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View additional product information for Bac-to-Bac™ HBM TOPO™ Cloning Kit - FAQs (A11338)
67 product FAQs found
The concentration of gentamicin might be too high. Try lowering the amount to 5 µg/mL and try adding more of the colony to the culture medium.
In the case of a blue colony, the E. coli has the bacmid and the plasmid in it, allowing the cells to survive the selection process. However, because the transposition has not occurred, the LacZ gene is not disrupted. For bulls-eye colonies, this indicates that the transposition took place when the colony was growing. Re-streaking for an isolated clone from the white portion of the mixed colony should yield some colonies where transposition occurred.
This is typically an indication of poor homologous recombination. Check the plasmid/linear DNA ratio you used. If there are some blue plaques, however, expand those viruses and check for their protein. In our experience, they are correct, even if they were in relatively low abundance.
Yes, cells are infected with wild-type virus individually and will develop polyhedra at different rates until all the cells in the flask are infected. The polyhedra in cells will form in approximately 3-4 days, differing in size and number until they reach their maximum capacity and burst the cell, releasing tiny particles of virus into the medium.
Normally, very small white dots show up about 5-7 days and 1 mm plaques show up around day 10. Plaques can vary in size from 1 mm to 4 mm.
On the day you intend to pick plaques, make a solution of Bluo-gal in DMSO at 20 mg/mL. Add 50 µL per plate and spread with a glass spreader under sterile conditions. Wait 30-60 min, and your plaques should turn blue.
There are a few things that can turn plates blue:
- Too much virus when plating. Try a higher dilution.
- Cells are being singed when plated with hot melted agarose. This lyses the cells and releases lacZ into the agarose, turning it blue. Double-check plating temperatures. If plates are too wet, the blue can diffuse.
The agarose overlay was too hot. After addition of the agarose overlay, cells should still be round and healthy.
Yes, this is indicative of an aspirating problem on the plaques. The agarose overlays were “floating” because the medium was not completely aspirated from the plates. The plates need to be completely dry before the agarose is placed over the cells, especially when plaques will be picked. To do this, we typically tip the plate slightly and keep going around the rim of the plate with the Pasteur pipette tip, being careful not to disturb the cell monolayer. If any medium pooling at the rims of the plates (they will be small pools) is seen, continue to aspirate. This “floating” agarose overlay problem may also result in wild-type contamination. The wild-type virus is able to migrate to other portions of the plates and contaminate recombinant plaques. Wild-type virus replicates much faster than recombinant virus, and can quickly overwhelm the recombinant virus.
Too many cells were seeded; we recommend seeding 8 x 10e5 cells per well for a 6-well plate.
An MOI of 5-10 is typically used. If too much virus is added, unfortunately the cells die too soon and the protein expression level goes down.
The kinetics of infection may be slower than expected. Observe plates until the 8-9th day after infection. If no plaques appear, investigate the following:
- If the cells are not healthy, then poor-quality or no plaques can result. Ideally, cells should be in mid-log phase and have a viability of greater than 90%. Cells should double at least once before infection stops growth. Ensure that the correct amount of cells was used at ~70% confluency.
- The viral replication cycle can be inhibited due to poor nutritional and physical conditions of the cell.
- The temperature of the agarose is also crucial. After overlaying the agarose, the plates should be left untouched for 1 hour for the agarose to completely solidify.
- Excessive condensation during incubation at 27 degrees C can inhibit plaque formation-remove paper towels or open the container containing plates as soon as condensation appears.
- The viral titer is too low: Use a higher viral titer. You may need to re-infect your cells and collect a higher titer of your viral stock.
Please check the construction of your entry clone, and ensure that the insert is in frame with the vector. Analyze the recombinant viral DNA by PCR to confirm the correct size and orientation of your insert after the LR reaction. Sequence your PCR product to verify the proper reading frame for expression of the epitope tag.
Find additional tips, troubleshooting help, and resources within our Protein Expression Support Center.
To get a high-titer stock, reinfect cells with the P1 stock and generate a P2 high-titer stock. Follow the directions in the BaculoDirect manual on page 18 to generate your P2 stock.
