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View additional product information for pYES2.1 TOPO™ TA Yeast Expression Kit - FAQs (K415001)
82 product FAQs found
We do not recommend storing competent E. coli strains in liquid nitrogen as the extreme temperature can be harmful to the cells. Also, the plastic storage vials are not intended to withstand the extreme temperature and may crack or break.
We recommend storing our competent E. coli strains at -80°C. Storage at warmer temperatures, even for a brief period of time, will significantly decrease transformation efficiency.
Following are the rich and minimal media used for culturing Pichia pastoris and S. cerevisiae:
Rich Media:
S. cerevisiae and Pichia pastoris
YPD (YEPD): yeast extract, peptone, and dextrose
YPDS: yeast extract, peptone, dextrose, and sorbitol
Pichia pastoris only
BMGY: buffered glycerol-complex medium
BMMY: buffered methanol-complex medium
Minimal Media (also known as drop-out media):
S. cerevisiae
SC (SD): Synthetic complete (YNB, dextrose (or raffinose or galactose), and amino acids)
Pichia pastoris
MGY: minimal glycerol medium
MD: minimal dextrose
MM: minimal methanol
BMGH: buffered minimal glycerol
BMMH: buffered minimal methanol
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S. pombe cannot generate P factor when P factor is replaced for alpha in the alpha factor gene. It can, however, produce alpha factor when alpha is replaced for P in the P factor gene. This is negative evidence that S. pombe can process its own mating factor cleavage sites, but not all the cleavage sites of the S. cerevisiae alpha factor. It is better to use a more generic signal sequence (rather than a pre- pro- signal sequence such as alpha). If it is necessary to go the pre- pro- route, it is better to use the S. pombe P factor leader rather than the S. cerevisiae alpha leader.
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Yes, we do offer the pYES2.1/V5-His-TOPO vector, which is part of the pYES2.1 TOPO TA Expression Kit (Cat. No. K415001), for the direct cloning of Taq polymerase-amplified PCR products and regulated expression in Saccharomyces cerevisiae using galactose.
Some researchers choose to grow yeast in medium containing 2% galactose as the sole carbon source during induction. However, yeast typically grow more quickly in induction medium containing 2% galactose plus 2% raffinose. Raffinose is a good carbon source for yeast, and unlike glucose, does not repress transcription from the GAL promoter. Raffinose is a trisaccharide of galactose, glucose, and fructose linked in that order. Most yeast can cleave the glucose-fructose bond, but not the galactose-glucose bond. Fructose is then used as a carbon source.
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We offer the INVSc1 yeast strain. It is a diploid strain for expression purposes only. It does not sporulate well and is therefore not suited for yeast genetic studies. The genotype and phenotype of the INVSc1 strain are as follows:
Genotype: MATa his3D1 leu2 trp1-289 ura3-52/MATalpha his3D1 leu2 trp1-289 ura3-52
Phenotype: His-, Leu-, Trp-, Ura-
Note that INVSc1 is auxotrophic for histidine, leucine, tryptophan, and uracil. The strain will not grow in SC minimal medium that is deficient in histidine, leucine, tryptophan, and uracil.
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Stock buffers of TE, lithium acetate, and PEG can be stored. However, the combined solution used to prepare the cells for transformation must be made fresh every time. There is a loss in transformation efficiency if the solutions are not freshly prepared.
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OD600 of 0.1 = approximately 3 x 10e6 cells/mL
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The efficiency is very strain-dependent, but 1000 to 100,000 transformants per µg DNA is the range.
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Here are the different methods available for S. cerevisiae transformation:
- S. cerevisiae EasyComp Transformation Kit (K505001): easy-to-use, ready-made reagents
Competent cells can be stored frozen. Transformation efficiency is >10e3 transformants per µg DNA. Higher transformation efficiencies are often obtained with frozen versus freshly prepared cells.
- Small-scale yeast transformation protocol (page 13 of the manual)
- Lithium acetate transformation: easy, do-it-yourself protocol
Competent cells must be made fresh
- Electroporation: easy and high efficiency, do-it-yourself protocol
Competent cells must be made fresh
- Spheroplast Kit for Yeast (K172001): high efficiency, a lot of work, not suitable for antibiotic selection
Note: Plate an appropriate density. Colonies will appear over several days. Don't pick the largest colonies, as these are often suppressors.
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We recommend storing yeast frozen at -80 degrees C in 15% glycerol. Glycerol stocks are good indefinitely (unless there are numerous freeze-thaws). When making a glycerol stock, we recommend using an overnight culture and concentrating it 2-4 fold. Spin down cells and suspend in 25-50% of the original volume with glycerol/medium. It is better to store frozen cells in fresh medium plus glycerol, rather than simply adding glycerol into the overnight culture.
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We offer the original Pichia pastoris expression systems, PichiaPink expression system, and Saccharomyces cerevisiae yeast expression system for expression of recombinant proteins. Both P. pastoris and S. cerevisiae have been genetically well-characterized and are known to perform many posttranslational modifications.
