Growth and Differentiation Factor 15 (GDF15) is a member of the TGFβ Superfamily and also a member of the subfamily of Growth Differentiation Factors (GDFs) which play important roles in development. GDF15 has a role in regulating inflammatory and apoptotic pathways during tissue injury and certain disease processes.
Protein Details
Endotoxin Level
<0.1 EU/µg as determined by the LAL method
Biological Activity
The biological activity of Human GDF15D was determined by the inhibition of DU145 cells. The expected ED<sub>50</sub>= 12µg/ml.
The predicted molecular weight of Recombinant Human GDF15D is Mr 26.8 kDa.
Predicted Molecular Mass
26.8
Storage and Stability
The lyophilized protein should be stored desiccated at 20°C. The reconstituted protein can be stored for at least one week at 4°C. For longterm storage of the reconstituted protein, aliquot into working volumes and store at 20°C in a manual defrost freezer. Avoid Repeated Freeze Thaw Cycles.
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Using Recombinant Human GDF15 Dvariant in research is essential when you need to study the biological effects, signaling, or measurement of the naturally occurring Dvariant (H202D, Aspartate at position 202) of GDF15, which is a common human polymorphism. The Dvariant is functionally equivalent to the wildtype in terms of bioactivity, but it can significantly affect immunoassay measurements and is relevant for studies on disease association, biomarker development, and therapeutic targeting.
Key reasons to use the Dvariant in your research:
Genetic Relevance: The Dvariant (H202D) is a naturally occurring polymorphism in the human population, with clinical studies showing it can influence disease risk and prognosis, particularly in cancer and cardiometabolic diseases.
Assay Accuracy: The Dvariant can cause underestimation of GDF15 levels in certain immunoassays (notably those using R&D Systems reagents), which is critical for biomarker studies and clinical research. Using the Dvariant protein allows you to calibrate assays or validate findings in populations carrying this allele.
Functional Studies: The Dvariant has been shown to have indistinguishable bioactivity compared to the wildtype (Hvariant), making it suitable for mechanistic studies on GDF15’s roles in inflammation, metabolism, immune regulation, and tissue injury.
Disease Association: The Dvariant is associated with altered risk and prognosis in several diseases, including colorectal and prostate cancer, making it important for genotypephenotype correlation studies.
Therapeutic Research: GDF15 (including the Dvariant) is a target for therapies in obesity, metabolic syndrome, and cancer, and recombinant protein is used in preclinical models to study its effects on weight loss, glucose metabolism, and immune modulation.
Best practices:
Use the Dvariant when studying populations or diseases where the H202D polymorphism is prevalent or relevant.
Employ the Dvariant for assay calibration to ensure accurate quantification in genetic subgroups.
Confirm the biological activity of your recombinant preparation, as most commercial sources report activity in cellbased assays (e.g., inhibition of DU145 cells).
Summary: Use Recombinant Human GDF15 Dvariant for research requiring genetic specificity, assay accuracy, or functional studies related to the H202D polymorphism, especially in biomarker, metabolic, and immunological research contexts.
Recombinant Human GDF15 Dvariant can be used as a standard for quantification or calibration in ELISA assays, provided the assay is validated to detect this specific variant. The suitability depends on the ELISA's antibody specificity and calibration protocol.
Key considerations:
Variant specificity: The Dvariant of GDF15 contains a His→Asp substitution at position 7. Some ELISA kits are designed to detect total GDF15 (including both H and D variants), while others are Hspecific and do not recognize the Dvariant. For accurate quantification, ensure your ELISA detects the Dvariant. Total GDF15 ELISAs have been shown to quantify both recombinant and natural GDF15 variants equally.
Calibration standards: Many commercial ELISA kits use recombinant human GDF15 (often the Dvariant) as a calibration standard. Recovery experiments demonstrate that recombinant GDF15 can be spiked into biological samples and accurately measured by validated ELISA protocols.
Validation: Before using the Dvariant as a standard, confirm that your assay's antibodies recognize the Dvariant with similar affinity as endogenous GDF15 in your sample matrix. If using a kit, consult the manufacturer's documentation to verify compatibility.
Documentation: Published protocols and kit inserts indicate that recombinant GDF15 (including Dvariant) is routinely used for calibration and recovery studies in ELISA assays for total GDF15.
Best practices:
Validate the standard curve using the recombinant Dvariant in your specific ELISA setup.