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Please see our recommendations below:
- Check the LR reaction by PCR analysis prior to transfection into insect cells.
- We recommend using Grace's Insect Cell Culture Medium, Unsupplemented during the transfection experiment instead of serum-free medium, as components in serum-free medium may interfere with transfection.
- Ensure that FBS, supplements, or antibiotics are not included during transfection, as the proteins in these materials can interfere with the Cellfectin II Reagent.
- Use the LR recombination reaction using the pENTR/CAT plasmid as a positive control and Cellfectin II Reagent only (mock transfection) as a negative control.
- Ensure that cells are in the log phase of growth with >95% viability, and the amount of cells are in accordance with the suggestions in the manual.
- Cells may not show signs of viral infection for up to a week depending on transfection efficiency; continue culturing and monitor cells daily for signs of infection.
Warm the ganciclovir solution in a water bath at 37 degrees C for 5-10 min, then vortex for a few minutes. The precipitate should go back into solution.
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Media used to culture insect cells usually have an acidic pH (6.0-6.5) or contain electron-donating groups that can prevent binding of the 6xHis-tagged protein to Ni-NTA. Amino acids such as glutamine, glycine, or histidine are present at significantly higher concentrations in media for growing insect cells than in media for growing mammalian cells, and compete with the 6xHis-tagged protein for binding sites on Ni-NTA matrices. Grace's medium (Thermo Fisher Scientific), for example, contains approximately 10 mM glutamine, 10 mM glycine, and 15 mM histidine.
Dialysis of the medium against a buffer with the appropriate composition and pH (8.0) similar to the lysis buffer recommended for purification under native conditions usually restores optimal binding conditions. Note that depending on the medium used, a white precipitate (probably made up of insoluble salts) can occur, but normally the 6xHis-tagged protein remains in solution. This can be tested by either protein quantitation if using a protein-free medium or by monitoring the amount of 6xHis-tagged protein by western-blot analysis. After centrifugation, 6xHis-tagged protein can be directly purified from the cleared supernatant.
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Please review the following possibilities and solutions:
- Viral stock was amplified using high MOI originally: Go back to the lower-passage viral stock and do a low-MOI amplification.
- Did not spin down and get rid of cells when harvesting viral supernatant: Go back to the lower-passage viral stock and do a low-MOI amplification; if this viral stock is P2, this stock can be used in amplification.
- For some genes, the virus can become very unstable: Free the aliquoted P2 viral stock and do one run of amplification after reviving.
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Low protein yield may occur due to the following reasons:
- Viral stock contains a mixture of recombinant and non-recombinant baculovirus: Perform plaque purification to isolate recombinant baculovirus.
- Baculovirus is not recombinant: Verify transposition by PCR analysis of bacmid DNA using pUC/M13 forward and reverse primers; re-transfect insect cells with new recombinant bacmid DNA.
- Use too low or too high viral titer: Vary the MOI.
- Time of cell harvest is not optimal: perform a time course of expression to determine the optimal time to obtain maximal protein expression.
- Cell growth conditions and medium are not optimal: Optimize cell culture conditions based on the size of your culture vessel and expression conditions; we recommend using Sf-900 II SFM or Sf-900 III SFM for optimal cell growth and protein expression.
- Cell line is not optimal; try other insect cell lines.
- Cells were harvested too late: Do a time-course experiment and harvest cells at different time points.
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Check the MOI. It may be low because the titer of the P1 virus is lower than what was estimated.
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Please see the possible reasons and suggestions below:
- Mixture of Cellfectin II Reagent and bacmid was not performed or was not incubated long enough: Mix the Cellfectin II Reagent and bacmid well by tapping or gentle vortexing, and incubate the mixture for 15-45 min.
- Bacmid yield is lower than estimated: Set up an optimization with different amounts of bacmid.
- Bacmid is sheared during purification or freeze/thaw: Verify the integrity of bacmid on a gel.
- Incubation time is not long enough: Incubate mix for 8 hr at 27 degrees C.
