Abcam, ab258434, Human GLRX2 (GRX2) knockout HeLa cell lysate

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GLRX2 KO cell lysate available now. KO validated by. Free of charge wild type control included. Knockout achieved by using CRISPR/Cas9, 10 bp deletion in exon1 and 1 bp deletion in exon1 and 1 bp insertion in exon1.
Key facts
Cell type:HeLa,
Species or organism:Human,
Tissue:Cervix,
Knockout validation:Sanger Sequencing,
Mutation description:Knockout achieved by using CRISPR/Cas9, 10 bp deletion in exon1 and 1 bp deletion in exon1 and 1 bp insertion in exon1.,
Disease:Adenocarcinoma

Product details:
Knockout cell lysate achieved by CRISPR/Cas9.
REACH authorisation
Abcam has not and does not intend to apply for the REACH Authorisation of customers' uses of products that contain European Authorisation list (Annex XIV) substances.
It is the responsibility of our customers to check the necessity of application of REACH Authorisation, and any other relevant authorisations, for their intended uses.
Lysate preparation:
Our lysates are made using RIPA buffer to which we add a protease inhibitor cocktail and phosphatase inhibitor cocktail (ratio: 300:100:10).
This means that the protein of interest is denatured.
If you require a native form of the protein please use the live cell version. Please refer to our lysis protocol for further details on how our lysates are prepared.
User storage instructions:
Lyophilizate may be stored at 4°C. After reconstitution, store at -20°C for short-term storage or -80°C for long-term storage.
This product is subject to limited use licenses from The Broad Institute, ERS Genomics Limited and Sigma-Aldrich Co. LLC, and is developed with patented technology. For full details of the licenses and patents please refer to our
limited use license
patent pages

Properties and Storage Information:
Gene name-GLRX2, Gene editing type-Knockout, Gene editing method-CRISPR technology, Knockout validation-Sanger Sequencing, Shipped at conditions-Ambient - Can Ship with Ice, Appropriate short-term storage conditions--20°C, Appropriate long-term storage conditions--20°C

Supplementary Information:
This supplementary information is collated from multiple sources and compiled automatically.
The target GRX2 also commonly known as GLRX2 is a human protein encoded by the GLRX2 gene. GRX2 functions as a glutaredoxin a type of enzyme involved in the process of reducing disulfide bonds in proteins which is essential for cell redox regulation. The protein has a molecular mass of approximately 16 kDa and primarily resides in the mitochondria and cytoplasm of cells. Its expression occurs in various tissues with significant levels in the heart brain and skeletal muscle indicating its broad functional roles across different organ systems.
Biological function summary
The GRX2 protein plays a critical role in maintaining cellular redox balance by facilitating the reversible oxidation of protein cysteines. This is important for protecting cells against oxidative stress. GRX2 does not function as an isolated entity but instead forms part of larger multi-protein complexes interacting with other enzymes to regulate cellular homeostasis. These interactions help to protect cells from oxidative damage promote protein folding and regenerate other antioxidants.
Pathways
GRX2 holds a significant position in the redox regulation and antioxidant pathways. It partners with thioredoxin reductase and glutathione systems to mediate these pathways and manage cellular oxidative stress. The protein's activity is closely tied to glutathione with GRX2 often acting in synergy with glutathione to reduce complex oxidized protein thiols. This collaboration is vital in the oxidative stress response where the pathway elements must efficiently counterbalance oxidative challenges.
GRX2's function links it to several oxidative stress-related conditions including neurodegenerative diseases and cardiovascular disorders. In neurodegenerative diseases like Parkinson's disease GRX2's ability to combat oxidative stress is compromised leading to neuronal damage. Additionally the protein's interaction with other redox regulatory proteins such as thioredoxin suggests interconnected roles in the progression of these disorders. Cardiovascular diseases also involve GRX2 due to its essential function in maintaining cardiovascular integrity under environmental and metabolic oxidative stress.