key: cord-0888124-t1p5ospi authors: Donaldson, Eric F.; Sims, Amy C.; Baric, Ralph S. title: Systematic Assembly and Genetic Manipulation of the Mouse Hepatitis Virus A59 Genome date: 2007-11-28 journal: SARS- and Other Coronaviruses DOI: 10.1007/978-1-59745-181-9_21 sha: b65a29cddbd3545658a10998acf318a6872986e1 doc_id: 888124 cord_uid: t1p5ospi We have developed a DNA assembly platform that utilizes the nonspecific, highly variable sequence signatures of type IIs restriction enzymes to assemble a full-length molecular clone of murine hepatitis coronavirus (MHV) strain A59. The approach also allows changes to be engineered into a DNA fragment by designing primers that incorporate the restriction site and the mutations of interest. By adding the type IIs restriction site in the proper orientation, subsequent digestion removes the restriction site and leaves a sticky end comprising the mutation of interest ready to ligate to a second fragment generated in parallel as its complement. In this chapter, we discuss the details of the method to assemble a full-length infectious clone of MHV and then engineer a specific mutation into the clone to demonstrate the power of this unique site-directed “No See’m” mutagenesis approach. Mouse hepatitis virus (MHV) strain A59 is an extensively studied group 2 coronavirus (CoV). Its genome is an approximately 31.5-kb single-stranded positive-sense RNA, which contains a 5 cap and poly(A) tail (1,2). The first two-thirds of the genome encodes the nonstructural proteins required for viral RNA replication and transcription, and the final third comprises six additional open reading frames (ORFs) from which a nested set of 3 co-terminal subgenomic mRNAs is transcribed (Figs. 1A,B,3C) . Upon entry into the cell, the Fig. 1 . The MHV genome, subgenomic transcription, and strategy for infectious clone assembly: (A) The MHV genome is ∼31.5 kb, with the first two-thirds comprising the nonstructural replicase genes required for viral RNA synthesis (gray rectangle), and the final third encoding the structural genes important for assembly of the viral particle (large black rectangle). The 5 -end is capped and contains a leader sequence (small black box) and the 3 -end has a poly(A) tail. (B) The structural and accessory genes are encoded as a nested set of co-terminal mRNAs, each of which contains the leader sequence derived from the 5 -end of the genome and a poly(A) tail. (C) For assembly of an infectious clone of MHV, the genome was divided into seven stable contiguous cDNA fragments known as MHV-A, MHV-B, MHV-C, MHV-D, MHV-E, MHV-F, and MHV-G. Unique type IIs restriction sites were used to generate unique junctions, which when ligated together produce a full-length cDNA. This allows manipulation of any region of the genome by targeting the fragment of interest and engineering No See'm sites to incorporate the mutation. In this example we target genomic position 13354-56 (indicated by •), which falls within the MHV-E fragment. Numbers on top of the assembled genome indicate fragment sizes, while bottom numbers represent genomic positions. N-encapsidated viral RNA is released from the virion and immediately translated by host machinery, resulting in large polyprotein precursors, which are autocleaved to generate intermediates and eventually 16 mature proteins, most of which are thought to function in viral RNA synthesis (3-6). The subgenomic mRNAs are generated from a similar-sized subgenomic negative strand, which is synthesized only after the viral replication complex is functional. The negative subgenomic RNA serves as a template for transcription of similar-sized subgenomic mRNAs, which contain the leader sequence as well as the ORF that encodes the protein directly downstream of the leader sequence (7-10). All subgenomic mRNAs are co-terminal, with each subsequent mRNA containing the sequence for all downstream ORFs, although only the 5 -most ORF is translated. This allows for rapid detection of viral replication by RT-PCR using primers that anneal to the