- Cells used are of high passages or have passed log-phase growth: For best results, use cells between 8-15 passages; plate cells when they are in log-phase growth.
- Cellfectin II Reagent has been frozen: Purchase a new vial.
- Medium used contains serum: Use unsupplemented Grace's medium in transfection.
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There are several possibilities:
- Using media containing antibiotics during transfections.
- Plating cells at too low a density: We recommend at least 70% confluence.
- Using cells at too early a passage: We recommend growing cells for at least 5 passages before using them for transfection.
- Contamination because of no pen/strep after the transfection: After 5-8 hr incubation with the transfection mixture, remove the mixture and add antibiotics containing media/well.
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This may be due to contamination or cytotoxicity from the bacmid prep. Make sure to include a negative control that is the bacmid only without Cellfectin II Reagent. Additionally, use the PureLink HiPure plasmid prep kit, not the silica-based miniprep kit for bacmid prep.
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Most likely, a colony that was gray or dark in the center was picked. Try to analyze more white DH10Bac transformants. Typically, we recommend picking a white colony whose diameter is >2 mm. Restreak the white colonies on a fresh plate with 50 µg/mL kanamycin, 7 µg/mL gentamicin, 10 µg/mL tetracycline, 100 µg/mL Bluo-gal and 40 µg/mL IPTG. Incubate plates for 24 hours.
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Please see the possible causes and suggestions we have to alleviate this problem:
- Insert is very long and causes difficulties in PCR: Instead of using both M13 forward and reverse primers, use one gene-specific primer paired with the M13 primer of your choice.
- Long GC-rich stretches in the gene of interest: Consider using DMSO (up to 8%) in the PCR reaction.
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Please see the possible reasons and suggestions below:
- DNA stored improperly: Ensure that purified bacmid DNA is stored at -20 degrees C in aliquots to avoid repeated free/thaws.
- High molecular weight bacmid DNA handled improperly: When isolating bacmid DNA, do not vortex the DNA solution; additionally, do not resuspend DNA pellets mechanically; allow solution to sit in the tube with occasional tapping.
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This could be caused by the following:
- Wrong antibiotic or old media: use fresh media.
- Colonies are too old or too small: Use large white colonies from freshly streaked plates.
- Unstable insert caused by special feature of the gene of interest; for example, direct repeats: Incubate the culture at 30 degrees C for 24 hours instead of 37 degrees C overnight.
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Poor color differentiation for your colonies could be caused by the following:
- Agar is not at the correct pH: Adjust pH of LB agar to 7.0.
- Intensity of the blue color is too weak; ensure that you are using Bluo-gal, not X-Gal. You can also try increasing the concentration of Bluo-gal to 300 µg/mL.
- Too many or too few colonies on the plate: Adjust the serial dilutions of cells to obtain an optimal number of colonies.
- Incubation period too short or temperature too low: Do not pick colonies until 48 hours after plating; incubate plates at 37 degrees C.
- IPTG concentration is not optimal: A range of 20-60 µg/mL IPTG generally gives optimal color development.
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We recommend running 1/8th of the 40 µL midiprep sample on a 0.5% TAE agarose gel. Electrophorese slowly at 23 V for 12 hr. The banding pattern of the recombinant bacmid midiprep should be seen.
Please review the following reasons and our recommendations:
- Use LB medium for recovery/expression period: Use SOC medium for the 4 hr growth time.
- Recovery/expression time too short: Increase the recovery time to > 4 hr at 37 degrees C or 6 hr at 30 degrees C.
- IPTG concentration is not optimal: We suggest using 20-40 µg/mL IPTG.
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Please review the following possibilities and recommendations:
- pFastBac DNA used for transformation was of poor quality: Use purified plasmid DNA for transformation and check the quality of your plasmid DNA.
- Gentamicin omitted from plates: Prepare fresh selective plates containing 50 µg/mL kanamycin, 7 µg/mL gentamicin, 10 µg/mL tetracycline, 100 µg/mL Bluo-gal, and 40 µg/mL IPTG.
