Recombinant Human Glycogen synthase kinase-3 beta (GSK3B)(K85P)

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CUSABIO TECHNOLOGY LLC
CUSABIO TECHNOLOGY LLC
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Overview
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Recombinant Human Glycogen synthase kinase-3 beta (GSK3B)(K85P) from Homo sapiens (Human). produced in E.coli spanning 1-420aa(K85P) C-terminal 6xHis-tagged 85% as determined by SDS-PAGE. Commonly used in Neuroscience studies, including workflows such as measure gsk3b enzymatic activity with defined substrates/cofactors (in vitro assay), evaluate inhibitor/activator effects on gsk3b activity across a concentration series.
Target GSK3B
Species Homo sapiens (Human)
Conjugate(s) C-terminal 6xHis-tagged
Expression System E.coli
Expression Region 1-420aa(K85P)
Options selector
Catalog no. Size
CSB-EP009963HU(M1)c7-1MG 1 mg
CSB-EP009963HU(M1)c7-100UG 100 ug
CSB-EP009963HU(M1)c7-20UG 20 ug
Available Options

Select the variant that best fits your experiment. Availability and lead time may vary by option.

  • Options: Size (3) - 1 mg, 100 ug, 20 ug
  • Lead time: typically ships in ~13-23 business days; timing may vary by selected option.
  • Storage: The shelf life is related to many factors, storage state, buffer ingredients, storage temperature and the stability of the protein itself. Generally, the shelf life of liquid form is 6 months at -20℃/-80℃. The shelf life of lyophilized form is 12 months at -20℃/-80℃.
  • Shipping: cold-chain shipment (typically with ice packs).
  • Upon receipt: store at the recommended temperature as soon as possible.
  • Sales terms and conditions: Please review prior to ordering.
Field Specification
Mfr No CSB-EP009963HU(M1)c7
Activity
  • Not Test
Alternative Names Serine/threonine-protein kinase GSK3B
Conjugate
  • C-terminal 6xHis-tagged
Endotoxin Level Not test
Expression System
  • E.coli
Form Liquid or Lyophilized powder
Molecular Weight 47.8 kDa
Product Type
  • Proteins & Peptides
  • Recombinant Proteins
  • Enzyme & Protease
Protein Length Full Length
Purity Greater than 85% as determined by SDS-PAGE.
Reconstitution We recommend that this vial be briefly centrifuged prior to opening to bring the contents to the bottom. Please reconstitute protein in deionized sterile water to a concentration of 0.1-1.0 mg/mL.We recommend to add 5-50% of glycerol (final concentration) and aliquot for long-term storage at -20℃/-80℃. Our default final concentration of glycerol is 50%. Customers could use it as reference.
Species Homo sapiens (Human)
Storage The shelf life is related to many factors, storage state, buffer ingredients, storage temperature and the stability of the protein itself. Generally, the shelf life of liquid form is 6 months at -20℃/-80℃. The shelf life of lyophilized form is 12 months at -20℃/-80℃. Repeated freezing and thawing is not recommended. Store working aliquots at 4℃ for up to one week.
Target GSK3B
UniProt # P49841

Overview

Recombinant Human Glycogen synthase kinase-3 beta (GSK3B)(K85P) is a recombinant protein preparation derived from Homo sapiens (Human). It is commonly used as a defined reagent for assay development, binding studies, and analytical controls where consistent protein specifications are required.

Key elements and design rationale

  • Expressed region: 1-420aa(K85P).
  • Expression system: E.coli (may influence folding and post-translational modifications).
  • Tag/format: C-terminal 6xHis-tagged; Liquid or Lyophilized powder.
  • Expected size: 47.8 kDa (as provided).
  • Purity: Greater than 85% as determined by SDS-PAGE.

Region choice, expression system, and tag/format can influence folding, post-translational modifications, and interaction behavior in downstream assays.

