since SARS-CoV replication is a highly complex process, interactions between helicase and cellular proteins, such as transcription factors, regulatory molecules and proteins controlling cell viability and proliferation, could be involved. In this study, we first used the yeast two-hybrid system to screen possible cellular proteins interacting with SARS-CoV helicase [24]. Aside from the advantage of the yeast two-hybrid system that it can screen a large number of protein–protein interactions in an intracellular setting, because enzymes are used as reporters that can amplify the signal, the yeast two-hybrid system is highly sensitive and can detect weak protein–protein interactions. On the other hand, since some proteins may have intrinsic transcriptional activation activity or are inherently sticky (“promiscuous interactors”), false positive results are commonly observed. Methods for eliminating or obviating this defect have been developed, and thus, the yeast strain AH109 used in this study contains three selective markers: ADE2, HIS3 and MEL1 for higher stringency in screening and assay. Therefore, in this study only seven positive clones were obtained that needed to be verified.
By two-hybrid assay in mammalian cells and co-immunoprecipitation, Ddx5 from A549 cells was shown to interact specifically and directly with the SARS-CoV helicase protein. It has been shown that SARS-CoV can replicate in the human-lung-derived A549 cell line [25], and we believe that this finding has important implications. Ddx5 is a prototypical member of the DEAD box family of RNA helicases, which was first identified by cross-reaction with a monoclonal antibody [26, 27]. Ddx5 was one of the first proteins showing RNA helicase activity in vitro [28], and Ddx5 (p68) has been shown to be involved in many biological events related to RNA structure, such as transcription [29], pre-mRNA processing, RNA degradation, RNA export, ribosome assembly and translation [30]. In addition, increasing evidence has indicated that Ddx5 (p68) interacts with many transcription factors, including several transcriptional co-activators and co-repressors. It interacts with and acts as a transcriptional coactivator for the nuclear receptor estrogen receptor alpha (ERα) [31]. A recent report has suggested that p68 acts as a potent coactivator for the tumor suppressor p53, a latent transcription factor that is induced and deactivated in response to stresses, such as DNA damage, and induces transcription of genes involved in cell cycle arrest and apoptosis[32]. Ddx5 also interacts with many other transcription factors including SMAD3 [33] and MyoD. In addition, Ddx5 also associates with RNA coactivator SRA [34], p300, CREB-binding protein (CBP) [35], RNA polymerase II and HDAC1 [36]. All of these data indicate that Ddx5 (p68) is involved in many cellular processes.
To our knowledge, this is the first report to show that SARS-CoV helicase can interact directly with multifunctional protein Ddx5 in cell culture and that inhibition of Ddx5 results in the suppression of viral replication. We speculate that Ddx5 may act as a coactivator by direct binding to the SARS-CoV helicase, resulting in enhanced viral genome transcription and virus proliferation. In addition, in view of the important functions of Ddx5, the cellular effects exerted by the complex formed between SARS helicase and Ddx5 needs further study.
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This work was supported by Sino-German collaborative grant GZ230 (202/3).
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Chen, JY., Chen, WN., Poon, KM.V. et al. Interaction between SARS-CoV helicase and a multifunctional cellular protein (Ddx5) revealed by yeast and mammalian cell two-hybrid systems. Arch Virol 154, 507–512 (2009). https://doi.org/10.1007/s00705-009-0323-y
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DOI: https://doi.org/10.1007/s00705-009-0323-y