pcDNA™6/TR vector Mammalian Expression Vector

No, you should use an entry vector that contains the elements necessary for RNA Polymerase III-dependent expression of your shRNA (i.e., Pol III promoter and terminator).

A dose response curve or kill curve is a simple method for determining the optimal antibiotic concentration to use when establishing a stable cell line. Untransfected cells are grown in a medium containing antibiotic at varying concentrations in order to determine the lowest amount of antibiotic needed to achieve complete cell death. The basic steps for performing a dose response curve or kill curve are as follows:

- Plate untransfected cells at 25% confluence, and grow them in a medium containing increasing concentrations of the antibiotic. For some antibiotics, you will need to calculate the amount of active drug to control for lot variation.
- Replenish the selective medium every 3-4 days. After 10-12 days, examine the dishes for viable cells. The cells may divide once or twice in the selective medium before cell death begins to occur.
- Look for the minimum concentration of antibiotic that resulted in complete cell death. This is the optimal antibiotic concentration to use for stable selection.

Find additional tips, troubleshooting help, and resources within our Protein Expression Support Center.

Unfortunately, the pENTR/U6 vector does not contain a selection marker; therefore, only transient RNAi analysis may be performed. If you wish to generate stable cell lines, perform an LR reaction into an appropriate Gateway destination vector to generate expression clones.
The pENTR/H1/TO vector contains the Zeocin resistance gene to facilitate generation of cell lines that inducbily express the shRNA of interest. Perform a kill curve to determine the minimum concentration of Zeocin that is required to kill your untransfected mammalian cell line. Please note that Zeocin-sensitive cells do not round up and detach from the plate, but rather may increase in size, show abnormal cell shape, display presence of large empty vesicles in the cytoplasm, or show breakdown of plasma/nuclear membranes.

Find additional tips, troubleshooting help, and resources within our RNAi Support Center.

You can use a loop sequence of any length ranging from 4 to 11 nucleotides, although short loops (i.e., 4-7 nucleotides) are generally preferred. Avoid using a loop sequence containing thymidines (Ts), as they may cause early termination. This is particularly true if the target sequence itself ends in one or more T nucleotides. Here are some loop sequences we recommend:

- 5' - CGAA - 3'
- 5' - AACG - 3'
- 5' - GAGA - 3'

Transcription of the shRNA initiates at the first base following the end of the U6 promoter sequence. In the top-strand oligo, the transcription initiation site corresponds to the first nucleotide following the 4 bp CACC sequence added to permit directional cloning. We recommend initiating the shRNA sequence at a guanosine (G) because transcription of the native U6 snRNA initiates at a G. Note the following:

- If G is part of the target sequence, then incorporate the G into the stem sequence in the top-strand oligo and add a complementary C to the 3' end of the top-strand oligo.
- If G is not the first base of the target sequence, we recommend adding a G to the 5' end of the top-strand oligo directly following the CACC overhang sequence. In this case, do not add the complementary C to the 3' end of the top-strand oligo. Note: We have found that adding the complementary C in this situation can result in reduced activity of the shRNA. Alternative, if use of a G to initiate transcription is not desired, use an adenosine (A) rather than C or T. Note, however, that use of any nucleotide other than G may affect initiation efficiency and position.