The P. pastoris expression system combines the benefits of expression in E. coli (high-level expression, easy scale-up, and inexpensive growth) and the advantages of expression in a eukaryotic system (protein processing, folding, and posttranslational modifications), thus allowing high-level production of functionally active recombinant protein. As a yeast, Pichia pastoris shares the advantages of molecular and genetic manipulations with Saccharomyces cerevisiae, and it has the added advantage of 10- to 100-fold higher heterologous protein expression levels. These features make Pichia pastoris very useful as a protein expression system. The Pichia expression vectors contain either the powerful alcohol oxidase (AOX1) promoter for high-level, tightly controlled expression, or the glyceraldehyde-3-phosphate dehydrogenase (GAP) promoter for high-level, constitutive expression. Both inducible and constitutive expression constructs integrate into the P. pastoris genome, creating a stable host that generates extremely high protein expression levels, particularly when used in a fermentor. The Pichia pastoris expression systems we offer include:
- PichiaPink Yeast Expression System: Newer Pichia pastoris expression system that contains both low- and high-copy plasmid backbones, 8 secretion signal sequences, and 4 yeast strains to help optimize for the highest yield possible of the recombinant protein. All PichiaPink vectors contain the AOX1 promoter for high-level, inducible expression and the ADE2 marker for selecting transformants using ADE2 complementation (i.e., by complementation of adenine auxotrophy) rather than antibiotic selection. However, they express the ADE2 gene product from promoters of different lengths, which dictate the copy number of the integrated plasmids. The pPink-LC vector has an 82 bp promoter for the ADE2marker and offers low-copy expression, and the pPink-HC vector has a 13 bp promoter for the ADE2marker and offers high-copy expression. The system also includes the pPinkalpha-HC vector (containing S. cerevisiae alpha-mating factor pre-sequence) for high copy number secreted expression, and provides eight secretion signal sequences for optimization of secreted expression.
- EasySelect Pichia Expression Kit: One of the original Pichia expression kits that contains the pPICZ and pPICZalpha vectors, for intracellular and secreted expression, respectively, of the gene of interest. These vectors contain the AOX1 promoter for high-level, inducible expression and the Zeocin antibiotic resistance marker for direct selection of multi-copy integrants. They facilitate simple subcloning, simple purification, and rapid detection of expressed proteins.
- Original Pichia Expression Kit: The kit includes the pPIC9, pPIC3.5, pHIL-D2, and pHIL-S1 vectors, each of which carries the AOX1 promoter for high-level, inducible expression and the HIS4 gene for selection in his4 strains, on histidine-deficient medium. pPIC9 carries the S. cerevisiae alpha-factor secretion signal while pHIL-S1 carries the Pichia pastoris alkaline phosphatase signal sequence (PHO) to direct transport of the protein to the medium. pHIL-D2 and pPIC3.5 are designed for intracellular expression.
- Multi-Copy Pichia Expression Kit: This kit is designed to maximize expression and contains the pPIC3.5K, pPIC9K, and pAO815 vectors, which allow production and selection of Pichia strains that contain more than one copy of the gene of interest. They allow isolation and generation of multicopy inserts by in vivo methods (pPIC3.5K and pPIC9K) or in vitro methods (pAO815). All of these vectors contain the AOX1 promoter for high-level, inducible expression and the HIS4 gene for selection in his4 strains, on histidine-deficient medium. The pPIC9K vector directs secretion of expressed proteins while proteins expressed from pPIC3.5K and pAO815 remain intracellular. The pPIC9K and pPIC3.5K vectors carry the kanamycin resistance marker that confers resistance to Geneticin Reagent in Pichia. Spontaneous generation of multiple insertion events can be identified by resistance to increased levels of Geneticin Reagent. Pichia transformants are selected on histidine-deficient medium and screened for their level of resistance to Geneticin Reagent. The ability to grow in high concentrations of Geneticin indicates that multiple copies of the kanamycin resistance gene and the gene of interest are integrated into the genome.
- For expression in S. cerevisiae, we offer the pYES Vector Collection. Each pYES vector carries the promoter and enhancer sequences from the GAL1 gene for inducible expression. The GAL1 promoter is one of the most widely used yeast promoters because of its strong transcriptional activity upon induction with galactose. pYES vectors also carry the 2m origin and are episomally maintained in high copy numbers (10-40 copies per cell).
Yeast is a single-celled, eukaryotic organism that can grow quickly in defined media (doubling times are typically 2.5 hr in glucose-containing media) and is easier and less expensive to use for recombinant protein production than insect or mammalian cells (see table below). These positive attributes make yeast suitable for use in formats ranging from multi-well plates, shake flasks, and continuously stirred tank bioreactors to pilot plant and industrial-scale reactors.
The most commonly employed species in the laboratory are Saccharomyces cerevisiae (also known as Baker's or Brewer's yeast) and some methylotrophic yeasts of the Pichia genus. Both S. cerevisiae and P. pastoris have been genetically characterized and shown to perform the posttranslational disulphide bond formation and glycosylation that is crucial for the proper functioning of some recombinant proteins. However, it is important to note that yeast glycosylation does differ from that in mammalian cells: in S. cerevisiae, O-linked oligosaccharides contain only mannose moieties, whereas higher eukaryotic proteins have sialylated O-linked chains. Furthermore S. cerevisiae is known to hyperglycosylate N-linked sites, which can result in altered protein binding, activity, and potentially yield an altered immunogenic response in therapeutic applications. In P. pastoris, oligosaccharides are of much shorter chain length and a strain has been reported that can produce complex, terminally sialylated or “humanized” glycoproteins.
