Invitrogen™ ElectroMAX™ Stbl4™ Competent Cells

Catalog No.	Quantity
11-635-018	5 x 100 μL

Catalog No. 11-635-018 Supplier Invitrogen™ Supplier No. 11635018

Description

Includes

ElectroMAX Stbl4 Competent Cells: 5 vials, 100μL each, pUC19 DNA (10pg/μL): 1 vial, 50μL, S.O.C. medium: 2 bottles, 6mL each

ElectroMAX Stbl4 Competent Cells are specifically designed for cloning unstable inserts. This strain is a derivative of Stbl2 cells (engineered from JM109/J5 strain).

ElectroMAX Stbl4 Competent Cells are specifically designed for cloning unstable inserts. This strain is a derivative of Stbl2 cells (engineered from JM109/J5 strain). To improve performance, the gal- mutation was introduced, lon- restored to wild type lon+ allele, and F′ episome introduced. The Stbl4 strain retains the genetic properties of the Stbl2 strain for the maintenance of unstable inserts such as retroviral sequences, direct repeats, and tandem array genes. In addition, the Stbl4 strain is reportedly used in discovery of complex secondary metabolites and CRISPR library construction and maintenance.

As electrocompetent cells, Stbl4 cells can achieve high transformation efficiency of >5 x 10⁹ cfu/μg, making them ideal for challenging applications such as generating cDNA, CRISPR, and genomic libraries of unstable inserts or using low DNA input. Electrocompetent Stbl4 cells are able to take up and maintain large plasmids (e.g., 50 kb cosmids and 100–200 kb P1 clones). Stbl4 cells also contain an F' episome, allowing them to serve as a host for single-stranded DNA such as M13mp cloning vectors if a lawn of DH5αF′IQ is provided to allow plaque formation. The lacZΔM15 marker provides α-complementation of the β-galactosidase gene from pUC or similar vectors and can therefore be used for blue-white screening of colonies on agar plates containing X-gal or Bluo-gal and IPTG. The mcrA mutation and the mcrBC-hsdRMS-mrr deletion allow cloning of genomic sequences that are methylated. Finally, the endA1 mutation greatly increases plasmid yield and quality.

ElectroMAX Stbl4 competent cell features
• Provide transformation efficiencies of >5 x 10⁹ cfu/μg
• Unique genotype stabilizes direct repeats and retroviral sequences
• The mcrA mutation and mcrBC-hsdRMS-mrr deletion allows cloning methylated genomic sequences
• Support of blue-white screening of recombinant clones due to lacZΔM15
• Designed to deliver high-yield plasmid preparations for downstream applications
• Stable F' episome allows isolation of ssDNA

Propagating unstable and large DNA with high transformation-efficiency cells
Many competent cell strains have the recA1 genotype, which reduces recombination. However, there are some instances when the DNA that you are trying to clone is still unstable in such cells, perhaps due to the presence of inverted or direct repeats or GC-rich tracts. While such sequences are relatively common in eukaryotic genomes, they are rare in E. coli. Consequently, rearrangements may occur when these sequences are introduced into standard E. coli strains.

Genotype: mcrA Δ(mcrBC-hsdRMS-mrr) recA1 endA1 gyrA96 gal–thi-1 supE44 λ–relA1 Δ(lac-proAB) / F′ [proAB+lacIqZΔM15 Tn10(TetR)]

Find the strain and format that fits your needs
• Stbl strains are available with a variety of genetic background.
• The Stbl3 strain is available in MultiShot format for high throughput applications.
• MAX Efficiency DH5αF´IQ Competent Cells (Cat. No. 18288019) are available in chemically competent format.

Notes
• To maximize stabilization of direct repeats and retroviral sequences, incubate Stbl4 cells and perform expression studies at 30°C.
• A high-voltage electroporation apparatus is required.
• Stbl4 strain genome sequences are available in the NCBI GenBank database under accession numbers CP076043.1 and CP076044.1 (Assad et al. 2021).

Order Info

Shipping Condition: Dry Ice

Specifications

• Product Type: Electrocompetent Cells
• Contains F' Episome: Yes
• Improves Plasmid Quality: Yes (endA1)
• Cloning Methylated DNA: Yes (mcrB, mrr)
• Transformation Efficiency Level: High Efficiency (>1 x 10⁹ cfu/μg)
• Content And Storage: • ElectroMAX Stbl4 Competent Cells (5 x 100 μL)
  Store Competent Cells at –80°C.
  
  • pUC19 DNA (50 μL at 10 pg/μL)
  Store pUC19 DNA at –20°C.
  
  • S.O.C. Medium (2 x 6 mL)
  Store S.O.C. Medium at 4°C or room temperature.
  
  
• Antibiotic Resistance Bacterial: Yes (Tetracycline)
• Cloning Unstable DNA: Yes (recA1)
• Blue/White Screening: Yes (lacZΔM15)
• High-throughput Compatibility: Low
• Plasmid: May be used for plasmids >100 kb
• Preparing Unmethylated DNA: No
• Reduces Recombination: Yes (recA1)
• Shipping Condition: Dry Ice
• T1 Phage - Resistant (tonA): No
• Species: E. coli (K12)
• Format: Tube
• Product Line: ElectroMAX
• Quantity: 5 x 100 μL

Frequently Asked Questions (FAQs)

How do you recommend that I prepare my DNA for successful electroporation of E. coli?

For best results, DNA used in electroporation must have a very low ionic strength and a high resistance. A high-salt DNA sample may be purified by either ethanol precipitation or dialysis.

The following suggested protocols are for ligation reactions of 20ul. The volumes may be adjusted to suit the amount being prepared.