leader and the N-gene, which results in a ladder of different sized products (Figs. 1B,3B,C) (7-10). In cell culture, murine delayed brain tumor (DBT) cells infected with wildtype MHV experience cytopathology characterized by the formation of syncytia, caused by interaction of spike glycoproteins, which anchor in the cell membrane and interact with other spikes in neighboring cells. Wild-type infections generate uniform circular plaques ∼5 mm in diameter (Fig. 4A) . Prior to the development of an infectious clone of MHV, reverse genetics of the viral coding sequence was restricted to the ORFs downstream of the replicase. Targeted recombination was the primary method for manipulation of the structural and accessory ORFs of MHV, and while extremely powerful, this methodology did not provide an approach to engineer changes into the viral replicase genes (2,11). Moreover, RNA recombination can result in aberrant recombination events resulting in second-site changes (12), necessitating an approach to manipulate the entire genome as a recombinant molecule. Full-length cDNA constructs revolutionized reverse genetic applications in the entire MHV genome. Our laboratory developed a full-length molecular clone of MHV-A59 (icMHV) by implementing a No See'm approach (Figs. 1C,2A,B ) (13). Our strategy was to divide the genome into pieces that could be stably subcloned into E. coli-based plasmids to facilitate targeted mutagenesis studies and would be easy DNA to store and maintain, using the same approach that was successful with the transmissible gastroenteritis virus (TGEV) infectious clone (13,14) (Figs. 1C,2A,B) . However, the MHV molecular clone was difficult to establish as several toxic regions existed in the genome. Consequently, several of the MHV cDNA fragments required subdivision into smaller subclones and cloning into transcription and translation negative vectors (Fig. 2B) . To ensure unidirectional ligation of all fragments, native or engineered type IIs restrictions sites were used to form junctions at the ends of each fragment, which allowed the restriction site to be removed by restriction digestion (13). A T7 promoter site was added at the 5 -end of the genome to facilitate in vitro transcription of the full-length cDNA fragment after ligation, and a poly(A) tail was included at the 3 -end (13) (Fig. 1C) . The purpose of this review is to provide a detailed protocol that allows for efficient, systematic assembly and mutagenesis of coronavirus full-length cDNAs using class IIs restriction enzymes and the No See'm based mutagenesis approach. The pros and cons of this approach and an appraisal of what the future holds for this technology are discussed at the end (see Note 8). Assembling the full-length clone of MHV involves a series of steps, each of which is important for amplifying and purifying the reagents necessary for the next step. Briefly, plasmids are transformed into chemically competent E. coli and plated in the presence of appropriate antibiotic selection. Colonies are isolated and grown overnight at room temperature (see Note 6); the DNA is harvested and inserts verified by a screening restriction digestion. It is important to screen the DNA prior to setting up the large-scale preps to ensure plasmid integrity. We typically harvest 50-75 g of each plasmid DNA, restrict the DNA with the appropriate restriction endonucleases, and purify the viral cDNAs from agarose gels. It is equally important to keep the digested fragments free of contaminants, including residual carbohydrates from the gel extraction procedure or contamination with other fragments, particularly a wild-type version of a mutated fragment (see Note 2). Following gel extraction, chloroform extractions are performed to ensure that all carbohydrate contaminants are removed prior to preparing the ligation reaction (see Note 4). It is also important to maintain an RNAse-free environment (as much as possible) after ligation of the full-length clone. Always wear gloves, keep the bench top RNAse-free by spraying with RNAse Zap (Ambion, Austin TX; cat. no. 9780), and always use DepC water (see Note 2) and barrier tips (see Note 3). In addition, washing the BHK-MHVr cells with PBS made with DepC water may help prevent degradation of the electroporated full-length viral RNA (see Note 2). 