Mouse Anti-Arabidopsis AT3G53180 Antibody (CBMOAB-15333FYC)


Cat: CBMOAB-15333FYC
Certificate of Analysis Lookup
To download a Certificate of Analysis, please enter a lot number in the search box below. Note: Certificate of Analysis not available for kit components.
Lot Number

Size:
Conjugate:
 Inquiry
  • Product Details

Specifications

Host speciesMouse (Mus musculus)
Species ReactivityA. thaliana (Arabidopsis thaliana)
CloneMO15333FC
SpecificityThis antibody binds to Arabidopsis AT3G53180.
FormatLiquid or Lyophilized
StorageStore at 4°C: short-term (1-2weeks)
Store at -20°C: long-term and future use
Purity> 90% was determined by SDS-PAGE
PurificationPurified with Protein A or G affinity chromatography
Cellular LocalizationCytosol

Application Information

ApplicationWB, ELISA
Application NotesELISA: 1:1000-1:3000
Other applications are to be developed. The optimal dilution should be determined by the end user.

Target

IntroductionIn Arabidopsis, At3g53180 represents a functionally characterized homologue of the γ-glutamine polyamine synthase from Streptomyces coelicolor M145 (SCO6962). Although the molecular function of At3g53180 is unknown, its mutation results in inhibited taproot growth, reduced meiotic activity in cell division zones, and disturbed root cap development. Further functional characterization of At3g53180 may reveal a novel putrescine catabolism pathway in plants.
Product OverviewMouse Anti-Arabidopsis AT3G53180 Antibody is a mouse antibody against AT3G53180. It can be used for AT3G53180 detection in Western Blot, Enzyme-Linked Immunosorbent Assay.
Alternative NamesNodulin/glutamine synthase-like protein; At3g53180
UniProt IDF4J9A0
Protein RefseqThe length of the protein is 852 amino acids long. The sequence is show below: MEFSELKEAIEKIELVDAHAHNIVSLDSSFPFIGTFSEAAGDALTFAPHSLSFKRNLREIAQLYGTEVSLEAVEEHRKTSGLDSFTSKCFKEARISALLIDDGLKLDKKHDIEWHRNFVPFVGRVLRIETLAEQILEEECPGGYFYGSESTEPPVWDLDSFTKTFVERLNSLVPEIVALKTIAAYRSGLDIDTYVSKEVAENGLVEVLRAGKPVRIGNKGLIDYILTISLEVAVRRDLPLQIHTGFGDKDLDLRLSNPLHLRTLLEDKRFGKCRIVLLHAAYPFSKEASFLSSVYPQVYLDFGLAVPKLSVHGMVSSVKELLDLASIKKVMFSTDGYASPETYYLGAKKAREVIFLVLSDACASGDLSLMEAIDAAKDIFSRNSIGFYKLNIDTDSSSPQNIISPKLKIKEPDVQEDSSSFVRIIWVDTSGQQRCRAVQAQRFNRSVKKNGVGLTFASMGMTSFTDGPAEESKLTGVGEIRLVPDLSTKQTIPWTKQESMVLADMQLKPGEAWGYCPRETLRRVAKVLKDEFDLVMNAGFENEFYLLKNVVREGKEEYMPFDFGPYCATSSFDAASPIFHDIVPALESLNIEVEQFHAESGKGQFEVSLGHTIASHAADNLVYTREVIRSVARKQGLLATFVPKYDYCDIGSGSHVHLSLWKNGENVFPASNNSSSHGISSVGEEFMAGVLFHLPSILAIIAPLPNSYDRIQPNTWSGAFQCWGKENREAALRAASPPGTPDGLVTNFEIKSFDGSANPHLGLAVIMAAGIDGLRRHLQLPTPIDINPADVAATLNRLPETLSEAVEALDKDKVLHDLLGQKLLVAIKGVRKAEVEYYSKNPDAYKQLIHRY.

Reference

Reference1. Shimizu, Y., Rai, A., Okawa, Y., Tomatsu, H., Sato, M., Kera, K., ... & Yamazaki, M. (2019). Metabolic diversification of nitrogen-containing metabolites by the expression of a heterologous lysine decarboxylase gene in Arabidopsis. The Plant Journal, 100(3), 505-521.
2. Badia, M. B., Maurino, V. G., Pavlovic, T., Arias, C. L., Pagani, M. A., Andreo, C. S., ... & Gerrard Wheeler, M. C. (2020). Loss of function of Arabidopsis NADP-malic enzyme 1 results in enhanced tolerance to aluminum stress. The Plant Journal, 101(3), 653-665.
For Research Use Only | Not For Clinical Use.
Online Inquiry