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huTGFB1 Mouse
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huTGFB1 Mouse

Product Name
huTGFB1 Mouse
Product ID
C002006
Strain Name
C57BL/6NCya-Tgfb1tm1(hTGFB1)/Cya
Backgroud
C57BL/6NCya
Status
Live Mouse
When using this mouse strain in a publication, please cite “huTGFB1 Mouse (Catalog C002006) were purchased from Cyagen.”
HUGO-GT Humanized ModelsCytokine Gene Humanized Mouse Models
MASH and Fibrosis
Product Type
Age
Genotype
Sex
Quantity
The standard delivery applies for a guaranteed minimum of three heterozygous carriers. Breeding services for homozygous carriers and/or specified sex are available.
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HUGO-GT Humanized ModelsCytokine Gene Humanized Mouse Models
MASH and Fibrosis

Basic Information

Related Resource

Basic Information
Gene Name
TGFB1
Gene Alias
CED, LAP, DPD1, TGFB, IBDIMDE, TGFbeta, TGF-beta1
NCBI ID
7040 (Human)
Chromosome
Chr 19 (Human)
MGI ID
MGI:98725
Datasheet
Click here to download >>

Strain Description

The TGFB1 gene encodes transforming growth factor β1 (TGF-β1), a member of the TGF-β superfamily and a multifunctional secreted cytokine. It participates in a variety of physiological and pathological processes by precisely regulating cell proliferation, differentiation, apoptosis, and the synthesis and deposition of the extracellular matrix (ECM). TGF-β1 plays a critical regulatory role in maintaining embryonic development, wound healing, tissue homeostasis, angiogenesis, extracellular matrix remodeling, skeletal development, and immune system balance [1]. This cytokine is widely expressed in multiple tissues and cell types, with relatively high expression levels in the spleen, bone marrow, platelets, and smooth muscle tissues. Its expression is enhanced or enriched in platelets, megakaryocytes, fibroblasts, and immune cells (such as eosinophils and T cells) [2]. Studies have shown that aberrant expression of the TGFB1 gene is closely associated with the occurrence and progression of various human diseases, including fibrosis, inflammation, tumors, and Camurati-Engelmann disease (characterized by bone hyperostosis) [3]. It serves as an important therapeutic target in the fields of oncology, fibrotic diseases, and autoimmune disorders. Dysregulation of the TGF-β signaling pathway is closely linked to multiple cancers, in which the loss of TGF-β-mediated growth inhibitory function represents a key mechanism underlying the tumorigenesis of colorectal cancer, pancreatic cancer, and others. Meanwhile, in the tumor microenvironment, TGF-β1 acts as a potent immunosuppressive cytokine that participates in the co-regulation of immune checkpoint expression, thereby promoting tumor immune evasion [4-5]. As a core pro-fibrotic cytokine, TGF-β1 drives the fibrotic process in multiple organs, including the liver, lung, and kidney, through mechanisms such as activating fibroblasts or myofibroblasts, promoting ECM deposition and remodeling, and inhibiting ECM degradation [6-7]. Furthermore, TGF-β1 plays a central protective role in autoimmune diseases; its expression deficiency, secretion impairment, receptor signaling defects, or cell-type-specific functional loss can all lead to disruption of immune tolerance and drive the onset and progression of autoimmune diseases [8-9].
The huTGFB1 mouse is a humanized model constructed using gene editing technology. The sequence from the start codon to downstream of the mouse Tgfb1 3' UTR was replaced with the sequence from the start codon to downstream of the human TGFB1 3' UTR. The huTGFB1 mice can be utilized to investigate the development and progression of TGF-β1-mediated diseases, including tumors, fibrosis, and autoimmune disorders. This model facilitates the research and development of TGFB1-targeted therapeutics and supports preclinical pharmacological and pharmacodynamic evaluations.
Reference
Deng Z, Fan T, Xiao C, et al. TGF-β signaling in health, disease, and therapeutics. Signal Transduct Target Ther. 2024;9(1):61.
TGFB1 transforming growth factor beta 1 [Homo sapiens]. NCBI Gene. Accessed July 10, 2026.
Massagué J, Sheppard D. TGF-β signaling in health and disease. Cell. 2023;186(19):4007-4037.
Wang L, Gu S, Chen F, et al. Imatinib blocks tyrosine phosphorylation of Smad4 and restores TGF-β growth-suppressive signaling in BCR-ABL1-positive leukemia. Signal Transduct Target Ther. 2023;8(1):120.
Vidotto T, Nersesian S, Graham C, Siemens DR, Koti M. DNA damage repair gene mutations and their association with tumor immune regulatory gene expression in muscle invasive bladder cancer subtypes. J Immunother Cancer. 2019;7(1):148.
Bhardwaj S, Gautam RK, Kushwaha S. From senescence to scarring: Exploring TGF-β signaling in cellular aging, fibrotic remodeling, and pulmonary fibrosis. Cytokine Growth Factor Rev. Published online August 22, 2025.
Abbad L, Esteve E, Chatziantoniou C. Advances and challenges in kidney fibrosis therapeutics. Nat Rev Nephrol. 2025;21(5):314-329.
Haque TT, Weissler KA, Schmiechen Z, et al. TGFβ prevents IgE-mediated allergic disease by restraining T follicular helper 2 differentiation. Sci Immunol. 2024;9(91):eadg8691.
Turner JA, Stephen-Victor E, Wang S, et al. Regulatory T Cell-Derived TGF-β1 Controls Multiple Checkpoints Governing Allergy and Autoimmunity. Immunity. 2020;53(6):1202-1214.e6.

Strain Strategy

The sequence from the start codon to downstream of the mouse Tgfb1 3' UTR was replaced with the sequence from the start codon to downstream of the human TGFB1 3' UTR.
Figure 1. Gene editing strategy of huTGFB1 mice.
Figure 1. Gene editing strategy of huTGFB1 mice.

Application Area

The screening, development, and preclinical evaluation of TGFB1-targeted drugs;
Research on the pathogenesis and therapies of TGFB1-mediated tumors, such as colorectal cancer and pancreatic cancer;
Research on the pathogenesis and therapies of organ fibrosis, such as liver, lung, and kidney fibrosis;
Research on the mechanisms of TGFB1-mediated immune tolerance and inflammatory response.
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The industry is undergoing a rapid transformation driven by next-generation modalities, globalized markets, and upstream technological innovations.
  • Market Structural Shift: Monoclonal antibodies drive steady growth, but ADCs and bispecifics are rapidly accelerating, reshaping the market with higher-value innovations.
  • Chinese Market Globalization: China is actively expanding globally, evidenced by a surge in high-value cross-border license-out deals.
  • Technology-Driven Efficiency: Advanced discovery engines—exemplified by Cyagen's HUGO-Ab platform and AI algorithms—are streamlining candidate screening, optimizing molecular design, and localizing the upstream supply chain.
  • Oncology-Focused Innovation: R&D pipelines remain heavily concentrated on high-incidence malignancies like non-small cell lung cancer, utilizing complex modalities to combat clinical resistance.
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