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Although you will be picking white (recombinant) colonies, you should expect to see some blue (contain non-recombinant bacmid) colonies. Here are some possible causes for seeing no blue colonies and recommendations for the same:
- Insufficient time for color development: Wait at least 48 hours before identifying colony phenotypes.
- Use Bluo-gal instead of X-Gal in agar plates: Use Bluo-gal in plates to increase contrast between blue and white colonies.
- Insufficient growth after transposition: Grow transformed cells in SOC medium for a minimum of 4 hours before plating.
- Bluo-gal and IPTG omitted from plates: Prepare fresh selective plates containing 50 µg/mL kanamycin, 7 µg/mL gentamicin, 10 µg/mL tetracycline, 100 µg/mL Bluo-gal, and 40 µg/mL IPTG.
- There are too many colonies on the plate: Serially dilute the transformation mix to obtain well-spaced colonies (10-2 to 10-4 is suggested).
- Plates are too old or stored in light: Do not use plates that are more than 4 weeks old; store plates protected from light.
- Incubation period too short or temperature is too low: Wait at least 48 hours before picking colonies. Incubate plates at 37 degrees C.
Find additional tips, troubleshooting help, and resources within our Protein Expression Support Center.
If this lower-titer stock is a P1 or P2 stock, a viral amplification protocol can be used. If the low-titer stock was once a high-titer stock, but has dropped titer due to age or the stock was propagated many generations, then it may be necessary to regenerate the high-titer stock. If the high titer stock is >P5, then there may be an excessive amount of defective interfering particles that infect cells but do not properly replicate or produce protein. If the existing stock is plated out and a fresh plaque is re-isolated (DIPs do not form plaques), a new high-titer stock can be established.
Yes, the same protocol used to make your P2 viral stock can be used to make a P3, P4, or P5 viral stock. We don't recommend making the stock higher than P5, as more defective interfering particles will be produced and a decrease in protein expression level will occur.
Yes, baculovirus can infect mammalian cells, although only at very high titers. Baculovirus works best in liver cells. However, there is no danger of cross-contamination unless the cells are directly infected with the high-titer stocks. Bacuolvirus can infect Drosophila cells; however, it will not replicate in these cells. The promoters used to drive expression of your gene in a typical baculovirus system are both late promoters and require earlier proteins from the baculovirus genome. Thus, they will not work in S2 cells since the early proteins are not made.
Typically, 0.5 x 106 cells per well in 2.5-3 mL is a good starting point. Lysis should begin by day 3. Virus may be harvested and amplified between 3 and 7 days (90% cell death).
Our R&D team will typically pick a plug and add it to a 12-well dish with 0.5 x 10e6 cells/well and 2.5 mL total volume per well. After approximately 3 days, remove 0.75 mL to make DNA for PCR and keep the remaining medium in an Eppendorf tube as your P1 viral stock. As an aside, it is okay to pick a plaque and store it in Grace's medium.
We recommend harvesting high-titer virus when there is 90% cell lysis. This takes approximately 5-7 days. If the cells go longer, the proteases released from the lysed cells will start to degrade viral surface proteins and result in less infectious virus.
This is dependent on how much virus is added. If cells are infected at an MOI of 5, usually cells are infected at 24 hours, and cells begin to lyse at around 65 hours. If less virus is used, this takes longer, and more virus takes less time.
When propagating virus stock, use a low MOI (0.03-0.1) in order to avoid effects of defective interfering particles (DIPs). A low MOI, which ensures no more than 1 virion per cell, prevents the amplification of DIPs. A harvest time based on 15% cell viability is appropriate. NOTE: DIPs are nearly normal virus capsids containing genomes that are defective and are unable to undergo successful replication. While this "particle" is not infectious by itself, it can replicate when co-infected with normal virion, or with some other types of DI particles.
You can stain the monolayer with neutral red or MTT to make the plaques more visible. Alternatively, you can allow the plates to develop for a few days longer (2-5 days on average) at room temperature to increase the contrast in recombinant plaques. However, the plaques stained with neutral red cannot be used for plaque purification and viral amplification.