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.
Find additional tips, troubleshooting help, and resources within our Protein Expression Support Center.
The optimal ratio is 1:1 insert to vector. Optimization can be done using a ratio of 0.5-2 molecules of insert for every molecule of the vector.
Equation:
length of insert (bp)/length of vector (bp) x ng of vector = ng of insert needed for 1:1 insert:vector ratio
Yes, the enzyme mix leaves 3' A-overhangs on a portion of the PCR products. However, the cloning efficiency is greatly decreased compared to that obtained with Taq polymerase alone. It is recommended to add 3' A-overhangs to the product for TA cloning.
Using the vector only for transformation is not a recommended negative control. The process of TOPO-adaptation is not a 100% process, therefore, there will be “vector only” present in your mix, and colonies will be obtained.
Phosphorylated products can be TA cloned but not TOPO cloned. This is because the necessary phosphate group is contained within the topoisomerase-DNA intermediate complex of the vector. TOPO vectors have a 3' phosphate to which topoisomerase is covalently bound and a 5' phosphate. Non-TOPO linear vectors (TA and Blunt) have a 3' OH and a 5' phosphate. Phosphorylated products should be phosphatased (CIP) before TOPO cloning.
You may be cloning in an artifact. TA and TOPO Cloning are very efficient for small fragments (< 100 bp) present in certain PCR reactions. Gel-purify your PCR product using either a silica-based DNA purification system or electroelution. Be sure that all solutions are free of nucleases (avoid communal ethidium bromide baths, for example.)
There could be a few possibilities for this:
- The insert does not interrupt the reading frame of the lacZ gene. If you have a small insert (< 500 bp), you may have light blue colonies. Analyze some of these blue colonies as they may contain insert.
- A polymerase that does not add 3' A-overhangs was used. If you used a proofreading enzyme, you will need to do a post-reaction treatment with Taq polymerase to add the 3' A-overhangs.
- PCR products were gel-purified before ligation. Gel purification can remove the single 3' A- overhangs. Otherwise, optimization of your PCR can be performed so that you can go directly from PCR to cloning.
- The PCR products were stored for a long period of time before ligation reaction. Use fresh PCR products. Efficiencies are reduced after as little as 1 day of storage.
- Too much of the amplification reaction was added to the ligation. The high salt content of PCR can inhibit ligation. Use no more than 2-3 µl of the PCR mixture in the ligation reaction.
- The molar ratio of vector:insert in the ligation reaction may be incorrect. Estimate the concentration of the PCR product. Set up the ligation reaction with a 1:1 or 1:3 vector:insert molar ratio.
On a typical plate there are a few white colonies which do not contain insert. These are usually larger than the other colonies and are due to a deletion of a portion of the plasmid sequence by a rare recombination event (usually from the polylinker to a site in the F1 origin). To find a colony with an insert it is best to pick clones of a variety of color and pattern for analysis. Often an insert will generate two distinct patterns according to its orientation.
No colonies may occur due to the following problems:
Bacteria were not competent. Use the pUC18 vector included with the One Shot module to check the transformation efficiency of the cells.
- Incorrect concentration of antibiotic on plates, or the plates are too old. Use 100 µg/mL of ampicillin or 50 µg/mL kanamycin. Be sure ampicillin plates are fresh (< 1 month old).
- The product was phosphorylated (TOPO cloning only). Phosphorylated products can be TA-cloned but not TOPO-cloned. This is because the necessary phosphate group is contained within the topoisomerase-DNA intermediate complex of the vector. The TOPO vector has a 3' phosphate to which topoisomerase is covalently bound and a 5' phosphate. The non- TOPO vectors (TA and Blunt) have a 3' OH and a 5' phosphate. Phosphorylated products should be phosphatased (CIP) before TOPO-cloning.
Please consider the following possible causes:
- pH > 9: Check the pH of the PCR amplification reaction and adjust with 1 M Tris-HCl, pH 8.
- Excess (or overly dilute) PCR product: Reduce (or concentrate) the amount of PCR product.
- Incomplete extension during PCR: Be sure to include a final extension step of 7 to 30 minutes during PCR. Longer PCR products will need a longer extension time.
- Cloning large inserts (>1 kb): Try one or all of the following suggestions: Increase amount of insert. Incubate the TOPO cloning reaction longer. Gel-purify the insert using either a silica-based DNA purification system (e.g., PureLink system) or electroelution. Be sure that all solutions are free of nucleases (avoid communal ethidium bromide baths, for example.)
- PCR product does not contain sufficient 3' A-overhangs even though you used Taq polymerase: Increase the final extension time to ensure all 3' ends are adenylated. Taq polymerase is less efficient at adding a nontemplate 3' A next to another A. Taq is most efficient at adding a nontemplate 3' A next to a C. You may have to redesign your primers so that they contain a 5' G instead of a 5´ T.
