PP2381
Yeast Signal Peptide Vector Set
plasmid vectors for molecular cloning
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Synonym(s):
cloning vector, expression vector, molecular cloning vector, plasmid, plasmid vector, snapfast vector, vector
UNSPSC Code:
12352200
NACRES:
NA.85
Recommended Products
tag
6-His tagged
form
buffered aqueous solution
bacteria selection
kanamycin
Origin of replication
2Micron
pUC (500 copies)
Peptide cleavage
TEV
no cleavage
Peptide tag location
N-terminal
Promoter
Promoter name: TEF1
Promoter activity: constitutive
Promoter type: yeast
Secretion signal
Inulase
alpha factor FL
alpha factor SP
alpha-amylase
glucoamylase
shipped in
ambient
storage temp.
−20°C
General description
Molecular cloning often benefits from optimizing the vector used for expression.
Yeast signal peptide vector set allows you to compare the activity of nine different yeast secretory tags (signal peptides) to identify which is preferred for your gene of interest. The most efficient tag seems to depend on the protein of interest and also on the cells used, hence we consider it important to compare several tags in order to select the best. Inserting your gene of interest into the MCS of these plasmids will place it downstream of the signal peptide, under regulatory control of the strong yeast TEF1 promoter.This plasmid set has been designed to be compatible with a range of cloning techniques. The multiple cloning site contains a range of standard commonly used restriction sites for cloning. Using these sites genes can be inserted using standard cloning methods with DNA ligase. Other methods such as ligase independent cloning (LIC) Gibson Assembly InFusionHD or Seamless GeneArt can also be used and because all of our plasmids are based on the same backbone the same method can be used for cloning into all of our catalogue vectors.
Multiple cloning site notes: There are a few important sites within the MCS. These include the NcoI site the XbaI site and the BsgI and BseRI sites. The NcoI site contains a start codon that is immediately downstream of both a Kozak and Shine-Dalgarno ribosomal binding site. These allow for optimal positioning of genes when the start codon is placed in this location. If this is not required and you wish to use a downstream site for gene cloning you can remove the NcoI site by cleaving the plasmid with KpnI. The XbaI site contains a stop codon. This stop codon is positioned in a specific position in relation to the BsgI and BseRI sites that are immediately downstream. When either BseRI or BsgI cleave the plasmid they produce a TA overhang from the stop codon in the XbaI site that is compatible with all of our peptide tag plasmids cut with the same sites. BseRI and BsgI sites are non-palindromic and cleave a defined number of bases away from their binding site. Whenever we clone a gene into our multiple cloning site we always position the start and stop codon in the same positions in the MCS. If the start and ends of the genes are not compatible with NcoI and XbaI we extend the sequence to the nearest external sites but keep the start and stop codons locations consistent.
Transcription Termination: Plasmids for molecular cloning 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.
Yeast signal peptide vector set allows you to compare the activity of nine different yeast secretory tags (signal peptides) to identify which is preferred for your gene of interest. The most efficient tag seems to depend on the protein of interest and also on the cells used, hence we consider it important to compare several tags in order to select the best. Inserting your gene of interest into the MCS of these plasmids will place it downstream of the signal peptide, under regulatory control of the strong yeast TEF1 promoter.This plasmid set has been designed to be compatible with a range of cloning techniques. The multiple cloning site contains a range of standard commonly used restriction sites for cloning. Using these sites genes can be inserted using standard cloning methods with DNA ligase. Other methods such as ligase independent cloning (LIC) Gibson Assembly InFusionHD or Seamless GeneArt can also be used and because all of our plasmids are based on the same backbone the same method can be used for cloning into all of our catalogue vectors.
Multiple cloning site notes: There are a few important sites within the MCS. These include the NcoI site the XbaI site and the BsgI and BseRI sites. The NcoI site contains a start codon that is immediately downstream of both a Kozak and Shine-Dalgarno ribosomal binding site. These allow for optimal positioning of genes when the start codon is placed in this location. If this is not required and you wish to use a downstream site for gene cloning you can remove the NcoI site by cleaving the plasmid with KpnI. The XbaI site contains a stop codon. This stop codon is positioned in a specific position in relation to the BsgI and BseRI sites that are immediately downstream. When either BseRI or BsgI cleave the plasmid they produce a TA overhang from the stop codon in the XbaI site that is compatible with all of our peptide tag plasmids cut with the same sites. BseRI and BsgI sites are non-palindromic and cleave a defined number of bases away from their binding site. Whenever we clone a gene into our multiple cloning site we always position the start and stop codon in the same positions in the MCS. If the start and ends of the genes are not compatible with NcoI and XbaI we extend the sequence to the nearest external sites but keep the start and stop codons locations consistent.
Transcription Termination: Plasmids for molecular cloning 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.
Sequence
For Genebank sequence, FASTA sequence, Quick-reference Plasmid Map, and Full Plasmid Map, see the individual vector product page for links.
Analysis Note
To view the Certificate of Analysis for this product, please visit www.oxfordgenetics.com.
Other Notes
Looking for more vector options to move your experiments forward faster? Consider a custom cloning vector designed and built by Oxford Genetics™. Find out more at Oxford Genetics - Sigma's partner for cloning and expression vectors for molecular biology and synthetic biology applications.
Legal Information
These plasmids are sold free of reach-through rights and can be used to make commercial products. However the plasmids themselves (or derivatives) cannot be sold.
Oxford Genetics is a trademark of Oxford Genetics Ltd
Kit Components Also Available Separately
Product No.
Description
SDS
- PSF-TEF1-NH2-A-FACTOR SP - ALPHA FACTOR SECRETION PLASMID, plasmid vector for molecular cloning
- PSF-TEF1-NH2-GLUCA - GLUCOAMYLASE SECRETION PLASMID, plasmid vector for molecular cloning
- OGS1879PSF-TEF1-NH2-INTS - INVERTASE SECRETION PLASMID, plasmid vector for molecular cloningSDS
related product
Product No.
Description
Pricing
Flash Point(F)
Not applicable
Flash Point(C)
Not applicable
Regulatory Information
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Certificates of Analysis (COA)
Search for Certificates of Analysis (COA) by entering the products Lot/Batch Number. Lot and Batch Numbers can be found on a product’s label following the words ‘Lot’ or ‘Batch’.
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