GDF15

Overview

This GenCefe mRNA encodes GDF15, a growth factor construct supplied for antibody validation and cell-based binding assays. The product is formulated as lyophilised, non-encapsulated RNA and is intended for use in cell-based research applications requiring transient protein expression with reduced immunogenicity.

mRNA Construct Design

• 5′ Cap: Cap1 (m7GpppNm) — co-transcriptionally added during in vitro transcription (IVT). Cap1 includes 2′-O-methylation at the first transcribed nucleotide, closely mimicking the cap structure found on endogenous mammalian mRNA and reducing recognition by innate immune sensors (e.g., IFIT1/IFIT3).
• Modified Nucleotides: 100% N1-methylpseudouridine (m1Ψ; N1-Me-Pseudo UTP) substitution for all uridine residues. m1Ψ modification reduces TLR7/TLR8-mediated innate immune activation and PKR-driven translational suppression, resulting in improved protein expression in immunocompetent cells and primary cell types.
• Poly(A) Tail: 100–120 nt — enzymatically polyadenylated. The poly(A) tail stabilises the 3′ terminus, supports poly(A)-binding protein (PABP) recruitment, and enhances ribosome recycling for efficient cap-dependent translation.
• 5′ UTR: hHBA1 (hemoglobin subunit alpha 1 5′ UTR) — a well-characterised human UTR that supports efficient cap-dependent translation initiation.
• 3′ UTR: hHBA1 (hemoglobin subunit alpha 1 3′ UTR) — provides post-transcriptional stability and modulates mRNA decay kinetics.
• Signal Peptide: No
• Protein Tag: No
• Codon Optimisation: No (native human codon usage retained)
• mRNA Length: Provided upon order placement.
• Form: Lyophilised powder; reconstitute in DEPC-treated water as needed.

This mRNA is supplied as non-encapsulated, lyophilised powder. Delivery vehicle selection (LNP, electroporation, lipofection) is at the discretion of the end user and should be optimised for the target cell type and application.

Biological Background

Growth factors are secreted or membrane-bound polypeptides that regulate cell proliferation, survival, differentiation, and migration by binding to specific cell-surface receptors and activating downstream signalling cascades (e.g., MAPK/ERK, PI3K/AKT, JAK/STAT). mRNA-based delivery of growth factors enables transient, dose-controlled protein expression in target cells without the need for stable genomic integration. This approach is particularly relevant for ex vivo cell expansion protocols, stem cell differentiation studies, and functional receptor-ligand binding assays, where precise temporal control of growth factor availability is required.

Research Relevance and Current Trends

• Ex vivo cell manufacturing: Transient mRNA expression of growth factors such as SCF, FLT3L, and TPO is being investigated for short-window stimulation of HSC expansion without chronic cytokine exposure that risks differentiation bias.
• Receptor-ligand interaction studies: Growth factor mRNA provides native-topology ligands for SPR, BLI, and cell-based binding assays validating therapeutic antibody epitopes on receptor ectodomains.
• Tissue engineering scaffolds: Growth factor mRNA is incorporated into hydrogel and scaffold matrices to achieve controlled spatiotemporal protein release in tissue-regeneration models.

Common Research Applications

• Receptor activation assays — transient growth factor mRNA expression stimulates cognate receptors in cell-based reporter assays to characterise ligand-receptor interactions.
• Ex vivo cell expansion — short-duration growth factor mRNA pulses to stimulate haematopoietic or stem cell expansion without chronic cytokine exposure.
• Antibody neutralisation studies — mRNA-expressed secreted growth factors as target antigens in neutralisation bioassays validating anti-growth-factor therapeutic antibodies.

Notes for Experimental Interpretation

• Secreted growth factors expressed from transfected cells are present in conditioned media; ensure downstream assays account for the actual secreted protein concentration rather than mRNA input dose.
• Growth factor receptor expression on the target cell must be confirmed; absence of receptor expression on the transfected cell line may result in undetectable signalling readouts.
• Transient expression windows are typically 24–72 h post-transfection for lyophilised mRNA; titrate dose and time-point empirically for the specific growth factor and cell type.

Can't find the mRNA or circRNA construct you need? We offer custom synthesis and add-on services to help you move your project forward — from sequence design and codon optimization to custom mRNA synthesis and circular RNA (circRNA) production for both in vitro and in vivo applications. Options may include chemically modified mRNA (e.g., N1-methylpseudouridine substitution, Cap1 capping strategy), circRNA synthesis via chemical ligation (short segments ≤100 nt) or IVT-based cyclization (longer constructs ≥200 nt), HPLC purification, and full QC documentation including gel or Bioanalyzer integrity analysis and a Certificate of Analysis. Additional options may include multiple synthesis scales from small research batches to larger quantities, miRNA sponge circRNA constructs, IRES element selection for cap-independent circRNA translation, labels and conjugation, and delivery formulation guidance. We can also assist with negative and scramble control formats and related RNA tools when a catalog product does not meet your specifications. Click Talk to a Scientist to submit a request, email us at support@biohippo.com, or explore our Research Services for additional support. Our team will be in contact with you shortly.