We suggest using a viral stock with a titer of >1 x 10e8 pfu/mL for expression studies.
Please see the equation below:
pfu/mL = number of plaques (pfu)/dilution factor x mL of inocula
So, if you have a well with viral dilution of 10-8 containing 18 white plaques, the viral titer is calculated as followed:
X pfu/mL = 18 pfu/10-8 x 1 mL
X = 1.8 x 10e9 pfu/mL
Please see the method below for an outline of the main steps of performing a plaque assay:
- Plate cells at 80% confluency in a 6-well plate
- Make a serial dilution of the P1 viral stock (1-10-5) and add to cells
- Incubate for an hour at 27 degrees C
- Mix 1% melted agarose into the medium
- Remove the viral supernatant
- Overlay the cells with the medium containing agarose
- Leave the plates for 2-3 hours for agar to completely solidify
- Incubate plates for 10-14 days
- Count plaques
When performing this assay, we suggest:
- Use cells that are in excellent health, of low passage (10-20) in log-phase growth, and high viability (>95%)
- Check viral stock for sterility (free of contamination)
- Use high-quality, low melting point agarose
- The temperature of the medium with agarose is crucial-too hot, cells will die; but if too cold, it will solidify too quickly
- Wait 2-4 hours before removing the plate after overlay so that the agarose can 100% solidify
- Count plaques on a dilution plate where (1/dilution) x # of plaques = pfu/mL
e.g., if you have 50 plaques on the 10-6 plate, then you have 1(10-6) x 50 = 5 x 10e7 pfu/mL
We recommend you perform a plaque assay to determine the titer of your viral stock. You may also perform a plaque assay to purify a single viral clone, if desired.
In the Bac-N-Blue system, recombination between the transfer vector and the baculovirus DNA occurs in insect cells. The Bac-N-Blue vector is a linearized AcMNPV derivative that contains an incomplete (3') lacZ fragment. The corresponding transfer vector contains a 5' lacZ fragment. Upon homologous recombination, the recombinant Bac-N-Blue baculovirus DNA will have a complete lacZ gene that is under the control of the PETL promoter. Thus, recombinant Bac-N-Blue baculovirus will provide blue plaques in the plaque assay and can be easily identified. In the Bac-to-Bac expression system, recombination or site-specific transposition between transfer and baculovirus DNA occurs in E. coli (DH10Bac). In the Bac-to-Bac expression system, selection of colonies containing recombinant baculovirus DNA occurs in the presence of Luria Agar plates with 50 µg/mL kanamycin (bacmid), 7 µg/mL gentamycin (pFastBac), 10 µg/mL tetracycline (helper plasmid), 100 µg/mL Bluo-gal, and 40 µg/mL IPTG.
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The following is an excellent reference for how to prevent proteolytic artifacts in the baculovirus expression system:
Hom LG, Volkman LE (1998) Preventing proteolytic artifacts in the Baculovirus expression system. BioTechniques 25:18-20.
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The baculovirus rod will continue to elongate as required to package the DNA. Thus, the system could theoretically accommodate hundreds of Kb. Standard cloning techniques will limit the insert size before packaging limits become an issue.
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Insect-derived signal peptides and/or prosequences cannot always enhance the expression and/or secretion of foreign secretory pathway proteins in the baculovirus system. Please see the following references:
- Jarvis DL, Summers MD, Garcia A Jr, Bohlmeyer DA (1993) Influence of different signal peptides and prosequences on expression and secretion of human tissue plasminogen activator in the baculovirus system. J Biol Chem 268(22):16754-16762.
- Tessier DC, Thomas DY, Khouri HE, Laliberte F, Vernet T (1991) Secretion of a plant protein in the baculovirus system was enhanced when its signal peptide was replaced with an insect-derived signal peptide. Gene (Amst.) 98:177-183.