Biological background

Constitutively active protein kinase that acts as a negative regulator in the hormonal control of glucose homeostasis, Wnt signaling and regulation of transcription factors and microtubules, by phosphorylating and inactivating glycogen synthase (GYS1 or GYS2), EIF2B, CTNNB1/beta-catenin, APC, AXIN1, DPYSL2/CRMP2, JUN, NFATC1/NFATC, MAPT/TAU and MACF1. Requires primed phosphorylation of the majority of its substrates. In skeletal muscle, contributes to insulin regulation of glycogen synthesis by phosphorylating and inhibiting GYS1 activity and hence glycogen synthesis. May also mediate the development of insulin resistance by regulating activation of transcription factors. Regulates protein synthesis by controlling the activity of initiation factor 2B (EIF2BE/EIF2B5) in the same manner as glycogen synthase. In Wnt signaling, GSK3B forms a multimeric complex with APC, AXIN1 and CTNNB1/beta-catenin and phosphorylates the N-terminus of CTNNB1 leading to its degradation mediated by ubiquitin/proteasomes. Phosphorylates JUN at sites proximal to its DNA-binding domain, thereby reducing its affinity for DNA. Phosphorylates NFATC1/NFATC on conserved serine residues promoting NFATC1/NFATC nuclear export, shutting off NFATC1/NFATC gene regulation, and thereby opposing the action of calcineurin. Phosphorylates MAPT/TAU on 'Thr-548', decreasing significantly MAPT/TAU ability to bind and stabilize microtubules. MAPT/TAU is the principal component of neurofibrillary tangles in Alzheimer disease. Plays an important role in ERBB2-dependent stabilization of microtubules at the cell cortex. Phosphorylates MACF1, inhibiting its binding to microtubules which is critical for its role in bulge stem cell migration and skin wound repair. Probably regulates NF-kappa-B (NFKB1) at the transcriptional level and is required for the NF-kappa-B-mediated anti-apoptotic response to TNF-alpha (TNF/TNFA). Negatively regulates replication in pancreatic beta-cells, resulting in apoptosis, loss of beta-cells and diabetes. Through phosphorylation of the anti-apoptotic protein MCL1, may control cell apoptosis in response to growth factors deprivation. Phosphorylates MUC1 in breast cancer cells, decreasing the interaction of MUC1 with CTNNB1/beta-catenin. Is necessary for the establishment of neuronal polarity and axon outgrowth. Phosphorylates MARK2, leading to inhibition of its activity. Phosphorylates SIK1 at 'Thr-182', leading to sustainment of its activity. Phosphorylates ZC3HAV1 which enhances its antiviral activity. Phosphorylates SNAI1, leading to its ubiquitination and proteasomal degradation. Phosphorylates SFPQ at 'Thr-687' upon T-cell activation. Phosphorylates NR1D1 st 'Ser-55' and 'Ser-59' and stabilizes it by protecting it from proteasomal degradation. Regulates the circadian clock via phosphorylation of the major clock components including BMAL1, CLOCK and PER2. Phosphorylates FBXL2 at 'Thr-404' and primes it for ubiquitination by the SCF(FBXO3) complex and proteasomal degradation. Phosphorylates CLOCK AT 'Ser-427' and targets it for proteasomal degradation. Phosphorylates BMAL1 at 'Ser-17' and 'Ser-21' and primes it for ubiquitination and proteasomal degradation. Phosphorylates OGT at 'Ser-3' or 'Ser-4' which positively regulates its activity. Phosphorylates MYCN in neuroblastoma cells which may promote its degradation. Regulates the circadian rhythmicity of hippocampal long-term potentiation and BMAL1 and PER2 expression. Acts as a regulator of autophagy by mediating phosphorylation of KAT5/TIP60 under starvation conditions, activating KAT5/TIP60 acetyltransferase activity and promoting acetylation of key autophagy regulators, such as ULK1 and RUBCNL/Pacer. Negatively regulates extrinsic apoptotic signaling pathway via death domain receptors. Promotes the formation of an anti-apoptotic complex, made of DDX3X, BRIC2 and GSK3B, at death receptors, including TNFRSF10B. The anti-apoptotic function is most effective with weak apoptotic signals and can be overcome by stronger stimulation. Phosphorylates E2F1, promoting the interaction between E2F1 and USP11, stabilizing E2F1 and promoting its activity. Phosphorylates mTORC2 complex component RICTOR at 'Ser-1235' in response to endoplasmic stress, inhibiting mTORC2. Phosphorylates mTORC2 complex component RICTOR at 'Thr-1695' which facilitates FBXW7-mediated ubiquitination and subsequent degradation of RICTOR. Phosphorylates FXR1, promoting FXR1 ubiquitination by the SCF(FBXO4) complex and FXR1 degradation by the proteasome. Phosphorylates interleukin-22 receptor subunit IL22RA1, preventing its proteasomal degradation

