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Wählen Sie konfigurierbare Panels & Premixed-Kits - ODER - Kits für die zelluläre Signaltransduktion & MAPmates™
Konfigurieren Sie Ihre MILLIPLEX® MAP-Kits und lassen sich den Preis anzeigen.
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Kits für die zelluläre Signaltransduktion & MAPmates™
Wählen Sie gebrauchsfertige Kits zur Erforschung gesamter Signalwege oder Prozesse. Oder konfigurieren Sie Ihre eigenen Kits mit Singleplex MAPmates™.
Die folgenden MAPmates™ sollten nicht zusammen analysiert werden: -MAPmates™, die einen unterschiedlichen Assaypuffer erfordern. -Phosphospezifische und MAPmate™ Gesamtkombinationen wie Gesamt-GSK3β und Gesamt-GSK3β (Ser 9). -PanTyr und locusspezifische MAPmates™, z.B. Phospho-EGF-Rezeptor und Phospho-STAT1 (Tyr701). -Mehr als 1 Phospho-MAPmate™ für ein einziges Target (Akt, STAT3). -GAPDH und β-Tubulin können nicht mit Kits oder MAPmates™, die panTyr enthalten, analysiert werden.
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48-602MAG
Buffer Detection Kit for Magnetic Beads
1 Kit
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Anti-Pras40 Antibody, Clone 73P21 is an antibody against Pras40 for use in IP & WB.
More>>Anti-Pras40 Antibody, Clone 73P21 is an antibody against Pras40 for use in IP & WB. Less<<
Anti-Pras40 Antibody, Clone 73P21: SDB (Sicherheitsdatenblätter), Analysenzertifikate und Qualitätszertifikate, Dossiers, Broschüren und andere verfügbare Dokumente.
PRAS40 (Proline Rich Akt Substrate, 40 kDa), also known as AKT1S1, is a ubiquitously express protein that is phosphorylated on residue Thr246 via the PI3K/Akt pathway. It was originally discovered as an Akt substrate as it has the putative Akt phosphorylation motif of RxRxxpS/pT2. This phosphorylation allows it to bind 14-3-3 and Raptor of the mTOR complex mTORC1. PRAS40 is known to bind to and regulate mTORC1 (mTOR, Raptor, mLST8) kinases activity that is activated by insulin downstream of PI3K and Akt and subsequently phosphorylates p70S6K and 4EBP1. PRAS40 is known to have a putative TOS motif (FVMDE) that allows it bind to Raptor of mTORC1 in the absence of insulin1. It is thought that through it binding to the Raptor, PRAS40 inhibits the kinase activity of mTORC1 by preventing to bind to its substrates such as p70S6K and 4EBP1.
References
Product Information
Format
Purified
Control
RIPA lysates of HeLa cells.
Presentation
Purified mouse monoclonal IgG1 in buffer containing PBS with 1% BSA and 0.1% sodium azide.
AKT1S1 is a proline-rich substrate of AKT (MIM 164730) that binds 14-3-3 protein (see YWHAH, MIM 113508) when phosphorylated (Kovacina et al., 2003 [PubMed 12524439]).[supplied by OMIM]
FUNCTION: SwissProt: Q96B36 # May play an important role in phosphatidylinositol 3- kinase (PI3K)-AKT1 survival signaling. Substrate for AKT1 phosphorylation, but can also be activated by AKT1-independent mechanisms. Its role in survival signaling pathways may be modulated by oxidative stress. May also play a role in nerve growth factor-mediated neuroprotection. SIZE: 256 amino acids; 27383 Da SUBUNIT: The phosphorylated form interacts with 14-3-3. SUBCELLULAR LOCATION: Cytoplasm, cytosol (By similarity). Note=Found in the cytosolic fraction of the brain (By similarity). TISSUE SPECIFICITY: Widely expressed with highest levels of expression in liver and heart. Expressed at higher levels in cancer cell lines (e.g. A549 and HeLa) than in normal cell lines (e.g. HEK293).