1. The seven fragments of MHV are maintained in either pCR-XL-Topo or pSMART vectors, and each vector encodes a different antibiotic resistance cassette. For pCR-XL-Topo cloning vector encodes kanamycin resistance, whereas the pSMART vector encodes ampicillin resistance (pSMART vectors are available with kanamycin or ampicillin resistance; in this case it is ampicillin). LB broth and LB agar plates with each antibiotic are required for growing the newly transformed bacteria. Although other vector-fragment combinations exist, we focus on the following in this report: pCR-XL-Topo-MHV-A, pSMART-MHV-B, pSMART-MHV-C, pSMART-MHV-D, pSMART-MHV-E, pSMART-MHV-F, and pSMART-MHV-G (13). Plasmids are stored at approximately 20 ng/l at -80 • C. 2. Thaw each plasmid and the chemically competent Top10 cells (one vial per plasmid) on ice. Add 100 ng of each plasmid to an appropriately labeled vial of cells (50 l) and incubate on ice for 30 min. 3. Transform the cells by heat shock in a water bath maintained at 42 • C for 2 min, followed by 2 min on ice. 4. Add 200 l SOC medium (without antibiotic) and rock the vials at room temperature for 2 h. 5. Inoculate two LB plates (with appropriate antibiotic) for each plasmid, using 25 l and 100 l of culture and incubate the plates at room temperature for 48 h. 6. Pick at least five colonies of each plasmid (from one or both plates) and inoculate each into a 15-ml conical containing 5 ml of LB broth with appropriate antibiotic. Grow the colonies for 16-24 h at 28.5 • C in an incubator shaker set at 250 rpm. We have found that plasmid stability is enhanced at the lower temperature. 7. Prepare a library plate by inoculating an LB agar plate (with appropriate selection) with 25 l of the supernatant of each colony. The library plate should contain all of the colonies for one plasmid, and is grown at room temperature for 16-24 h and then stored at 4 • C. Then spin the cultures at 3000 × g for 10 min at 4 • C, aspirate, and discard the supernatant. 8. Plasmids are isolated from E. coli using the Qiagen Miniprep Kit, according to the manufacturer's instructions. Follow the plasmid DNA purification scheme using the Qiaprep Spin Miniprep Kit and a microcentrifuge protocol, and elute the plasmid DNA in 50 l of elution buffer preheated to 70 • C. 9. Screen each colony by restriction digestion to verify the insert size and restriction map. a. pCR-XL-Topo-MHV-A: 10 l plasmid, 1 l MluI, 1 l BsmBI, 2 l NEB Buffer 3, 6 l water. Incubate at 55 • C for 1 h. b. pSMART-MHV-B: 10 l plasmid, 1 l BglI, 2 l NEB Buffer 3, 6 l water. Incubate at 37 • C for 1 h. Add 1 l BsmBI and incubate at 55 • C for an additional 1 h. c. pSMART-MHV-C: 10 l plasmid, 1 l BglI, 2 l NEB Buffer 3, 6 l water. Incubate at 37 • C for 1 h. Add 1 l BsmBI and incubate at 55 • C for an additional 1 h. d. pSMART-MHV-D: 10 l plasmid, 1 l BsmBI, 1 l BSA, 2 l NEB Buffer 4, 5 l water. Incubate at 55 • C for 1 h. Add 1 l AhdI and incubate at 37 • C for an additional 1 h. e. pSMART-MHV-E: 10 l plasmid, 1 l BsmBI, 2 l NEB Buffer 3, 7 l water. Incubate at 55 • C for 1 h. f. pSMART-MHV-F: 10 l plasmid, 1 l BsmBI, 2 l NEB Buffer 3, 7 l water. Incubate at 55 • C for 1 h. g. pSMART-MHV-G: 10 l plasmid, 1 l SfiI, 1 l BsmBI, 1 l BSA, 2 l NEB Buffer 2, 5 l water. Incubate at 55 • C for 1 h. 10 . Run the restriction digestions out on a 0.8-1.0% agarose gel in TAE buffer (4.84 g/liter Tris base, 2 ml/liter 0.5 M EDTA pH 8.0, 1.14 ml/liter glacial acetic acid; pH to 8.5) at 100 mA, and determine that the plasmid DNAs have the appropriate banding pattern ( Fig. 2A) . The digests were designed to ensure that the desired MHV insert is the slowest migrating band in the gel ( Fig. 2A) . MHV-A is 5000 bp, MHV-B is 4672 bp, MHV-C is 1954 bp, MHV-D is 1451 bp, MHV-E is 2792 bp, MHV-F is 6985 bp, and MHV-G is 8711 bp (Figs. 1C,2A ). 