Research relevance and current trends

  • Domain- and isoform-aware assay design to improve biological interpretation across model systems.
  • Quantitative workflows emphasizing calibration standards, spike-in controls, and cross-lot comparability.
  • In vitro binding/kinetics profiling (SPR/BLI) to connect biochemical interactions with cellular phenotypes.

Common research applications

  • Measure GSK3B enzymatic activity with defined substrates/cofactors (in vitro assay).
  • Evaluate inhibitor/activator effects on GSK3B activity across a concentration series.
  • Quantify GSK3B using calibration standards in plate-based assays (assay development).
  • Profile binding interactions of GSK3B by SPR/BLI (kinetic characterization).

Interpret results in the context of the biological system, assay format, and any known domain/isoform constraints for the target.

Notes for experimental interpretation

  • Consider species- and isoform-specific differences when comparing results across models or homologs.
  • For quantitative assays, include appropriate negative controls and matrix-matched spike-in concepts to assess non-specific signal.
What is protein expression and purification?
Protein expression is the biotechnological process of generating a specific protein. It can be done in prokaryotic, eukaryotic or In vitro E. coli expression system. Protein purification is a series of processes intended to isolate one or a few proteins from cells or organisms. The most popular method for protein purification is affinity chromatography, and which is designed by different protein tags. Other protein purification methods, including ion exchange chromatography, size-exclusion chromatography, polish purification and hydrophobic interaction chromatography are available to handle tag-free proteins with high purity.
Why is there no/low protein expression?
a. Incorrect vector construction. You should confirm vector by sequencing or apply for our custom clone service.

b. Rare codons. You should optimize codons, use strains supplementing rare codons, induce at lower temperature or grow in poor media.

c. Protein toxicity. You should use promoters with tighter regulation or lower plasmid copy number. Use pLysS/pLysE bearing strains in T7-based systems or strains that are better for the expression of toxic proteins. Start induction at high OD and shorten induction time. Add glucose when using expression vectors containing lac-based promoters.
How to avoid inclusion bodies and improve soluble expression?
a. Proteins with high hydrophobicity or transmembrane domains. You should add fusion tags or add heat shock chaperones. You should induce for a shorter time at low temperature or change to poor media. Generate truncated forms of protein or use membrane rich strains.

b. Incorrect disulfide bond formation. You should add fusion partners, including thioredoxin, DsbA, DsbC. Clone in a vector containing secretion signal peptide to cell periplasm. Use gamiB (DE3)strains with oxidative cytoplasmic environment. Lower inducer concentration and induction temperature.

c. Incorrect folding. You should use a fusion partner. Co-express with molecular chaperones. Use strains with cold-adapted chaperones. Supplement media with chemical chaperones and cofactors. Reduce the inducer concentration and add fresh media. Induce for a shorter time at low temperature.
Why is the molecular weight of protein smaller than the predicted?
a. Rare amino acids selenocysteine (Sec) or pyrrolysine (Pyl) in protein sequence. You should use some other amino acids to instead these two unusual amino acids.

b. Imbalanced translation process of fusion protein. You should change another fusion tag or move fusion tag to C-terminal. You should induce for a shorter time at low temperature or change to poor media.

