Interferon (IFN) Family Proteins

Home
Products

products by category

Recombinant proteins
GMP Grade CytokinesNew Fc receptor proteins FcRn Proteins IgG Fc Proteins (Isotype Control) CGT development solutions New Key raw materials for CGT New Targets of CAR-T cell therapy Solid Tumor CAR Targets New CAR Targets for Hematological Malignancies New New Generation Tools for CAR DetectionStar Staining Solutions for T Cell Activation and Culture New FDA DMF filed proteins Multi-pass TpsHot Immune checkpoint proteins Agonist Target Proteins ADC targets BsAb targets TME pathway targets Cytokine TargetsHot Enzymes Enzymes for In-Depth Antibody Characterization New Llama IgG Fc fusion protein Interleukin Protein Families Hot Biosimilar drug targets Biomarkers & CD antigens All recombinant proteins

Antibodies
Anti-idiotypic antibody Anti-FMC63 mAb Neutralizing antibodies IgG Isotype Control Immunohistochemistry (IHC) Antibody New
Support on research about infectious diseases Hot
Core reagents for infectious disease researchNew SARS-CoV-2 related products Reagents for vaccine development SARS-CoV-2 mutant products SARS-CoV-2 related kits Reagents for diagnostic development
Kits/Beads
Residue Detection Kits New Cytokine detection ELISA kits New Pre-coupling magnetic beads Inhibitor Screening Kits ELISA Assay Kits for Quantitative analysis of therapeutic antibodies in serum

Featured products

Universal Tools
Star Ribbon Protein Marker New SA, SA Coated Plates, SA Magnetic Beads Hot MPCLIA Key Reagents New Anti-His Antibody New Anti-Human IgG Antibody New Anti-MMAE Antibody New Fc Receptor Proteins Hot IgG Fc ProteinsHot IgG Isotype ControlHot Serum AlbuminHot Matrigengel Matrix Basement Membrane ExtractsHot
Pre-labeled proteins
New Generation Tools for CAR DetectionStar Staining Biotinylated protein collection FITC & PE labeled proteins
Full-length multi-pass TpsHot
Multi-pass Tps FLAG Claudin Family Claudin 18.2 GPCRs CD20 proteins
Advance Neuroscience Research
Proteins for Neuroscience New Pre-formed Fibrils (PFFs) New Aneuro | Neural Factors New Solutions for In Vivo Electrophysiology Recordings New

Hot targets
CD19 BCMA CD3 proteins IL-2 and IL-2 receptor proteins Interleukin 4 Receptor proteinsNew IL-6 and IL-6 receptor proteins New VEGF proteins IGF family proteins New IFN family proteins New Chemokine family proteins New Complement Components New CD39/CD73 proteins B7 families TNFSF proteins PD1 proteins TIGIT Siglec-15 proteins Integrin CD24&siglec-10
Cytokines
Growth Factors for Cell Culture New Growth Factors for iPSC CulturingNew Growth Factors for Stem Cell TherapyNew Cytokines for Organoid CultureNew Promising Therapeutic Targets Hot

FLAG Star Staining ViruStop Aneuro ComboX ActiveMax GENPower ClinMax Star Ribbon
Services

Innovation Lab
SPR /BLI analytical serviceNew Quality Characterization Analytical Service New Enzyme-Linked Immunosorbent Assay (ELISA) Service New Meso Scale Discovery (MSD) ServiceNew Anti-Idiotypic Antibody Development ServiceNew Pseudovirus Neutralization Assay ServiceNew Custom GMP-grade Protein Services New MHC Class I Complex Custom ServiceNew Recombinant Antibody ServiceNew

Licensing Opportunities
GIP/GLP-1/FGF21 Fusion Protein treating NASH, T2DM, Hyperlipoidemia New A2aR/A2bR AntagonistNew Her2xCD3 BsAb New PD-1×TIGIT BsAb for Advanced solid tumor New B7-H3×CD3 BsAb for solid tumor New FRα BsAb-ADC New CCR8 Humanized Antibody New Anti-GCC humanized antibody New
Supports

How to Order Shipping & Payments Global Distributors Testimonials FAQs Download COA
Applications

The Process of How SARS-CoV-2 Infects the Host Quantitative Analysis of mAb in Serum Evaluation of CAR Expression Claudin18.2-VLP：designed for CAR detection SPR & BLI：Binding activity assay SEC-MALS: Aggregation state and purity
News