Please try the suggestions below to increase the number of colonies.
- Longer incubation of the TOPO cloning reaction at room temperature, provided that the 6X Salt solution is added to the reaction.
- Electroporation can give significant increases in colony numbers; often 10-20 fold higher. However, if doing electroporation, it is important that the TOPO reaction mix contains diluted Salt solution or, for best results, precipitated prior to transformation. For high primary transformants by electroporation it is recommended to:
- Add 100 µL double diH2O to the 6 µL TOPO reaction and incubate 10 more minutes at 37 degrees C.
- Precipitate by adding 10 µL 3 M Na-Acetate, 2 µL 20 µg/µL glycogen, 300 µL 100% ethanol. Place on dry ice or –80 degrees C for 20 min, spin at top speed in a microcentrifuge at 4 degrees C for 15 min. Wash pellet with 800 µL 80% ethanol, spin at top speed for 10 min, pour off ethanol, spin 1 min, and remove remaining ethanol without disturbing pellet. Dry pellet (air-dry or speed-vac).
- Resuspend pellet in 10 µL ddH2O and electroporate 3.3 µL of resuspended DNA according to a normal electroporation protocol. This electroporation protocol can yield up to 20 fold more colonies than chemical transformation of an equivalent TOPO-reaction. The addition of the 100 µL ddH2O followed by 10 mins incubation is not absolutely necessary, but it sufficiently dilutes the reaction and may help inactivate topoisomerase so that it is more easily electroporated.
We would suggest using our TOPO TA cloning kit for sequencing, which contains the pCR 4 TOPO vector, or our Zero Blunt TOPO PCR cloning kit for sequencing, which contains the pCR4Blunt-TOPO vector.
Due to the small size of your product, we recommend using the pCR 2.1 TOPO vector for your cloning. This size fragment would not be able to fully interrupt the ccdB gene in the pCR4-TOPO vector, and therefore, you may not get colonies as ccdB is lethal to E. coli.
Regular TOPO TA Cloning kits are efficient for cloning PCR products up to approximately 2-3 kb. With PCR products larger than 3 kb, the efficiency of cloning drops significantly. The TOPO XL PCR Cloning Kit has been optimized for TOPO cloning of long (3-10 kb) PCR products.
If using the regular TOPO kits, here are some tips to improve efficiency:
1. Use crystal violet instead of ethidium bromide (EtBr) to visualize the PCR for gel isolation to avoid DNA nicks
2. Increase incubation time of the TOPO reaction to 30 mins
3. Keep insert:vector molar ratio low, optimally 1:1
4. Dilute reaction to 20 µL, while maintaining same amount of vector and insert. Increase the volume of the salt solution to 3.7 µL to compensate for the increase in volume. Diluting the reaction reduces the competition for the vector ends.
Storage of the TOPO vector plus insert reaction for 1 week at 4 degrees C has shown no detectable decrease in the cloning efficiency of the TOPO reaction, as >95% of the colonies have insert. However, the total number of colonies was decreased by 10-fold. Storage of the TOPO reaction mix overnight at 4 degrees C showed little to no decrease in the number of colonies when compared to fresh TOPO reaction mix.
The composition of the 6X Stop solution is 0.3 M NaCl, 0.06 M MgCl2, and the composition of the 6X Salt solution is 1.2 M NaCl, 0.06 M MgCl2. Stop solution is only included in the TOPO XL Cloning kit whereas Salt solution is currently included in all of the other TOPO cloning kits. These solutions prevent free topoisomerase from re-binding and nicking the plasmid, which would reduce the number of colonies from a TOPO reaction.
When doing a TOPO cloning reaction, 2 µl of a PCR reaction containing up to 10% DMSO or 1.3 M betaine will not interfere with the TOPO reaction. Formamide and high levels of glycerol will inhibit the reaction. These reagents are usually added to the PCR reaction to enhance the yield of the PCR product, e.g., to reduce the effect of secondary structure or assist in amplification of GC-rich sequences. The effects of tricine or acetamide have not been tested on the TOPO cloning reaction.
PCR primers should not have 5'-phosphates when cloning into any TOPO vector, as the presence of 5'-phosphates inhibit the TOPO cloning reaction. Phosphorylated products can be TA-cloned but not TOPO-cloned. This is because the necessary phosphate group is contained within the topoisomerase-DNA intermediate complex of the vector. TOPO vectors have a 3' phosphate to which topoisomerase is covalently bound and a 5' phosphate. Non-TOPO linear vectors (TA and Blunt) have a 3' OH and a 5' phosphate. Phosphorylated products should be treated with phosphatase (CIAP) prior to TOPO-cloning. Treatment with CIAP may raise efficiency to 25%. PCR products generated with 5'-biotinylated primers (or any other 5'-label including 5'-Cy5) will not ligate into any of the TOPO vectors due to steric hindrance.
Gel purification is not required if the gel indicates that the PCR product is clean with no visible non-specific bands or primer dimers. It is recommended if the PCR product is >1.5 kb or if non-specific bands and primer dimers are visible on the gel. Smaller products clone much more efficiently into the vector than larger products; therefore, they should be eliminated from the sample prior to cloning. There is some reduction in A-overhangs if the PCR product is gel purified, which along with PCR product loss during the procedure may slightly reduce total number of colonies. However, the percentage of colonies with insert does not change; it is typically >90% recombinant clones.