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Our R&D team has successfully expressed proteins up to 300 kDa. If they express in >2% serum, it should minimize degradation. If you don't mind the extra step of purification, 10% serum could be used. We highly recommend doing a time-course infection with high-titer stock, with a MOI of 5-10, to make an assessment of the minimum harvesting time necessary for the best expression. Time points should be taken every 24 hours for 5 days.
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The polyhedron protein is 30 kDa.
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The promoter that drives the gene of interest is the polyhedron promoter.
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While the importance of a Kozak consensus sequence in translation initiation has been demonstrated in mammalian cells, there seems to be some debate as to whether the Kozak rules are as stringent in insect cells. The only way to determine its importance would be a direct comparison of expression of the same protein from different initiation sequences. Even then, the rules for optimal expression of one protein may not hold for another. Here are two references which indicate that a Kozak consensus sequence does not have any effect on efficiency of expression in insect cells:
- Hills D, Crane-Robinson C (1995) Baculovirus expression of human basic fibroblast growth factor from a synthetic gene: role of the Kozak consensus and comparison with bacterial expression.
- Biochim Biophys Acta 1260(1):14-20.
- Ranjan A, Hasnain SE (1995) Influence of codon usage and translational initiation codon context in the AcNPV-based expression system: computer analysis using homologous and heterologous genes. Virus Genes 9(2):149-153.
Yes, it is possible. Several five-subunit proteins, such as human replication factor C, have been expressed using recombinant baculovirus. We recommend that a separate high-titer stock (HTS) of each subunit be produced to optimally express the multi-subunit protein. This way, the amount of each subunit expressed can be controlled by varying the multiplicity of infection (MOI) of each subunit's HTS. Please refer to the following articles for more information:
- Chen W and Bhal OP (1991) Recombinant carbohydrate and selnomethionyl variants of human choriogonadotropin. J Biol Chem 266(13):8192-8197.
- Chen WY and Bhal OP (1991) Selenomethionyl analog of recombinant human choriogonadotropin. J Biol Chem 266(15):9355-9358.
- Fabian JR, Kimball SR, Jefferson LS (1998) Reconstitution and purification of eukaryotic initiation factor 2B (eIF2B) expressed in Sf21 insect cells. Protein Expr Purif 13(1):16-22.
The MOI, or multiplicity of infection, is the average number of viral particles that infect a single cell in a specific experiment. You can calculate the MOI with the following equation:
MOI (pfu/cell) = [titer (pfu) x viral stock volume (mL) used in inocula] / [cell density (cells/mL) x culture volume (mL)]
Yes, large-scale expression experiments can be performed. Please see below for different large-scale methods, requirements, added benefits, and references:
- Stirred bioreactor
- Airlift fermentor
- Insect larvae
If the medium is serum-free, add serum to 10%. Serum proteins act as substrates for proteases and therefore prevent degradation of viral coat proteins. Store viral stocks at 4 degrees C, and protect from light. Aliquots can be stored at -80 degrees C, but viral titer should be checked before use, as freeze/thaw cycles of the virus can result in a 10- to 100-fold decrease in viral titer.
Yes. Contamination of your recombinant DNA with uncut occlusion body positive (occ+) DNA will lead to dilution of your recombinant virus over time because, in general, uncut (wild-type, occ+) virus infects and replicates at higher efficiency than recombinant virus. Also, initiating expression studies with a pure, single virus population will ensure reproducible results.
Please see the description below of the different stages of viral infection:
Early
- Increased cell diameter-a 25-50% increase in the diameter of the cells may be observed.
- Increased size of cell nuclei-the nuclei may appear to "fill" the cells.
Late
- Cessation of cell growth-cells appear to stop growing when compared to a cell-only control.
- Granular appearance
- Signs of viral budding-vesicular appearance of cells.
- Viral occlusions-few cells will contain occlusion bodies, which appear as refractive crystals in the nucleus of the insect cell.
- Detachment-cells release from the dish or flask.
Very late
- Cell lysis-a few cells may fill with occluded virus, die, and burst, leaving signs of clearing in the monolayer.
Yes, we offer our Bac-to-Bac HBM TOPO Secreted Expression System (Cat. No. A11338 or A11339), which uses the honeybee melittin (HBM) secretion signal.
