System Biosciences

AAVS1 Safe Harbor Positive Control Donor Vector [pAAVS1D-CMV.RFP-EF1a.copGFPpuro]

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SKU:
PIN610A-1
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Size:
10 ug
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  • AAVS1 Safe Harbor Positive Control Donor Vector [pAAVS1D-CMV.RFP-EF1a.copGFPpuro]
  • AAVS1 Safe Harbor Positive Control Donor Vector [pAAVS1D-CMV.RFP-EF1a.copGFPpuro]
£964.92

Description

AAVS1 Safe Harbor Positive Control Donor Vector [pAAVS1D-CMV.RFP-EF1a.copGFPpuro]. Cat# GE603A. Supplier: SBI System Biosciences

Use this Luciferase-expressing PinPoint Donor Vector as a positive control or to troubleshoot your PinPoint Targeted Integration Projects
  • Create isogenic cell lines
  • Achieve high-efficiency integration with no insert size-limit
  • Turn cell line construction into a high-throughput process

Products

Easy and efficient isogenic cell line creation
 
With the PinPoint Targeted Integration System you can get controlled, single-copy integration of your PinPoint Donor Vector at a pre-placed PinPoint attP site. The CMV-Luc PinPoint Positive Control Donor Vector (pPP-CMV-Luc-pA-attB-Puro-pA; Cat.# PIN610A-1) inserts a luciferase marker into the PinPoint attP site and includes a promoterless puromycin marker—proper integration into a PinPoint attP site inserted using any of SBI’s PinPoint Placement Vectors (Cat.#s PIN300A-1PIN400A-1, and PIN410A-1) results in a PGK promoter positioned to drive the puromycin marker, enabling selection for the desired integrants. The vector also includes a LoxP site to mediate removal of most of the unnecessary vector sequences and both kanamycin and hygromycin markers for cloning and propagation.
With the PinPoint Targeted Integration System, you can ensure that only a single copy of your transgene is inserted into the genome.
  • Create isogenic cell lines
  • Achieve high-efficiency integration with no insert size-limit
  • Turn cell line construction into a high-throughput process

How It Works

Targeted integration with the PinPoint System

Engineering cells with the PinPoint Targeted Integration System is a two-step process:

Insertion of the PinPoint placement site (PinPoint attP) into the target genome using either the PhiC31 Integrase, which preferentially inserts into transcriptionally active sites of the genome, or the CRISPR/Cas9 System for insertion into a defined locus, such as the AAVS1 Safe Harbor Site.

Integration of a PinPoint Vector into the pre-placed attP site. Integration is mediated by the PinPoint Integrase, which mediates a recombination event between the PinPoint attB site (located on the PinPoint Vector) and the PinPoint attP site (placed into the target genome in step 1). Because the PinPoint Integrase only recognizes your pre-placed PinPoint attP site, you get very stringent control of integration location.

A third optional step involves removal of extra vector sequences using the Cre/Lox system, leaving behind only your expression cassette and a single LoxP site.

Selection for correctly-inserted integrants by puromycin resistance

When you use any of SBI’s PinPoint Placement Vectors (Cat.#s PIN300A-1PIN400A-1, and PIN410A-1) to insert the PinPoint attP site, the PGK promoter on the Placement Vector combines with the promoterless puromycin marker on the CMV-Luc PinPoint Positive Control Donor Vector to enable puromycin selection only if the PinPoint Donor Vector integrates at the correct site.

Supporting Data

See the PinPoint Targeted Integration System in action

Figure 1. Efficient placement of the PinPoint attP site using the PhiC31 System. Step 1 of the PinPoint Targeted Integration System—the PinPoint attP site was placed into HEK293 cells using the PinPoint-FC Placement Vector (Cat.# PIN300A-1) and the PhiC31 Integrase (Cat.# FC200PA-1).

Positive cells were selected with G418 (neomycin resistance) for fourteen days and six separate lines were picked and expanded. After eleven days, the cells were fixed and stained with a solution of 50% methanol plus 1% methylene blue. The plates were washed twice with PBS and allowed to air dry. Only the plate of cells that were transfected with the PhiC31 Integrase Expression Plasmid showed a robust number of cells.

Figure 2. Targeted integration with the PinPoint Integrase and a PinPoint Donor Plasmid. Step 2 of the PinPoint Targeted Integration System—the cell lines created in Figure 1 were transfected with a Positive Control PinPoint Gene Donor Vector expressing GFP (Cat.# PIN600A-1) for precise integration.

Unlike the R4 integrase used in a similar system, the PinPoint Integrase does not recognize pseudo-sites and will only integrate at its placed recognition sequence. This feature results in the increased efficiency of correctly retargeted cell lines compared to the R4 integrase system. The entire therapeutic gene expression cassette is active and fully insulated with cHS4 DNA elements.

Figure 3. The PinPoint Integrase mediated specific placement of the PinPoint Donor Vector. We used a junction PCR assay to verify that the PinPoint Donor Vector was integrated at the correct site targeted to the correct site, amplifying across the PinPoint attL site (after PinPoint mediated integration, the plasmid-borne PinPoint attP and attB sites become genomic attL and attR sites). The appearance of bands in the L1, L2, and L3 lanes only indicate the predicted, PinPoint Integrase-mediated insertion of the PIN600A-1 Donor Vector at the placed PinPoint attP site with high precision.

 

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