1. Identify replicates on the library plate for each fragment that looks right by restriction screen. 2. Prepare a 50-ml conical containing 15 ml of LB broth with appropriate antibiotic and inoculate it with a streak from the library plate for each plasmid to be amplified. In general, one 15-ml culture of each plasmid DNA insert is sufficient for assembling at least two full-length MHV clones. Incubate for 12-16 h at 28.5 • C in an incubator shaker set at 250 rpm. Then add 5 ml of LB plus antibiotic and allow growth to continue for an additional 4-6 h under the same conditions. 3. Spin the cultures at 3000 × g for 10 min at 4 • C and discard the supernatants. Resuspend 5. Isolate the digested fragments by electrophoresis on a 0.8-1.0% gel in wells capable of holding 75 l each (three wells per reaction) ( Fig. 2A) . The restriction products should be run for enough time to allow for high resolution of individual fragments. 6. Excise the top band of the correct size for each fragment from the gel, making sure that it corresponds to the size of the MHV fragment ( Fig. 2A) and is not an undigested vector-MHV fragment. Place the excised band in a 1.5-ml microfuge tube. 7. Use the Qiaex II Gel Extraction Kit for extracting the DNA from the agarose as follows: a. Use the Qiaex II Agarose gel extraction protocol with the following modifications: i. Resuspend the excised band in 620 l of QX1 buffer, 12.5 l 3 M sodium acetate, and 11 l QIAEX II resin. Incubate in a water bath at 55 • C for a total of 12-16 min, agitating every 2 min. For fragments larger than 4 kb (MHV-A, MHV-B, MHV-F, and MHV-G), add 360 l of water after 6 min of incubation. Follow the protocol for the remaining steps and elute to a final volume of 35 l. Add the three replicates for each extraction into one tube (∼100 l). A final chloroform only extraction is performed to remove any residual impurities that remain after the DNA extraction (see Note 1). Use a 1:1 volume of chloroform, shake for 2 min, and spin at top speed in a microcentrifuge at room temperature for 2 min. Remove the aqueous phase to a fresh tube. h. Then run PCR through the following cycles: 1 cycle of 94 • C for 5 min, followed by 30 cycles of 94 • C for 1 min, 58 • C for 1 min, 68 • C for 3 min, and then 1 cycle of 68 • C for 10 min followed by 4 • C until ready for gel electrophoresis. i. The PCR product is then purified as described above (Section 3.2 steps 5-8). 6 . In vitro transcription of the N-gene is conducted using the mMessage mMachine SP6 Transcription Kit with the following reaction recipe per reaction: a. 12.5 l 2X NTP/CAP (10 mM ATP, 10 mM CTP, 10 mM UTP, 2 mM GTP, and 8 mM cap analog). b. 2.5 l 10X Buffer.. c. 3.5 l SP6-N-gene template d. 2.5 l enzyme (RNA polymerase). e. 4 l nuclease-free water. f. Incubate the reaction at 40.5 • C for 25 min, then at 37 • C for 50 min, and then at 40.5 • C for 25 min more. Use a PCR-cycler for the most consistent results. g. Do one reaction for each transfection and one additional reaction for the negative control. 1. Cell culture must be planned a day or two in advance, as three T150 flasks of BHK-MHVr cells at ∼70% confluency and one T150 flask of DBTs at 80-90% confluency are required to do one transfection and one negative control (see Note 5). 2. Cells are maintained in the medium described above (Section 2.1, steps 1-3). For passage, the medium is aspirated and the attached cells are washed. Cells are removed from the flask with 0.25% trypsin, and then resuspended and passaged in the medium. Splitting a confluent T150 flask of BHK-MHVr cells (e.g., ∼2-3 × 10 7 cells) the night before at 1:5 will generally produce a T150 at ∼70% confluency the next day. a. The remaining 5 l is saved to run on an RNA gel (Fig. 3A) . Pulser Excel electroporator at 25 F and 850 V. 5. Place each cuvette into the Shock Pod shocking chamber and pulse three times. 