For optimal TOPO cloning, we recommend using fresh PCR products.
TA cloning ligates the insert and vector using a T4 DNA ligase, while TOPO TA cloning uses the intrinsic properties of topoisomerase, which ligates the insert and vector during a 5 minute desktop reaction. TOPO TA cloning results in >95% recombinants, while TA cloning results in >80% recombinants.
We offer a custom service for TOPO cloning adaptation services. Our scientists can prepare your vector for either blunt TOPO cloning, TOPO TA cloning, or directional TOPO cloning of PCR products.
Yes, our pCR.1 TOPO TA (Cat. No. 450641), pCR4-TOPO TA (Cat. No. 450030), pCRBluntII-TOPO (Cat. No. 450245) are available separately.
No, we do not recommend this as these vectors contain the topoisomerase DNA protein complex conjugated to the end of the vector.
We suggest starting with a molar ratio of 1:1 (insert:vector), with a range of 0.5:1 to 2:1 (insert:vector). The ng quantities should be between 5-10 ng of a 2 kb PCR product in a TOPO cloning reaction.
Please consider the following before TOPO cloning:
- TOPO cloning cannot ligate DNA with a 5' phosphate group.
- TOPO cloning will decrease in efficiency inversely with the size of the insert (above 3 kb) unless using the TOPO XL cloning kit.
- TOPO vectors contain different antibiotic resistance markers which should be considered before purchase.
- TOPO TA vectors accept fragments containing a 3' A overhang while Zero Blunt vectors accept fragments that are blunt-ended.
TOPO and TOPO TA vectors (non-directional) have phenol red dye added. The color should be pink (or yellow) at room temperature. If it turns blue when PCR product is added, the PCR product buffer is too basic and the number of transformed colonies will drop. When the solution is yellow, it signifies an acidic pH. At a pH 2.0, TOPO vectors still maintain high cloning efficiency. Directional TOPO and Zero Blunt TOPO vectors have bromophenol blue dye added.
Subcloning DH5? cells are a compatible strain, but you will get lower efficiency (10e6 vs 10e9) and therefore risk getting fewer clones. Top10F' is also compatible, but if blue/white screening is performed, IPTG along with X-gal will be needed for detection due to the expression of the lacIq repressor present in cells containing an F' episome.
Ensure that you are using the correct antibiotic at the appropriate concentration. Additionally, make sure the antibiotic is not expired. If colonies exhibit unexpected morphologies, contamination could be a factor. Check your S.O.C. medium and LB growth medium.
Here are a few suggestions:
- Small fragments/linkers are cloning in to your vector instead of your insert; to correct this, gel-purify the insert before ligation
- Ensure that the correct concentrations of X-gal and/or IPTG (if vector contains the lacIq marker) are used
- If spreading X-gal and/or IPTG on your plate, allow sufficient time for the reagents to diffuse into the plate
- Incubate your plate for a longer period to ensure full color development
While there is no specific strain that works better with large plasmids, it is important to focus on transformation efficiency. For larger plasmids, chemically competent cells with highest efficiency are suggested, such as OmniMAX 2, TOP10, etc. We would recommend using an electrocompetent cell strain with plasmids larger than 20 kb for best efficiency.
With any strain, the first thing to try would be to lower the growth temperature of the culture to 30 degrees C or even lower (room temperature). Slower growth will generally allow E. coli to tolerate difficult sequences better. If reducing the growth temperature doesn't help, you may want to consider using a competent cell strain such as Stbl2 or Stbl4 cells, which have been shown to accommodate this type of sequence better than other strains in the same conditions.
We recommend trying the following:
- Carry out the puc19 transformation control; this gives you information about the performance of the cells.
- Check plates for expiration and correct media used (LB/agar).
- Confirm that the correct antibiotic and concentration was used.
The F' episome in TOP10F' has a lacIq marker, which over-expresses the lac repressor. IPTG must be added to LB plates along with X-gal to see beta-galactosidase expression and blue color in this strain. TOP10, on the other hand, does not require IPTG for blue/white screening.
There are a few conditions that can lead to this: SOC medium or other media used when plating was contaminated, DNA was contaminated with amp-resistant microbes, you used old plates with degraded amp, or the competent cells themselves were contaminated.
If you are using a mcr/mrr(+) competent cell strain, cellular enzymes may be recognizing eukaryotic methylation patterns on the yeast genomic DNA and deleting or rearranging it. Try a mcr/mr(-) strain such as Top10, DH10B, or OmniMAX 2.
