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Recombinant Human ACPL2 Protein (His Tag)– MSE Supplies LLC

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Recombinant Human ACPL2 Protein (His Tag)

SKU: PKSH031183-100

  • £62300
  • Save £7000



Recombinant Human ACPL2 Protein (His Tag)

 

SKU # PKSH031183
Expression Host HEK293 Cells

 

 

Description

Synonyms ACPL2, FLJ23751, UNQ370/PRO706
Species Human
Expression Host HEK293 Cells
Sequence Met 1-Phe 480
Accession NP_689495.1
Calculated Molecular Weight 54.0 kDa
Observed Molecular Weight 50 kDa
Tag C-His
Bio-activity Not validated for activity
  

 

Properties

Purity > 95 % as determined by reducing SDS-PAGE.
Endotoxin < 1.0 EU per μg of the protein as determined by the LAL method.
Storage Generally, lyophilized proteins are stable for up to 12 months when stored at -20 to -80℃. Reconstituted protein solution can be stored at 4-8℃ for 2-7 days. Aliquots of reconstituted samples are stable at < -20℃ for 3 months.
Shipping This product is provided as lyophilized powder which is shipped with ice packs.
Formulation Lyophilized from sterile PBS, pH 7.4
Normally 5% - 8% trehalose, mannitol and 0.01% Tween 80 are added as protectants before lyophilization.
Please refer to the specific buffer information in the printed manual.
Reconstitution Please refer to the printed manual for detailed information.


Background

acid phosphatase-like protein 2, also known as ACPL2, is a secreted protein which belongs to thehistidine acid phosphatase family. A large-scale effort, termed the Secreted Protein Discovery Initiative (SPDI), was undertaken to identify novel secreted and transmembrane proteins. In the first of several approaches, a biological signal sequence trap in yeast cells was utilized to identify cDNA clones encoding putative secreted proteins. A second strategy utilized various algorithms that recognize features such as the hydrophobic properties of signal sequences to identify putative proteins encoded by expressed sequence tags (ESTs) from human cDNA libraries. A third approach surveyed ESTs for protein sequence similarity to a set of known receptors and their ligands with the BLAST algorithm. Finally, both signal-sequence prediction algorithms and BLAST were used to identify single exons of potential genes from within human genomic sequence.