6. Allow each cuvette to incubate at room temperature for 10 min. 7. Remove the electroporated cells from the cuvette into the appropriately labeled T75 flask of DBT cells (optional). Alternatively, allow the electroporated MHVr cells to settle onto a T75 flask and incubate at 37 • C for 1-2 days to allow for the development of cytopathology. 8. Incubate the flasks at 37 • C in an incubator with 5% CO 2 . 1. Wild-type MHV from the clone will generally produce cytopathic effects (CPE) within 8-12 h, and the syncytium across the monolayer is usually complete by 24 h. We typically recover between 1000 and 10,000 plaques (infectious center assay) following electroporation of transcripts. CPE is very obvious for DBT cells infected with MHV. Excess spike glycoproteins accumulate at and protrude from the cell surface, which facilitates fusion with the neighboring cells. This creates large multinucleated syncytia, which are usually observed by 8-12 h posttransfection. As the cells die, they lift off the flask, and so an efficient transfection of full-length viral RNA will result in a rapid clearing of the monolayer, usually within 16-24 h. 2. Mutants generally come up more slowly and may take up to 72 h for CPE to be obvious. Highly debilitated mutants may not display obvious CPE. Passage usually selects for second-site revertant viruses that replicate efficiently, so extensive passage usually results in recombinant viruses containing multiple mutant alleles scattered across the genome. Reversions at the site of mutation can be reduced by fixing each engineered mutation with two or more nucleotide changes in the codon. 3. Harvest supernatants by spinning the at ∼3000 × g for 10 min at room temperature and aliquoting to fresh 2-ml screw cap tubes. Store at -80 • C. These are labeled as passage zero (P0). 1. Plaque purification allows isolation of single colonies of virus for propagation of stocks and verification of genotype (Fig. 4) . This is done by plating a serial dilution of supernatants from P 0 onto 60-mm dishes of DBT cells and then adding an agar overlay to prevent diffusion of the virus into the medium. 3. When the cells are confluent, remove the medium. Dilute the supernatant from P 0 using dilutions of one part P 0 supernatant to nine parts PBS, ranging from 10 -1 to 10 -7 dilutions. 4. Add 200 l of the appropriate dilution onto a 60-mm plate of DBT cells and spread evenly by mixing back and forth every 15 min, while incubating at room temperature for 1 h. This is passage one (P 1 ). 5. Prepare the overlay ahead of time. Make enough to aliquot 5 ml of overlay onto each plate. For 100 ml: a. Autoclave 49 ml sterile water and 0.8 g of LE agar (low-melt) and incubate in a water bath at 55 • C for 15 min. b. Add 40 ml 2X medium heated to 37 • C. c. Add 10 ml FCII or FBS heated to 37 • C. d. Add 1 ml of Gen/Kan heated to 37 • C. 6. Carefully add 5 ml of overlay onto each plate. This must be accomplished at close to 40 • -42 • C as the medium rapidly solidifies below these temperatures and higher temperatures will adversely affect cell viability. Allow the plates to incubate 24-48 h at 37 • C. 7. Plaques for ic MHV resemble wt MHV (Fig. 4A) , whereas mutant plaques can vary greatly (Fig. 4B) . Select five plaques for each virus. For each plaque to be picked: use sterile technique to cut ∼ 1 / 3 in. off the end of a P1000 barrier tip, place the tip over the plaque, and push it through the agar, making sure that the surface of the plate and the agar are both manipulated so as to ensure that the entire plaque is extracted without any neighboring plaques. Place the picked medium into 300 l PBS and incubate at 4 • C for 30 min. 8. The 300 l containing the plaque and PBS is then used to infect a 60-mm plate of DBT cells, brought up as described above. To infect cells, remove the medium and pipette all 300 l of the plaque and PBS onto a 60-mm plate of DBT cells, spread evenly by mixing back and forth every 10-15 min, and incubate at room temperature for 1 h. Then add 4 ml of medium to each plate. This is passage 2 (P 2 ). Allow the infections to proceed at 37 • C until CPE is obvious (usually 24-36 h). We typically only plaque purifiy recombinant viruses 1X as additional passages increase the probability of second-site mutations or reversions (see Note 7). 