News Insights Promotions Exhibitions
Resources

Download Brochures Download E-resources Download COA
ACROBiosystems

About Us Join Us Contact Us Partner with us Quality management system Acro Certify

Introduction

Interferon (IFN) was first discovered in 1957 by Alick Isaacs and Jean Lindenmann from their initial studies in viral interference. Over the years, various studies about IFN were performed, elucidating its anti-viral activity. It was only until 1980 when IFN could be produced in a large-scale for research use, where pioneering recombinant DNA technology was utilized. IFN proteins were discovered to have both anti-tumor and immunomodulatory functions along with its inherent anti-viral activity, classifying them as a subset of cytokines.

The IFN protein family is organized into three types according to its corresponding receptor: type I, type II and type III; each of which are produced in different cellular locations. IFN-α and IFN-β are the most prominent members of type I IFNs and are mainly produced by pathogenesis-associated molecular patterns (PAMPs). PAMPs are induced by stimulation of Toll-like receptors (TLR) or cytoplasmic pattern recognition receptors located on the cell membrane. Type II IFNs have only one type, IFN-γ, which are produced by a variety of cells in the immune system. This includes innate lymphoid-like cell populations such as innate lymphocytes (ILC) and natural killer (NK) cells, as well as adaptive immune cells consisting of helper T cells 1 (Th1) and CD8 cytotoxic T lymphocytes (CTL). Type III IFNs are mainly produced by epithelial cells in non-hematopoietic cells, where viruses can mediate type III interferon expression in different cell types. However, since these IFNs were discovered in 2003, the exact mechanism of its production is still unknown and is the subject of various academic studies.

The corresponding signaling pathways of the three types of IFNs are also different, where each bind to different compositions of heterodimeric receptor complexes. Intracellular signaling is conducted through the Janus kinase/signal transducer and acts as an activator of transcription (JAK/STAT) pathways.

The main transduction pathways of the IFN signaling

Mechanism of action of a drug targeting IFN (Anifrolumab)

Due to the widespread effects of the IFN regulatory pathways, IFN is often associated with the progression of tumor diseases. In vitro studies have shown that IFN can inhibit tumor cell growth by up-regulating the cell cycle and also induce apoptosis by binding to tumor necrosis factor-related apoptosis-inducing ligands. However, in vivo studies have shown that deletion of the type I or type II interferon signaling pathway accelerates tumorigenesis and progression.

The correlation of both type I and II IFN responses to oncogenic properties has highlighted it as a significant pathway for targeted cancer drug resistance. This was observed from the resulting tumor cells after cancer therapy expressing intact or partially intact IFN signaling. As a result, a resistance to viral replication is developed, preventing targeted therapeutics from exerting its normal anti-tumor effects. To combat this, targeted therapies inhibiting JAK/STAT signaling by IFN can be a therapeutic modality to overcome resistance to therapeutic agents.

To assist with your research into the IFN protein family, ACROBiosystems provides a comprehensive catalog of high-quality IFNs to meet your needs in drug discovery, functional evaluation, quality control.