Purifying DNA by Precipitation: Add 5 to 10 ug of tRNA to a 20ul ligation reaction. Adjust the solution to 2.5 M in ammonium acetate using a 7.5 M ammonium acetate stock solution. Mix well. Add two volumes of 100 % ethanol. Centrifuge at 12,000 x g for 15 min at 4C. Remove the supernatant with a micropipet. Wash the pellet with 60ul of 70% ethanol. Centrifuge at 12,000 x g for 15 min at room temperature. Remove the supernatant with a micropipet. Air dry the pellet. Resuspend the DNA in 0.5X TE buffer [5 mM Tris-HCl, 0.5 mM EDTA (pH 7.5)] to a concentration of 10 ng/ul of DNA. Use 1 ul per transformation of 20 ul of cell suspension.

Purifying DNA by Microdialysis: Float a Millipore filter, type VS 0.025 um, on a pool of 0.5X TE buffer (or 10% glycerol) in a small plastic container. Place 20ul of the DNA solution as a drop on top of the filter. Incubate at room temperature for several hours. Withdraw the DNA drop from the filter and place it in a polypropylene microcentrifuge tube. Use 1ul of this DNA for each electrotransformation reaction.

How can I clone a gene that has direct repeats and propagate it without altering the repeat sequences?

The first thing you can do is to lower the growth temperature of your E. coli cells when propagating your plasmid containing the unstable gene. Slowing the growth of any cell strain at 30C, 25C or even lower can help to stabilize the replication of the plasmids they contain.

If your sequence is still unstable despite low-temperature growth, there are also specific bacterial strains available that can further help to stabilize repeated sequences during propagation. Invitrogen Stbl2 and Stbl4 competent cells are both designed to improve stability when cloning retroviral or direct repeat sequences.

In a series of experiments, Stbl2 was compared directly to several other strains also known for increasing stability of retroviral and tandem repeat inserts. An article in the Focus Journal (Issue 16.3, p. 78) contains data from two such experiments – the full article can be found on the Thermo Fisher Scientific website. A brief summary of the data is included below:

Stability of clones containing SIV retroviral sequences:
Stbl2 @ 30°C - 100%; Stbl2 @ 37°C - 100%; HB101 @ 30°C - 100%; HB101 @ 37°C - 100%; SURE @ 30°C - 72%; SURE @ 37°C - 0%

Stability of clones containing 100 repeats of a 32-bp sequence:
Stbl2 @ 30°C - 89%; Stbl2 @ 37°C - 73%; HB101 @ 30°C - 15%; HB101 @ 37°C - 0%; SURE @ 30°C - 53%; SURE @ 37°C - 0%

Results from a separate experiment on stability of a tandem repeat of four R67 dihydrofolate reductase genes in Stbl2 vs. SURE cells can be found in Focus 19.2, p. 24 on the Thermo Fisher Scientific website.

Can encapsulated phagemid DNA or M13 phage be used to infect bacteria?

Single-stranded DNA viral particles like M13 require the presence of an F pilus in order to infect E. coli. This criterion is met by TOP10F', DH5? F'IQ, INV?F', Stbl4, OmniMAX2-T1 and DH12S cells. These cells are not traD mutants, which effectively allows the cells to retain the F' episome. Transforming single-stranded DNA can cause a 100- to 1,000-fold reduction in efficiency compared to viral particles.

Is S.O.C. medium absolutely required when recovering competent bacterial cells during transformation?

Many media can be used to grow transformed cells, including standard LB, SOB or TB broths. However, S.O.C. is the optimal choice for recovery of the cells before plating. The nutrient-rich formula with added glucose is often important for obtaining maximum transformation efficiencies.

How can unstable or toxic DNA inserts be maintained in bacteria?

There are a few steps you can take to improve stability of clones with difficult-to-maintain inserts. Supplement the medium with extra nutrients (e.g., add 20-30 mM glucose to Terrific Broth) or try a vector that has a reduced copy number (e.g., pBR322). Some clones can exhibit a high degree of deletions; this is usually a result of the clones having long terminal repeat (LTR) sequences or regions with high secondary structure. To overcome this problem, the cells can be grown at 30°C or ambient temperature (in LB or in a nutrient rich broth like Terrific Broth). Do not to let the cells reach late stationary phase in liquid culture. Alternatively, transform into cells that maintain unstable sequences such as Stbl2, Stbl3, or Stbl4 cells.

Why is it necessary to dilute ligated DNA products before adding them to competent bacterial cells?

Components of the ligation reaction (enzymes, salts) can interfere with transformation, and may reduce the number of recombinant colonies or plaques. We recommend a five-fold dilution of the ligation mix, and adding not more than 1/10 of the diluted volume to the cells. For best results, the volume added should also not exceed 10% of the volume of the competent cells that you are using.

When should DMSO, formamide, glycerol and other cosolvents be used in PCR?

Cosolvents may be used when there is a failure of amplification, either because the template contains stable hairpin-loops or the region of amplification is GC-rich. Keep in mind that all of these cosolvents have the effect of lowering enzyme activity, which will decrease amplification yield. For more information see P Landre et al (1995). The use of co-solvents to enhance amplification by the polymerase chain reaction. In: PCR Strategies, edited by MA Innis, DH Gelfand, JJ Sninsky. Academic Press, San Diego, CA, pp. 3-16.

Additionally, when amplifying very long PCR fragments (greater than 5 kb) the use of cosolvents is often recommended to help compensate for the increased melting temperature of these fragments.

For Research Use Only. Not for use in diagnostic procedures.