c. Protein degradation. You should replace specific protease sites. Use protease deficient strains. Induce at high OD. You should induce for a shorter time at low temperature or use protease inhibitors when breaking cells.
Why is the actual band size different from the predicted?
a. Post-translational modification. Phosphorylation, glycosylation, etc which increases the size of the protein.

b. Post-translational cleavage. Many proteins are synthesized as pro-proteins, and then cleaved to give the active form.

c. Splice variants. Alternative splicing may create different sized proteins from the same gene.

d. Relative charge. The composition of amino acids have different relative charge which will affect the electrophoretic mobility.

e. Multimers such as dimerisation of a protein. This is usually prevented in reducing conditions, although strong interactions can result in the appearance of higher bands.

f. Protein structure such as disulfide bond, protein secondary structure or protein 3D structure formation.

g. Hydrophobic proteins, such as transmembrane proteins, may have difficulties in migrating into the gel, and thus resulting in different multi-banded patterns.
How to express a protein with bioactivity? Why is the protein inactive?
For gaining a protein with bioactivity, you should choose a right expression system, a suitable expression vector, an appropriate purification method and a validation experiment. You can learn more from this link: https://www.cusabio.com/c-20275.html. Otherwise, you can check the problems below:

a. Low solubility of the protein. You should fuse desired protein to a fusion partners and lower temperature.

b. Lack of essential post translational modification. You should change another expression system.

c. Incomplete folding. You should use a fusion partner and use strains with cold-adapted chaperones. Co-express with molecular chaperones at lower temperature. Monitor disulfide bond formation and allow further folding in vitro.

d. Mutations in cDNA. You should sequence plasmid before and after induction or use a recA− strain to ensure plasmid stability. Transform E. coli before each expression round.
Why are our protein products almost invisible in pipes?
CUSABIO protein product does not contain carrier protein or other additives (such as bovine serum albumin (BSA), human serum albumin (HSA) and sucrose, and lyophilized from low salt solution, so it often does not form a white grid structure, but a trace amount of protein deposit within the tube, forming a thin transparent or invisible protein layer.

Tips: Before opening the lid, we recommend to centrifuge in a small centrifuge for 20-30 seconds firstly to ensure that the contents are on the bottom of the tube. Our quality control steps ensure that the amount of protein contained in each tube is accurate, although sometimes you can’t see the protein powder, but the protein content in the tube is still very accurate.
How is the protein purified? Is the purity guaranteed?
We will design the optimal purification scheme according to the tag type of the fusion protein and the physicochemical properties of the protein itself. Our common purification methods are: affinity chromatography, hydrophobic chromatography, ion exchange chromatography, molecular sieve, salting out, etc. We guarantee a minimum purity standard of >85%. If the initial purification does not meet this standard or customer has higher purity requirement, we also have AKATA purification instrument, which is highly automated, precise control, combining the use of various column, to ensure that the purity of our protein product is further enhanced and the final purity test results are displayed on the COA report.

Although we guarantee a minimum purity standard of >85%, some of the proteins we prepared have a purity of 95% or even 97%.
How should I reconstitute and store the products?
Centrifugate the reagent tube before opening the cap.

As for short-term storage or usage, please use sterile deionized water to completely reconstitute proteins to 0.1-1.0 mg/mL. Aliquot after 10-15 minutes if needed and store at 4℃.