Molecular Weight
40 kDa
Physicochemical Information
Dimensions
Materials Information
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Safety Information according to GHS
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Product Usage Statements
Quality Assurance
Routinely evaluated by western blot.
Western Blot Analysis: A 0.1-1.0 µg/mL dilution of this lot detected PRAS40 in RIPA lysates of HeLa cells.
Usage Statement
Unless otherwise stated in our catalog or other company documentation accompanying the product(s), our products are intended for research use only and are not to be used for any other purpose, which includes but is not limited to, unauthorized commercial uses, in vitro diagnostic uses, ex vivo or in vivo therapeutic uses or any type of consumption or application to humans or animals.
Storage and Shipping Information
Storage Conditions
Stable for 1 years at -20°C from date of receipt.
Handling Recommendations: Upon first thaw, and prior to removing the cap, centrifuge the vial and gently mix the solution. Aliquot into microcentrifuge tubes and store at -20°C. Avoid repeated freeze/thaw cycles, which may damage IgG and affect product performance.
Evaluating the therapeutic potential of mTOR inhibitors using mouse genetics. Huawei Li,Jennifer L Cotton,David A Guertin Methods in molecular biology (Clifton, N.J.)
821
2011
Extensive efforts are underway to develop small-molecule inhibitors of the mammalian target of rapamycin (mTOR) kinase. It is hoped that these inhibitors will have widespread clinical impact in oncology because mTOR is a major downstream effector of PI3K signaling, one of the most frequently activated pathways in cancer. In cells, mTOR is the catalytic core subunit of two distinct complexes, mTORC1 and mTORC2, which are defined by unique mTOR-interacting proteins and have unique functions downstream of PI3K. Two classes of mTOR inhibitors are currently being evaluated as cancer therapeutics: rapamycin and its analogs, which partially inhibit mTORC1 and in some cell types mTORC2, and the recently described ATP-competitive inhibitors, which inhibit the kinase activity of both complexes. Although small molecules that selectively target mTORC2 do not yet exist, experiments using mouse genetics suggest that a theoretical mTORC2 inhibitor may have significant therapeutic value. Here, we discuss an approach to model mTOR complex specific inhibitors using mouse genetics and how it can be applied to other gene products involved in oncogenic signaling to which inhibitors do not exist.
Ingestion of whey or casein yields divergent patterns of aminoacidemia that influence whole-body and skeletal muscle myofibrillar protein synthesis (MPS) after exercise. Direct comparisons of the effects of contrasting absorption rates exhibited by these proteins are confounded by their differing amino acid contents.Our objective was to determine the effect of divergent aminoacidemia by manipulating ingestion patterns of whey protein alone on MPS and anabolic signaling after resistance exercise.In separate trials, 8 healthy men consumed whey protein either as a single bolus (BOLUS; 25-g dose) or as repeated, small, "pulsed" drinks (PULSE; ten 2.5-g drinks every 20 min) to mimic a more slowly digested protein. MPS and phosphorylation of signaling proteins involved in protein synthesis were measured at rest and after resistance exercise.BOLUS increased blood essential amino acid (EAA) concentrations above those of PULSE (162% compared with 53%, P less than 0.001) 60 min after exercise, whereas PULSE resulted in a smaller but sustained increase in aminoacidemia that remained elevated above BOLUS amounts later (180-220 min after exercise, P less than 0.05). Despite an identical net area under the EAA curve, MPS was elevated to a greater extent after BOLUS than after PULSE early (1-3 h: 95% compared with 42%) and later (3-5 h: 193% compared with 121%) (both P less than 0.05). There were greater changes in the phosphorylation of the Akt-mammalian target of rapamycin pathway after BOLUS than after PULSE.Rapid aminoacidemia in the postexercise period enhances MPS and anabolic signaling to a greater extent than an identical amount of protein fed in small pulses that mimic a more slowly digested protein. A pronounced peak aminoacidemia after exercise enhances protein synthesis. This trial was registered at clinicaltrials.gov as NCT01319513.