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Adherent Sf9 cells round up and show a smaller contact point. Infected Sf9 cells in suspension culture round up and look larger when infected.
Please follow the recommendations below:
- Cells should be in excellent health, of their low passages (5-15), in log-phase growth, with viability >95%
- DNA must be of high purity, free of endotoxin
- No antibiotics should be used during transfection
- Cellfectin reagent has to be completely resuspended
- Include controls (media control, DNA control, and transfection reagent control) for comparison and troubleshooting
Peak expression of protein in insect cells is dependent on the multiplicity of infection (MOI), expression time, and the protein being expressed. Guidelines to optimize your system include using an MOI of 5-10 and an expression time of 48-72 hours. Protein expressed at times later than 72 hours may be processed aberrantly, because the large virus load can cause a breakdown of cellular processes.
Yes, baculovirus is a good candidate for the problem of expressing toxic proteins (i.e., membrane proteins). The polyhedron promoter does not express at maximal levels until 18-24 hr after infection. The polyhedron promoter is active late in the lytic cycle. That being said, it is minimally active as early as 8 hours, so if the gene is very toxic, there may be a problem. The solution in that case would be to switch to an inducible expression system. Transmembrane proteins can often be difficult to express in any system.
ATG is often sufficient for efficient translation initiation although it depends upon the gene of interest. The best advice is to keep the native start site found in the cDNA unless one knows that it is not functionally ideal. If concerned about expression, it is advisable to test two constructs, one with the native start site and the other with a Shine Dalgarno sequence/RBS or consensus Kozak sequence (ACCAUGG), as the case may be. In general, all expression vectors that have an N-terminal fusion will already have a RBS or initiation site for translation.
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Prokaryotic mRNAs contain a Shine-Dalgarno sequence, also known as a ribosome binding site (RBS), which is composed of the polypurine sequence AGGAGG located just 5’ of the AUG initiation codon. This sequence allows the message to bind efficiently to the ribosome due to its complementarity with the 3’-end of the 16S rRNA. Similarly, eukaryotic (and specifically mammalian) mRNA also contains sequence information important for efficient translation. However, this sequence, termed a Kozak sequence, is not a true ribosome binding site, but rather a translation initiation enhancer. The Kozak consensus sequence is ACCAUGG, where AUG is the initiation codon. A purine (A/G) in position -3 has a dominant effect; with a pyrimidine (C/T) in position -3, translation becomes more sensitive to changes in positions -1, -2, and +4. Expression levels can be reduced up to 95% when the -3 position is changed from a purine to pyrimidine. The +4 position has less influence on expression levels where approximately 50% reduction is seen. See the following references:
- Kozak, M. (1986) Point mutations define a sequence flanking the AUG initiator codon that modulates translation by eukaryotic ribosomes. Cell 44, 283-292.
- Kozak, M. (1987) At least six nucleotides preceding the AUG initiator codon enhance translation in mammalian cells. J. Mol. Biol. 196, 947-950.
- Kozak, M. (1987) An analysis of 5´-noncoding sequences from 699 vertebrate messenger RNAs. Nucleic Acids Res. 15, 8125-8148.
- Kozak, M. (1989) The scanning model for translation: An update. J. Cell Biol. 108, 229-241.
- Kozak, M. (1990) Evaluation of the fidelity of initiation of translation in reticulocyte lysates from commercial sources. Nucleic Acids Res. 18, 2828.
Note: The optimal Kozak sequence for Drosophila differs slightly, and yeast do not follow this rule at all. See the following references:
- Romanos, M.A., Scorer, C.A., Clare, J.J. (1992) Foreign gene expression in yeast: a review. Yeast 8, 423-488.
- Cavaneer, D.R. (1987) Comparison of the consensus sequence flanking translational start sites in Drosophila and vertebrates. Nucleic Acids Res. 15, 1353-1361.
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You will get the antisense strand with pProEXHT.
You will get the + or sense strand with pFastBac I of pFastBac HT.