As for long-term storage, the cytokines or recombinant proteins are recommended to add 5-50% of glycerol (final concentration) and aliquot for long-term storage at -20℃/-80℃. Our default final concentration of glycerol is 50%. Customers could use it as reference.
What types of tags do you use for fusion?
The common tags we provide include His-tag, FLAG-tag, GST-tag, MBP-tag, combination tags (His-GST-tag, His-sumo-tag, His-MBP-tag), etc. Sometimes, the tag of proteins will be determined during the manufacturing process. If you have specified tag type, please feel free to consult with us. Click here to learn more about the general information of different tags.
What is the impact of a given tag type and any potential biological activity of the protein?
Theoretically small tags generally have very small influence on protein activity. However, the specific impact on protein activity can't be concluded (There is no impact on some proteins, small impact on some proteins, and relatively great impact on some proteins).
Can you remove the endotoxin?
Not all endotoxin can be removed. Please communicate with us in advance if you need to remove the endotoxin which takes 2-3 business days. We could offer endotoxin removal service free of charge using PMB affinity chromatography, use LAL reagent to semi-quantitatively detect the content of endotoxin and guarantee endotoxin level within 0.1 ng/μg (1 EU/μg).
Can you offer aseptic manufacture processing?
Yes, we can offer this service and it is free of charge, but you should remark this information when placing the order. We've performed aseptic processing for liquid protein before lyophilization, but there may exist contamination during lyophilization process, so we can't say germ-free for the whole process.
How to determine species cross-reactivity of cytokines?
a. Apart from a few exceptions, most human cytokines are active on mouse cells.

b. Many mouse cytokines may also have effect on human cells, however, the activity may be lower than the corresponding human cytokines.

c. One of the few human cytokines will be more active than corresponding mouse cytokines when acting on mouse cells, such as IL-7.

d. Interferon, GM-CSF, IL-3 and IL-4 and other cytokines are species-specific and almost have no activity on non-homologous cells.

e. In contrast, fibroblast growth factor (FGF) and neurotrophin are highly conserved and both have good activity on cells of different species.
What is the general preservative? Which kind of preservative do you usually add?
Commonly used preservative include Proclin 300, Sodium azide, etc. We do not add any preservative to our proteins.
What is the general protectant? What kind of protectant do you usually add?
Commonly used protectant include saccharides, polyols, polymers, surfactants, some proteins and amino acids etc. We usually add 8% (mass ratio by volume) of trehalose and mannitol as lyoprotectant. Trehalose can significantly prevent the alter of the protein secondary structure, the extension and aggregation of proteins during freeze-drying process; mannitol is also a universal applied protectant and fillers, which can reduce the aggregation of certain proteins after lyophilization.

Can’t Find What You’re Looking For? We can help you source the best match or customize a recombinant protein solution for your study. Options may include species (human/mouse/rat), protein region/domain (full-length vs fragment), tag or label (His/GST/FLAG/biotin/fluorescent), expression system (E. coli/HEK293/insect), purity grade, formulation (buffer, carrier-free, glycerol-free), activity/functional validation (binding or enzymatic assays), endotoxin level (low-endotoxin for cell-based work), mutants/variants (point mutations, isoforms), and bulk or custom packaging. Click Talk to a Scientist to submit a request form, email us at support@biohippo.com, or explore our Research Services for additional support. Our team will be in contact with you shortly.

Why is the actual band size different from the predicted?
a. Post-translational modification. Phosphorylation, glycosylation, etc which increases the size of the protein. b. Post-translational cleavage. Many proteins are synthesized as pro-proteins, and then cleaved to give the active form. c. Splice variants. Alternative splicing may create different sized proteins from the same gene. d. Relative charge. The composition of amino acids have different relative charge which will affect the electrophoretic mobility. e. Multimers such as dimerisation of a protein. This is usually prevented in reducing conditions, although strong interactions can result in the appearance of higher bands. f. Protein structure such as disulfide bond, protein secondary structure or protein 3D structure formation. g. Hydrophobic proteins, such as transmembrane proteins, may have difficulties in migrating into the gel, and thus resulting in different multi-banded patterns.
How should I reconstitute and store the products?
Centrifugate the reagent tube before opening the cap. As for short-term storage or usage, please use sterile deionized water to completely reconstitute proteins to 0.1-1.0 mg/mL. Aliquot after 10-15 minutes if needed and store at 4℃. As for long-term storage, the cytokines or recombinant proteins are recommended to add 5-50% of glycerol (final concentration) and aliquot for long-term storage at -20℃/-80℃. Our default final concentration of glycerol is 50%. Customers could use it as reference.
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Experience the power of Celltrypse™, c-LEcta's innovative enzyme solution for gentle and efficient cell dissociation. Request your free sample and discover a superior alternative for your cell culture workflows.

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