N-terminal PelB secretory signal peptide and CMyc epitope tag plasmid. This bacterial expression vector has no protease cleavage tag to remove the tag. The signal peptide itself is removed during secretion.
Product Name: pSF-OXB20-NH2-PelB-CMyc
Product Code: OG3151
Size (bp): 3944 bp
Bacterial Antibiotic Selection: KanR
Origin and Compatibility: pUC high copy derived from pBR322
Bacterial Copy Number: 500-700 per cell
Promoter: OXB20 strong constitutive bacterial promoter
This plasmid is designed to express tagged proteins in E.coli. The plasmid contains a constitutive promoter (OXB20) derived from the region upstream of the E.coli RecA gene. It does not require induction or any additional components for activity. It is the strongest of the bacterial promoters that we provide and this high level of expression can cause expression problems with some proteins with poor solubility. For this reason we sell a range of bacterial promoters with different expression levels (OXB1(low)>OXB20(high)) that can be provided with the peptide tags in this plasmid on request.Promoter Expression Level:
This plasmid contains a constitutive bacterial promoter that does not require induction. It is the strongest bacterial promoter we sell and this can cause solubility and expression problems with some proteins. We also offer a range of other bacterial promoters that are compatible with this plasmid and are available on request.
About the Peptide Tag:
This plasmid contains an Pectate Lyase B (PelB) secretory signal peptide (SP) to allow proteins to be exported from the cytosol. During translocation from the cytosol the signal peptide is removed from the protein by endogenous proteases.
This plasmid also contains a secondary C-Myc protein tag. The sequence of this tag is: EQKLISEEDL
We provide a range of dual peptide tag plasmids. This is because some peptide tags provide specific biological properties (e.g small molecule affinity new epitopes solubility or protein secretion) that are not provided by others.
This plasmid contains three alternative transcription terminators for mammalian bacterial and bacteriophage (T7) expression. This means that only the promoter needs to be changed to alter the expression system you are using. We sell multiple promoters that can be used in each of these systems. The presence of each terminator does not reduce expression in the alternative systems.
This plasmid has been designed to allow three types of cloning into the main MCS to join a coding sequence with the tag.1: SnapFusion Cloning:
If you would like to fuse your coding sequence to the tag with minimal additional bases you can use our SnapFusion technology. This process involves amplifying your gene by PCR to add specific restriction sites onto the ends. When these sites are cut they produce an overhang that is compatible with this plasmid cut with BseRI or BsgI.To insert your gene:
1: Amplify your gene with primers designed using this spreadsheet
2: Cut the plasmid with either BseRI or BsgI.*
3: Cut your gene with the enzyme you added using the spreadsheet (any of AcuI BpmI BpuEI BseRI BsgI EciI).
4: Clone the gene into the plasmid using DNA ligase.
Using this method with an N-terminal tag plasmid will result in the tag coding sequence immediately followed by your genes ATG start codon at the join. This results in a seamless fusion of the two sequences with no extra bases being added. Using this method on C-terminal tag plasmids will convert your genes stop codon into a TAC (Tyr Y) codon followed by the plasmid tag coding sequence. This results in no extra bases between your gene and the tag. See the diagram below for more information.
*Please note that insect expression plasmids cannot be cut with BsgI only BseRI because of unavoidable conflicting sites in the backbone. Also Yeast plasmids cannot be cut with BseRI because of unavoidable restriction sites in the backbone.
Using this technique will create a gene fragment that can be ligated into any or our >1500 peptide and reporter tag plasmids. If you use one of the other techniques below (Gibson InFusion Seamless or LIC) you will need new primers for every vector you clone into because the arms of homology will change according to the tag plasmid you are cloning into.
If you find that your gene sequence has sites in it that make using this cloning strategy difficult you can still use one of the alternative methods below (e.g. standard cloning or Gibson cloning).
Open the Primer Design Tool to help you design primers for cloning your gene in our SnapFusion technique.2: Standard Enzymes:
If you are not concerned about leaving a few extra bases between the tag coding sequence and your gene you can clone your gene into the vector using standard cloning restriction enzymes. This strategy will require you to choose which enzymes you want to use to clone your gene.
Open the Primer Design Tool which provides primers with different enzyme choices positioning your gene as close to the tag as possible in each case. Please note that standard enzymes will always leave additional nucleotides between your gene and the tag but using the spreadsheet will ensure the tag and gene are in frame.3: Gibson cloning/InfusionHD/GeneArt Seamless/Ligase Independent Cloning (LIC) Methods:
These cloning techniques use reagents sold by other companies and allow you to fuse sequences together using enzymes that chew back the DNA to leave overlapping ends/overhangs. The subsequent method of joining the DNA depends on the kit used. To use one of these techniques you can either design your own primers or you can use the spreadsheet below to help with the design.
Open the Primer Design Tool to help you design primers for cloning your gene using Gibson assembly InfusionHD GeneArt Seamless cloning or Ligase Independent Cloning (LIC) techniques.