9. Remove the medium from the 60-mm dishes, centrifuge at ∼3000 × g for 10 min at room temperature and aliquot the supernatant into 1.5-ml microfuge tubes labeled P 2 . 10. Resuspend the cells in 1 ml of Trizol reagents and dispense them into a 1.5-ml microfuge tube for isolation of total RNA. a. All steps are performed at room temperature. Start by thawing the frozen cells in Trizol and allowing them to sit at room temperature for 5 min. b. Add 200 l chloroform and shake by hand for 15 sec. c. Spin at 12,000 × g for 15 min. d. Remove aqueous phase to a fresh tube. e. Add 500 l of isopropanol and incubate for 10 min. f. Spin at 12,000 × g for 10 min. g. Remove supernatants and resuspend the pellet in 1 ml of 75% ethanol diluted in DepC water. h. Spin at 7500 × g for 5 min. i. Remove ethanol and air-dry the pellet for 5-10 min. j. Dissolve the pellet 100 l of DepC water heated to 70 • C and incubate at 55 • C for 10 min. 3. Amplify the region of interest with a 50 l PCR reaction appropriate for the size and composition of the cDNA target. 4. Isolate the DNA from PCR following the same procedures as described in Section 3.2, steps 5-7.i modifying the recipes for the 50-l reaction size. 5. Once isolated, clone the target into a vector of choice. We use pCR-XL-Topo, following the manufacturer's recommended protocol. 6. Transform, grow-up, and screen as described in Section 3.1. Screen by restriction digestion with EcoRI, and sequence clones that are of the appropriate size to verify genotype. The vector sequence, the wild-type fragment, and the mutated fragment are analyzed to determine which type IIs restriction enzymes do not cut any of them, and one of these is selected as the restriction site to add. In this case BbsI is selected. (B) Primers are designed that add the mutation and the restriction site in proper orientation so that upon digestion the restriction site is eliminated and complementing sticky ends are produced. The BbsI cut sites are highlighted in gray. The mutated codon is bold and underlined. (C) PCR is conducted using vector specific 3. Select one of the noncutters to add onto the end of each fragment. In Figs. 1C and 5, we selected a glutamate codon at position 13354-56 (CAG) and changed it to an alanine (GTC). To stabilize the mutation against reversion to the wt genotype, we generally alter the codon at multiple positions. This mutation maps to MHV-E A B C Fig. 5 . (Continued) primers along with the newly designed primers that incorporate the mutation of interest to produce two amplicons. These are cloned and purified, and then digested with BbsI and BsmBI to produce a mutated MHV-E fragment that can then be incorporated into the full-length clone. as the fragment target, and enzyme BbsI does not cut the sequence or the pCR-XL-Topo vector. 4 . Design primers that incorporate the mutation into the target fragment utilizing the nonspecific site of the restriction cut site to engineer a junction oriented such that upon cleavage the restriction site is removed and complementing sticky ends remain (Fig. 5) . 5. Amplify both fragments by PCR using the newly designed primers along with vector-specific sequencing primers and reaction conditions appropriate for the size of each target. For MHV-E fragment in pCR-XL-Topo M13F and M13R are used. Run PCR reactions on a gel, extract and purify amplicons of the correct size, clone into pCR-XL-Topo (or another vector of choice), transform, pick colonies and grow larger cultures, screen by restriction digestion, and sequence verify each amplicon (as described above). 