XbaI cutting site is a Dam-methylation sensitive restriction site. TOP10 is a dam(+) strain, which means it expresses the methylating enzyme, Dam. You can try re-transforming into a dam(-) strain, such as INV110. Other dam- (and dcm-) sensitive restriction sites include the following:
- Dam: Bcl I, Cla I, Hph I, Mbo I, Mbo II, Taq I, Xba I, BspH I, Nde II, Nru I
- Dcm: Ava II, EcoO 109 I, EcoR II, Sau96 I, ScrF, Stu I, Aat I, Apa I, Bal I, Kpn I, ISfi I
1. Use pUC or pUC-based vectors that contain the portion of the lacZ gene that allows for ? complementation.
2. Select an E. coli strain that carries the lacZdeltaM15 marker.
3. Plate transformations on plates containing X-gal. Spread 50 µg of 2% X-gal or 100 microliters of 2% bluo-gal (both can be dissolved in DMF or 50:50 mixture of DMSO:water) on the surface of a 100 mm plate and let dry. Alternatively, add directly to the cooled medium (~50 degrees C) before pouring the plates at a final concentration of 50 µg/mL for X-gal and 300 µg/mL for bluo-gal. Plates are stable for 4 weeks at 4 degrees C.
4. If the strain used carries the lacIq marker, add IPTG to induce the lac promoter. Spread 30 µl of 100 mM IPTG (in water) on 100 mm plates. Alternatively, add the IPTG directly to cooled medium (~50 degrees C) before pouring the plates to a final concentration of 1 mM. Plates are stable for 4 weeks at 4 degrees C.
5. Do not plate E. coli on medium containing glucose if using X-gal or bluo-gal for blue-white screening. Glucose competes as a substrate and prevents cells from turning blue.
For long-term storage, preparation of glycerol stocks stored at -70 degrees C is recommended. Follow the protocol below:
1. Pick one colony into 5 mL LB broth or S.O.C. medium. Grow overnight at 37 degrees C.
2. Prepare glycerol solution: 6 mL of S.O.B. medium and 4 mL of glycerol.
3. Take one volume of cells and add one volume of glycerol solution and mix.
4. Freeze in ethanol/dry ice. Store at -70 degrees C.
Yes, this is possible. We recommend using saturating amounts of DNA (10 ng of each plasmid). Make sure that the origin of replication is different in each plasmid so that they can both be maintained in the cell. If the ori is the same, the plasmids will compete for replication and the one with even a slight disadvantage will be lost. Alternatively, cells with a resident plasmid can be electroporated with a second plasmid without “electrocuring” taking place.
In plates, we recommend 50 µg/mL X-gal and 1 mM IPTG (0.24 mg/mL). When spreading directly onto agar plates, we recommend 40-50 µl of 40 mg/mL X-gal (2% stock) in dimethylformamide and 30-40 µl of 100 mM IPTG on top of the agar. Let the X-gal and IPTG diffuse into the agar for approximately 1 hour. Do not plate on media containing glucose, as it competes with X-gal or bluo-gal and prevents cells from turning blue.
Competent cell efficiency is measured by transformation efficiency. Transformation efficiency is equal to the number of transformants, or colony forming units, per microgram of plasmid DNA (cfu/microgram).
Some suggestions that will help you to obtain the highest transformation efficiency are:
- Thaw competent cells on ice instead of room temperature; do not vortex cells.
- Add DNA to competent cells once thawed.
- Ensure that the incubation times are followed as outlined in the competent cell protocol for the strain you are working with; changes in the length of time can decrease efficiency.
- Remove salts and other contaminants from your DNA sample; DNA can be purified before transformation using a spin column, or phenol/chloroform extraction and ethanol precipitation can be employed.
DH5? cells are commonly used for routine cloning, but are mcr/mrr+, and therefore not recommended for genomic cloning. The TOP10 competent cells, on the other hand, contain mutated mcr/mrr, and therefore are a good choice for routine cloning and can be used for cloning of methylated DNA, such as eukaryotic genomic DNA. Our Mach1 strain is the fastest growing cloning strain that is T1 phage resistant.
These small colonies are most likely caused by degradation of the Ampicillin. The colonies are just untransformed cells that grow on LB with degraded Amp. In order to circumvent this scenario, you can try to:
1. Plate cells at a lower density
2. Use fresh LB-Amp plates or replace Ampicillin with carbenicillin.
3. The plates should not be incubated for more than 20 hours at 37 degrees C. Beta-lactamase, the enzyme produced from the Ampicillin-resistance gene, is secreted from the Amp-resistant transformants and inactivates the antibiotic in the area surrounding the transformant colony. This inactivation of the selection agent allows satellite colonies (which are not truly Amp-resistant) to grow. This is also true if carbenicillin is being used.
One possible explanation could be toxicity associated with the insert. This toxicity does not affect slow growing cells on solid medium but is much stronger in faster growth conditions like liquid medium.
Suggestions:
1. Use TOP10F' or any other strain with the LacIq repressor
2. Try using any other strain appropriate for cloning.
3. Lower growth temperature to 27 - 30 degrees C and grow the culture longer
4. Another possibility to explain lack of growth is possible phage contamination. In this situation we recommend using an E. coli strain that is T1 phage resistant like DH5alpha-T1R.
This may be caused by the instability of the insert DNA in TOP10 E. Coli. In this case, E.coli strains such as Stbl2, Stbl3, or Stbl4 have been shown to support the propagation of DNA with multiple repeats, retroviral sequences, and DNA with high GC content better than other strains.
Some possible causes and remedies are:
- Ligase function is poor. Check the age of the ligase and function of the buffer.