Include recovery and dilution linearity controls to confirm assay performance with the Dvariant.
If your assay is Hspecific, the Dvariant will not be detected and is unsuitable as a standard.
Summary Table:
ELISA Type
Detects Dvariant?
Suitable as Standard?
Total GDF15 ELISA
Yes
Yes
Hspecific ELISA
No
No
In conclusion: You can use recombinant human GDF15 Dvariant as a standard for quantification or calibration in ELISA assays if your assay is validated for total GDF15 detection and not restricted to the Hvariant. Always verify antibody specificity and assay documentation before proceeding.
Recombinant Human GDF15 Dvariant has been validated for several applications in published research, primarily related to its biological activity and functional roles in disease models. Key applications include:
Protection of Pancreatic β Cells: Recombinant GDF15 (including the Dvariant) has been shown to protect human pancreatic β cells against proinflammatory cytokinemediated apoptosis and cellular stress. Pretreatment with rGDF15 reduces insulitis and increases β cell survival, suggesting its potential as a therapeutic agent for type 1 diabetes (T1D) prevention and management .
Induction of Muscle Atrophy: GDF15 protein, including recombinant forms, can directly induce muscle atrophy in cultured C2C12 myotubes by regulating apoptotic pathways such as Bcl2/caspase3. This application is relevant for studying cancer cachexia and muscle wasting disorders .
Antiinflammatory and ImmuneRegulatory Effects: GDF15 has demonstrated antiinflammatory functions in various models, including sepsis, where GDF15 knockout mice exhibit heightened inflammatory responses. Recombinant GDF15 is used to study immune checkpoint regulation and its potential as a target for cancer immunotherapy .
Metabolic Regulation and Weight Loss: Treatment with recombinant GDF15 in rodent models fed a highfat diet results in weight loss, reduced liver steatosis, and improved glycemic control. These studies highlight its role in appetite regulation, energy expenditure, and metabolic health .
Biomarker Studies: The Dvariant of GDF15 is used in biomarker research, particularly for early detection of heart disease and heart failure. It is also studied as a prognostic marker for diabetes and cardiovascular disease .
Measurement and Assay Validation: The Dvariant has been specifically studied for its impact on immunoassay measurements, as it can affect the accuracy of GDF15 quantification in clinical and research settings. This is important for interpreting results in studies involving GDF15 as a biomarker [8, 11].
These applications demonstrate the versatility of Recombinant Human GDF15 Dvariant in both basic research and translational studies, particularly in the fields of diabetes, cancer, metabolism, and cardiovascular disease.
To reconstitute and prepare Recombinant Human GDF15 Dvariant protein for cell culture experiments, follow these steps:
Centrifuge the vial briefly before opening to ensure all lyophilized material is at the bottom.
Reconstitute the protein by adding sterile water to achieve a final concentration of 0.1 mg/mL. Gently pipette the solution down the sides of the vial to dissolve the protein completely. Do not vortex, as vigorous mixing can denature the protein.
Allow several minutes for complete dissolution. If necessary, gently swirl or invert the vial.
For longterm storage, aliquot the reconstituted protein into working volumes, dilute with a carrier protein such as 0.1% BSA in PBS, and store at 80°C. Avoid repeated freezethaw cycles to preserve protein integrity.
Preparation for cell culture experiments:
Before use, dilute the reconstituted stock solution to the desired working concentration using sterile cell culture medium or buffer compatible with your assay.
If your application is sensitive to endotoxin, confirm the endotoxin level is below 0.1 EU/µg, which is typical for recombinant GDF15 Dvariant preparations.
For bioactivity assays, typical working concentrations range from ng/mL to µg/mL, depending on cell type and experimental design.
Additional notes:
If your protocol or supplier recommends a different reconstitution buffer (e.g., 4 mM HCl, 5 mM acetic acid, or PBS), use that buffer instead of water, as some recombinant proteins may require acidic conditions for optimal solubility and stability.
Always consult the specific product datasheet for any unique instructions regarding buffer composition or handling.
Summary of best practices:
Centrifuge vial, reconstitute in sterile water (or specified buffer) at 0.1 mg/mL, gentle mixing, aliquot with carrier protein for storage, avoid freezethaw cycles, and dilute to working concentration in cell culture medium for experiments.
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Products are for research use only. Not for use in diagnostic or therapeutic procedures.