6. Digest each amplicon using the appropriate reaction conditions and enzymes. In the case of MHV-E in Fig. 5 , we amplified with vector primers M13R and M13F, which ensured that the BsmBI sites were preserved at both ends of the fragment, so each amplicon has a BsmBI site and a newly engineered BbsI site. These amplicons are digested first with BbsI and NEB buffer 2 for 1.5 h at 37 • C, followed by digestion with BsmBI at 55 • C for 2 h. In addition, we digested wild-type MHV-E with just BsmBI, and purified the vector band (the smaller of the two). All of these digests are purified as described above. 7. With this strategy, both amplicons and the vector are ligated in a single ligation reaction: a. 11 l of each purified band (amplicon 1, amplicon 2, vector). b. 4 l ligation buffer. c. 3 l ligase. d. Incubate at 4 • C overnight. 8. Transform 5 l of the ligation, plate, pick colonies and grow larger cultures, screen by restriction digestion, and sequence verify each amplicon. 9. Build MHV virus using the newly mutated cDNA. even very low levels of cross-contamination of fragments will result in wild-type MHV out-competing any mutant. 5. For best results use BHK-MHVr cells at or below 80% confluency. 6. Clone stability is enhanced by growing everything at room temperature. 7. Avoid passage of highly attenuated mutant viruses because reversions to wild-type and second-site reversions occur rapidly upon passage. Well over a hundred mutants have been engineered into the clone of MHV using this approach, which far exceeds the number for all other coronavirus reverse genetic systems reported. Moreover, this technology has been used to rapidly develop reagents in response to newly identified emerging coronaviruses. For example, SARS-CoV was identified in the fall of 2002, and a full-length infectious clone was available the summer of 2003 (16). Piecemeal assembly of smaller subclones is within range of commercial DNA synthesis companies, allowing for synthetic reconstruction of coronavirus genomes. However, attempts to reconstruct other coronavirus genomes using this method have proven more difficult. Current problem areas that must be solved for the advancement of this technology include: (a) unreliable sequence information in the public databases; (b) mistake-prone amplification and cloning of AT-rich genomes (such as in human coronavirus NL63); (c) clone stability and sequence toxicity issues with different viruses; (d) size issues of the different fragments for different viruses; and (e) cell tropism issues with newly identified animal viruses (Bat CoV). Once an infectious clone is established for a virus, rapid production of candidate vaccine strains (17-19) and vectors for therapeutic gene delivery in animals and humans (20) is possible. Attenuating mutations can be identified, combinations can be engineered into the infectious clone, and recombinant viruses can be generated and tested. In SARS-CoV, this approach has identified zoonotic candidate vaccine strains (17,18) and a novel strategy for preventing recombination between wild-type and recombinant viruses by rewiring the viral communication network (19) . This strategy provides a recombination safe vaccine platform that will likely redefine coronavirus vaccinology. A tremendous amount of creativity in the coronavirus field has resulted in four independent and unique reverse genetic systems for a single virus family (11,13,14,21,22) , all of which have helped pave the way for the emergence of the golden age of coronavirus genetics. We anticipate the discovery and genetic analysis of a large number of unique genetic functions in the coronavirus genome, and expect that these discoveries will translate to a better understanding of coronavirus replication, transcription, assembly, and mechanisms of pathogenesis of these important human and animal pathogens. MHV N-gene amplified with SP6 promoter on the 5 -end is used as a template for generating N-gene transcripts Transfecting in parallel with N-gene increases viral replication by roughly 15-fold 1340) for generating full-length MHV RNA or SP6-N-gene RNA One 0.4-cm Gene Pulser Cuvette BHK-MHVr cells are seeded at low density and grown in 150-cm 2 flasks to 70% confluence, washed three times in nuclease-free PBS, and resuspended in cold PBS at a concentration of 1.0 × 10 7 cells/ml, and ∼5 × 10 6 DBT cells are infected by plating the electroporated BHK-MHVrs on top. We see greatly reduced transfection efficiencies if cells are allowed to Gene Pulser Excel electroporator for doing the transfection Harvesting Viral RNA, and RT-PCR 1. 