Product Features

HEK293 expressed, native protein conformation

High purity verified by SDS-PAGE

High structural homogeneity verified by SEC-MALS

High bioactivity verified by ELISA/SPR/BLI - protocol available

High batch-to-batch consistency

Product List

Molecule	Cat. No.	Species	Product Description	Preorder/Order
IFN-alpha 1	IFA-H52H9	Human	Human IFN-alpha 1 Protein, His Tag	Order
	IFA-H5258	Human	Human IFN-alpha 1 Protein, Fc Tag (MALS verified)	Order
	IFA-M52H3	Mouse	Mouse IFN-alpha 1 Protein, His Tag	Order
IFN-alpha 2b	IFB-H5253	Human	Human IFN-alpha 2b (K46R) Protein, Fc Tag (MALS verified)	Order
IFN-gamma	IFG-H4211	Human	Human IFN-gamma / IFNG Protein, premium grade	Order
	IFN-BM411		Biotinylated Monoclonal Anti-IFNγ antibody, Human IgG1 (13E6H4)	Order
	IFN-M412		Monoclonal Anti-IFNγ antibody, Human IgG1 (8C5F8)	Order
	IFN-M414		Monoclonal Anti-IFNγ antibody, Human IgG1 (13E6H6)	Order
	IFN-M411		Monoclonal Anti-IFNγ antibody, Human IgG1 (13E6H4)	Order
	IFN-BS138	Mouse	Biotinylated Monoclonal Anti-IFNγ antibody, Mouse IgG1 (13E6H6) (MALS verified)	Order
	IFN-S120		Monoclonal Anti-IFNγ antibody, Mouse IgG2a (8C5F8) (SPR verified)	Order
	IFN-S138		Monoclonal Anti-IFNγ antibody, Mouse IgG1 (13E6H4)	Order
IFN-alpha/beta R1	IF1-H5253	Human	Human IFN-alpha / beta R1 Protein, Fc Tag	Order
	IF1-H5225	Human	Human IFN-alpha / beta R1 Protein, His Tag (MALS verified)	Order
	IF1-M5225	Mouse	Mouse IFN-alpha / beta R1 Protein, His Tag	Order
IFN-alpha/beta R2	IF2-H5224	Human	Human IFN-alpha/beta R2 Protein, His Tag (MALS verified)	Order
	IF2-H5255	Human	Human IFN-alpha / beta R2 Protein, Fc Tag	Order
	IF2-M5225	Mouse	Mouse IFN-alpha / beta R2 Protein, His Tag	Order
	IFA-R52H1	Rat	Rat IFN-alpha/beta R2 Protein, His Tag	Order
IFN-gamma R1	IF1-H5223	Human	Human IFN-gamma R1 / IFNGR1 Protein, His Tag	Order
IFN-gamma R1	IF1-H5254	Human	Human IFN-gamma R1 / IFNGR1 Protein, Fc Tag	Order

Verification Data

High purity and structural homogeneity verified by SDS-PAGE and SEC-MALS

Human IFN-alpha 1 (Cat. No. IFA-H5258), Fc Tag on SDS-PAGE under reducing (R) condition. The gel was stained overnight with Coomassie Blue. The purity of the protein is greater than 95%.

The purity of Human IFN-alpha 1, Fc Tag (Cat. No. IFA-H5258) is more than 90% and the molecular weight of this protein is around 90-118 kDa verified by SEC-MALS.

High biological activity verified by ELISA

Immobilized ActiveMax® Human IFN-gamma, Tag Free (Cat. No. IFG-H4211) at 5 μg/mL (100 μL/well) can bind Human IFN-gamma R1, His Tag (Cat. No. IF1-H5223) with a linear range of 0.01-0.313 μg/mL.

Protocol

Immobilized Human IFNAR2, His Tag (Cat. No. IF2-H5224) at 5 μg/mL (100 μL/well) can bind Human IFN-alpha 2b (K46R), Fc Tag (Cat. No. IFB-H5253) with a linear range of 2.4-10 ng/mL.

Protocol

High biological activity verified by SPR

Loaded Human IFN-alpha 1, His Tag (Cat. No. IFA-H52H9) on HIS1K Biosensor, can bind Human IFNAR1, Fc Tag (Cat. No. IF1-H5253) with an affinity constant of 0.191 μM as determined in BLI assay (ForteBio Octet Red96e).

Protocol

Mouse IFN-alpha / beta R1, His Tag (Cat. No. IF1-M5225) immobilized on CM5 Chip can bind Mouse IFN-alpha 1, His Tag (Cat. No. IFA-M52H3) with an affinity constant of 2.96 μM as determined in a SPR assay (Biacore 8K).

Protocol

References

1. Li Q, Tan F, Wang Y, et al. The gamble between oncolytic virus therapy and IFN[J]. Frontiers in Immunology, 2022, 13.https://doi.org/10.3389/fimmu.2022.971674.
2. Zhang X, Zou M, Liang Y, et al. Arctigenin inhibits abnormal germinal center reactions and attenuates murine lupus by inhibiting IFN-I pathway[J]. European Journal of Pharmacology, 2022, 919: 174808.https://doi.org/10.1016/j.ejphar.2022.174808.
3. Barrat F J, Crow M K, Ivashkiv L B. Interferon target-gene expression and epigenomic signatures in health and disease[J]. Nature immunology, 2019, 20(12): 1574-1583.https://doi.org/10.1038/s41590-019-0466-2.
4. Felten R, Scher F, Sagez F, et al. Spotlight on anifrolumab and its potential for the treatment of moderate-to-severe systemic lupus erythematosus: evidence to date[J]. Drug design, development and therapy, 2019, 13: 1535.https://doi.org/10.2147/DDDT.S170969.