- Competent cells are not transforming. Test the efficiency of the cells with a control supercoiled vector, such as puc19.
- Both molecules were de-phosphorylated.
- Inhibition of ligation by restriction enzymes and residual buffer. Try transformation of uncut vector, clean up restriction with phenol, or carry out PCR cleanup/gel extraction before ligation.
- Incorrect antibiotic selection used. Check the plasmid and plates and make sure concentration of antibiotic used is correct.
If nothing above applies, low to no colonies may be due to instability of the insert DNA in your competent cells. In this case, E. coli strains such as Stbl2, Stbl3, or Stbl4 have been shown to support the propagation of DNA with multiple repeats, retroviral sequences, and DNA with high GC content better than other strains.
If working with a vector that contains the lac promoter and the LacZ ? fragment (for ? complementation), blue/white screening can be used as a tool to select for presence of the insert. X-gal is added to the plate as a substrate for the LacZ enzyme and must always be present for blue/white screening. The minimum insert size needed to completely disrupt the lacZ gene is >400 bp. If the LacIq repressor is present (either provided by the host cells, for example TOP10F', or expressed from the plasmid), it will repress expression from the lac promoter thus preventing blue/white screening. Hence, in the presence of the LacIq repressor, IPTG must be provided to inhibit the LacIq. Inhibition of LacIq permits expression from the lac promoter for blue/white screening.
TOPO vectors containing the LacZ-ccdB cassette allow direct selection of recombinants via disruption of the lethal E. coli gene, ccdB. Ligation of a PCR product disrupts expression of the LacZ-ccdB gene fusion permitting growth of only positive recombinants upon transformation. Cells that contain non-recombinant vector are killed upon plating. Therefore, blue/white screening is not required. When doing blue/white color screening of clones in TOPO vectors containing the LacZ-ccdB cassette, colonies showing different shades of blue may be observed. It is our experience that those colonies that are light blue as well as those that are white generally contain inserts. The light blue is most likely due to some transcription initiation in the presence of the insert for the production of the lacZ alpha without enough ccdB expressed to kill the cells and is insert dependent. To completely interrupt the lacZ gene, inserts must be >400 bp; therefore an insert of 300 bp can produce a light blue colony. A white colony that does not contain an insert is generally due to a spontaneous mutation in the ccdB gene.
A minimum insertion of 150 bp is needed in order to ensure disruption of the ccdB gene and prevent cell death. (Reference: Bernard et al., 1994. Positive-selection vectors using the F plasmid ccdB killer gene. Gene 148: 71-74.)
Strains that contain an F plasmid, such as TOP10F', are not recommended for transformation and selection of recombinant clones in any TOPO vector containing the ccdB gene. The F plasmid encodes the CcdA protein, which acts as an inhibitor of the CcdB gyrase-toxin protein. The ccdB gene is also found in the ccd (control of cell death) locus on the F plasmid. This locus contains two genes, ccdA and ccdB, which encode proteins of 72 and 101 amino acids respectively. The ccd locus participates in stable maintenance of F plasmid by post-segregational killing of cells that do not contain the F plasmid. The CcdB protein is a potent cell-killing protein when the CcdA protein does not inhibit its action.
If working with a vector that contains the lac promoter and the LacZ alpha fragment (for ? complementation), blue/white screening can be used as a tool to select for presence of the insert. X-gal is added to the plate as a substrate for the LacZ enzyme and must always be present for blue/white screening. The minimum insert size needed to completely disrupt the lacZ gene is >400 bp. If the LacIq repressor is present (either provided by the host cells, for example TOP10F', or expressed from the plasmid) it will repress expression from the lac promoter, thus preventing blue/white screening. Hence in the presence of the LacIq repressor, IPTG must be provided to inhibit the LacIq. Inhibition of LacIq permits expression from the lac promoter for blue/white screening. X-gal (also known as 5-bromo-4-chloro-3-indolyl β-D-glucopyranoside) is soluble in DMSO or DMF, and can be stored in solution in the freezer for up to 6 months. Protect the solution from light. Final concentration of X-gal and IPTG in agar plates: Prior to pouring plates, add X-gal to 20 mg/mL and IPTG to 0.1 mM to the medium. When adding directly on the surface of the plate, add 40 µl X-gal (20 mg/mL stock) and 4 µl IPTG (200 mg/mL stock).
No, these vectors do not contain a functional promoter to express your gene of interest. These vectors are typically for subcloning or sequencing.
TA Cloning:
- This cloning method was designed for use with pure Taq polymerases (native, recombinant, hot start); however, High Fidelity or Taq blends generally work well with TA cloning. A 10:1 or 15:1 ratio of Taq to proofreader polymerase will still generate enough 3' A overhangs for TA cloning.
- Recommended polymerases include Platinum Taq, Accuprime Taq, Platinum or Accuprime Taq High Fidelity, AmpliTaq, AmpliTaq Gold, or AmpliTaq Gold 360.
Blunt cloning:
- Use a proofreading enzyme such as Platinum SuperFi DNA Polymerase.
Directional TOPO cloning:
- Platinum SuperFi DNA Polymerase works well.