2X DMEM medium (Gibco) Fetal Clone II (Hyclone) or fetal bovine serum (Gibco) Low-melting-temperature cell culture grade agarose Phosphate buffered saline (Gibco) Trizol reagents (Invitrogen, Carlsbad, CA) for harvesting total RNA from infected cells PCR/sequencing primers flanking the region of the mutation SuperScript III Reverse Transcription kit (Invitrogen; cat. no. 18080-044) for reverse transcription of viral RNA to cDNA K4500) for cloning the amplicon for sequencing MHV genomic sequence (Accession no. NC 001846) for designing primers ) for analyzing sequences to ensure that the type IIs restriction site selected does not occur naturally in the wild-type sequence and is not introduced by the mutation primer) for development of primers for engineering mutations and for sequencing to verify that the correct change was incorporated into the virus Always do a chloroform-only extraction of the viral fragments after digestion as impurities left behind by the extraction kit can interfere with the DNA ligase Always use PBS prepared in DepC water for washing cells. This reduces the opportunity for RNAses in the medium to degrade the full-length viral transcript prior to electroporation Always use barrier tips for pipetting, particularly when working with wild-type MHV along side a mutant Run digestions of wild-type fragment and mutant fragment on different gels with new running buffer each time. Wild-type MHV is so efficient at replication that References The molecular biology of coronaviruses Adv The molecular biology of coronaviruses Adv Four proteins processed from the replicase gene polyprotein of mouse hepatitis virus colocalize in the cell periphery and adjacent to sites of virion assembly Characterization of the expression, intracellular localization, and replication complex association of the putative mouse hepatitis virus RNA-dependent RNA polymerase Processing of the MHV-A59 gene 1 polyprotein by the 3C-like proteinase Processing of the coronavirus MHV-JHM polymerase polyprotein: identification of precursors and proteolytic products spanning 400 kilodaltons of MHV subgenomic negative strand function Coronavirus minus-strand RNA synthesis and effect of cycloheximide on coronavirus RNA synthesis Coronavirus transcription: subgenomic mouse hepatitis virus replicative intermediates function in RNA synthesis Coronavirus subgenomic minusstrand RNAs and the potential for mRNA replicons Proc Retargeting of coronavirus by substitution of the spike glycoprotein ectodomain: crossing the host cell species barrier The murine coronavirus mouse hepatitis virus strain A59 from persistently infected murine cells exhibits an extended host range Systematic assembly of a full-length infectious cDNA of mouse hepatitis virus strain A59 Strategy for systematic assembly of large RNA and DNA genomes: transmissible gastroenteritis virus model Molecular Cloning: A Laboratory Manual Reverse genetics with a full-length infectious cDNA of severe acute respiratory syndrome coronavirus Proc SARS coronavirus vaccine development Vaccine efficacy in senescent mice challenged with recombinant SARS-CoV bearing epidemic and zoonotic spike variants Rewiring the severe acute respiratory syndrome coronavirus (SARS-CoV) transcription circuit: engineering a recombination-resistant genome Proc Severe acute respiratory syndrome coronavirus groupspecific open reading frames encode nonessential functions for replication in cell cultures and mice Engineering the largest RNA virus genome as an infectious bacterial artificial chromosome Proc Infectious RNA transcribed in vitro from a cDNA copy of the human coronavirus genome cloned in vaccinia virus We are grateful to Boyd Yount, who developed this protocol and has taught many of us how to use it.