S. cerevisiae can grow using either or both mechanisms of carbon metabolism. The balance between the two is different for glucose vs. galactose as a carbon source. Under ideal conditions, S. cerevisiae grows slower on galactose than on glucose, because production of glucose-6-P from galactose is rate limiting. (gal -> gal-1-P -> glu-1-P -> glu-6-P). Under non-ideal conditions (low oxygen, as in the center of a colony or a culture without really good oxygen feed), it becomes even worse because cells grown on galactose are using more respiration than fermentation relative to cells grown on glucose. Low oxygen makes fermentation more necessary, which cells growing on galactose are not good at.
Glucose will shut down completely expression from the GAL1 promoter. Glucose causes repression of the Gal1 promoter.
The doubling time of a pYES2 transformed S. cerevisiae strain grown on minimal media with glucose is approximately 2 hours. The doubling time on media with galactose is approximately 4 hours.
The 2 micron plasmid occurs naturally in some strains of S. cerevisae. When a plasmid contains the 2 micron origin of replication it is maintained at 10-40 copies per cell.
As with other sugars (e.g. glucose), D-raffinose is the biologically active carbon source for yeast. Pure L-raffinose will not work.
The suggested initial cell density for galactose induction is 1 to 5 X 10E6 cells/ml . The cells are allowed to divide one or two times and then induced with galactose. Galactose induction is best in log phase and the culture will probably approach static phase at 1 to 4 X 10E7 cells/ml. Induction of cells maintained in raffinose may begin in 15 to 30 minutes whereas induction of cells maintained in glucose may not first occur for an hour or more. Peak expression will often occur in 2 - 4 hours so time points should be taken every hour (or every other hour) for up to 10 hours. When using raffinose maintained cells, the induction is much faster than induction of glucose maintained cells. Maximal expression levels remain the same.
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Although there are no other genes on the plasmid that are induced, there certainly are a number of proteins in the cell that are turned on by galactose and any of those may be apparent. As with any experiment, one should always run the plasmid without insert, induced with galactose as a negative control. The additional bands could be due to post-translational modifications, such as glycosylation, that would increase the apparent molecular weight. Since the size of the sugar chains can be variable, glycosylated proteins often appear as less well defined bands compared to non-glycosylated proteins.
pYES2 does not have a CEN sequence. pYES2 has the 2µ ori which maintains a copy number of 30 to 50 copies per cell. The 2µ ori sequence is derived from the endogenous 2µ circle plasmid (it's the replication origin for 2µ circle).
'CEN' stands for 'CENtromere' sequence. This origin of replication keeps the copy number of that vector down to one or two per cell in yeast. CEN sequences are actual chromosome centromere sequences. CEN ori will keep copy number to 1 or 2 per cell (depending on whether the cell is haploid or diploid). This sequence allows the cell to recognize this plasmid as a chromosome; regulation of chromosome number is extremely rigid. Only functional CEN sequences from S. cerevisiae have been isolated and used on plasmids. CEN sequences are only a couple of hundred base pairs in size. Apparently functional centromere sequences from other eukaryotes, including Sc. pombe and Pichia, are too large to be isolated and utilized on a plasmid.
The 2µ sequence in pYES2 has the replication origin only--not sequences that code for the proteins required for self replication. Therefore, vectors such as pYES2 will replicate to high copy number (30 per cell) and are very stable in circle-plus (have endogenous 2µ) strains but are maintained only at low copy number (2 per cell) and are very unstable in circle-zero strains, with no endogenous 2µ.
The following relative expression levels were observed in beta-galactosidase expression assays:
0.1 units when repressed in the presence of glucose.
Greater than 2000 units when induced in the absence of glucose and the presence of galactose.
The following are commonly employed auxotrophic markers:
1) his3Δ1: Histidine requiring strain (from gene disruption) with a deletion in locus 1. The his3 denotes the disruption of the HIS3 gene. The Δ1 is a deletion that has been engineered to decrease the recombination between the incoming plasmid DNA and the chromosomal site.
2) leu2: Leucine requiring strain due to the disruption of the LEU2 gene.
3) trp1-289: Tryptophan requiring strain, developed from gene disruption and a further point mutation to decrease the recombination between the incoming plasmid DNA and the chromosomal site.
4) ura3-52: Uracil requiring.
For more detail on types and methods of gene disruption in yeast refer to METHODS IN ENZYMOLOGY Vol. 194.
Some researchers choose to grow yeast in medium containing 2% galactose as the sole carbon source during induction. However, yeast typically grow more quickly in induction medium containing 2% galactose plus 2% raffinose. Raffinose is a good carbon source for yeast, and unlike glucose, does not repress transcription from the GAL promoter. Raffinose is a trisaccharide of galactose, glucose and fructose linked in that order. Most yeasts can cleave the glucose-fructose bond, but not the galactose-glucose bond. Fructose is then used as a carbon source.
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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Our vectors have not been completely sequenced. Your sequence data may differ when compared to what is provided. Known mutations that do not affect the function of the vector are annotated in public databases.
No, our vectors are not routinely sequenced. Quality control and release criteria utilize other methods.
Sequences provided for our vectors have been compiled from information in sequence databases, published sequences, and other sources.