Technical articles
Applications of BMP Signaling Pathway Regulators in Stem Cell Differentiation, Organoid Culture and Developmental Research
Applications of BMP Signaling Pathway Regulators in Stem Cell Differentiation, Organoid Culture and Developmental Research
The BMP signaling pathway is an important signaling network that regulates embryonic development, tissue homeostasis, cell fate determination and regenerative repair. Through combined regulation using exogenous BMP ligands, receptor inhibitors, antagonistic proteins and pathway-coordinating factors, signaling environments corresponding to different developmental stages can be reconstructed in vitro for directed stem cell differentiation, organoid formation and developmental mechanism studies.
Keywords: BMP signaling pathway; stem cell differentiation; organoid culture; developmental biology; BMP inhibitor; SMAD signaling
1 Regulatory Basis of the BMP Signaling Pathway
1.1 Pathway Components
(1) BMP ligands
BMPs belong to the TGF-β superfamily. Common members include BMP2, BMP4, BMP7 and BMP9. Different BMP ligands have distinct roles in germ layer establishment, neural induction, osteochondral differentiation, angiogenesis and organ development. In vitro culture systems often use recombinant BMP proteins to simulate exogenous signaling input during developmental stages.
(2) BMP receptors
BMP signaling is mainly transmitted through type I and type II serine/threonine kinase receptors. After ligand binding, the type II receptor phosphorylates and activates the type I receptor, thereby initiating downstream SMAD-dependent signaling. Different cells express different receptor types, so the same BMP ligand may produce different effects in different cell types.
(3) SMAD transcriptional regulation
The canonical BMP pathway transmits signals through phosphorylation of SMAD1/5/8. Phosphorylated SMAD1/5/8 forms a complex with SMAD4 and enters the nucleus to regulate the expression of ID genes, developmental transcription factors, cell-cycle factors and lineage markers. p-SMAD1/5/8 is usually an important indicator for determining whether the BMP pathway is activated.
1.2 Regulatory Levels of the Pathway
(1) Ligand-level regulation
Exogenous addition of BMP2, BMP4 or BMP7 can enhance pathway activity. Antagonistic proteins such as Noggin, Gremlin and Chordin can bind BMP ligands and block their binding to receptors. This regulatory level is suitable for simulating BMP gradient changes during development.
(2) Receptor-level regulation
Small molecules such as LDN-193189, DMH-1, DMH2 and K 02288 can inhibit BMP type I receptor kinase activity and reduce SMAD1/5/8 phosphorylation. Receptor inhibitors are commonly used for neural induction, organoid patterning and pathway-dependence validation.
(3) Pathway interaction regulation
BMP signaling rarely determines cell fate alone, and usually acts together with pathways such as Wnt, FGF, TGF-β/Activin/Nodal, RA, Notch and Hedgehog. The timing, dose and combination of different pathways are central to the design of stem cell differentiation and organoid culture systems.
2 Main Types of BMP Regulators
2.1 Activating Regulators
(1) Recombinant BMP proteins
BMP2, BMP4 and BMP7 are commonly used to externally activate the BMP pathway. BMP4 is frequently used in mesoderm induction, trophoblast-like differentiation and embryoid structure models. BMP2 is commonly used for osteogenic and chondrogenic induction. BMP7 is often used in kidney, neuroprotection and epithelial-related models.
(2) Small-molecule agonists
Small molecules such as BMP agonists and BMP4 agonists can be used to enhance BMP-related signaling output. Compared with recombinant proteins, small molecules are more convenient for dose-gradient setup and high-throughput screening, but their pathway specificity should be confirmed using indicators such as p-SMAD1/5/8 and ID1.
(3) Synergistic induction factors
BMP signaling often needs to be combined with Wnt activators, FGF, RA or osteogenic induction components. For example, BMP and Wnt can synergistically promote mesodermal and cardiovascular lineage induction, while BMP combined with β-glycerophosphate, ascorbic acid and dexamethasone can promote osteogenic differentiation.
2.2 Inhibitory Regulators
(1) BMP receptor inhibitors
LDN-193189, DMH-1, DMH2 and K 02288 can inhibit BMP type I receptor-related signaling and reduce SMAD1/5/8 phosphorylation. These inhibitors are commonly used for neural ectoderm induction, intestinal organoid patterning and BMP-dependence validation.
(2) BMP antagonistic proteins
Noggin is a commonly used BMP antagonist in organoid culture, especially in intestinal, gastric, pancreatic and some epithelial organoid systems, where it helps maintain the stem cell niche. Gremlin and Chordin-related factors can also serve as important components of the BMP ligand antagonism axis and are used to analyze developmental axial patterning and signaling gradients.
(3) Gene intervention tools
siRNAs or knockout cell lysates targeting BMP ligands, BMP receptors, SMAD members and downstream genes such as ID1 can be used to validate pathway causality. These tools are suitable for answering whether a specific BMP node is necessary, rather than merely observing correlation changes after exogenous factor treatment.
3 Applications in Stem Cell Differentiation
3.1 Germ Layer Fate Regulation
(1) Ectoderm induction
BMP inhibition is a key strategy in neural ectoderm induction. During the differentiation of human pluripotent stem cells toward the neural lineage, inhibition of BMP and TGF-β/Activin/Nodal signaling is often used to reduce non-neural lineage interference and improve the efficiency of neural epithelial-like cell generation.
(2) Mesoderm induction
BMP4, together with Wnt, Activin/Nodal and other signals, can promote mesoderm formation. During induction, BMP signal intensity and exposure duration determine whether cells shift toward cardiovascular, hematopoietic, osteochondral or muscle lineages. Excessively strong or prolonged BMP signaling may result in mixed lineage outcomes.
(3) Endoderm and its derivative lineages
The role of BMP in endoderm differentiation is stage-dependent. In early endoderm induction, BMP signaling can cooperate with Activin/Nodal. During subsequent patterning toward foregut, liver, pancreas or intestinal lineages, BMP levels need to be precisely controlled to avoid lineage deviation.
3.2 Osteogenic, Chondrogenic and Mesenchymal Differentiation
(1) Osteogenic differentiation
BMP2 and BMP4 can promote the expression of osteogenic markers such as RUNX2, ALP, COL1A1 and OCN. In in vitro osteogenic systems, BMPs are usually combined with ascorbic acid, β-glycerophosphate and dexamethasone to enhance matrix maturation and mineralization.
(2) Chondrogenic differentiation
BMP2, BMP4 and BMP7 can promote cartilage matrix formation and work together with TGF-β signaling to affect SOX9, COL2A1 and ACAN expression. Excessive BMP in chondrogenic induction may promote hypertrophy, so differentiation quality should be assessed using indicators such as COL10A1 and MMP13.
(3) Mesenchymal lineage balance
Mesenchymal stem cells are sensitive to BMP signaling. BMP activation can promote osteogenic or chondrogenic tendency, but may also affect adipogenic differentiation and fibrosis-related phenotypes. Interpretation should be based on induction factor combinations and time windows.
3.3 Cardiovascular and Hematopoietic Differentiation
(1) Cardiomyocyte induction
Stage-specific coordination between BMP and Wnt signaling can promote mesoderm and early cardiac progenitor formation. In cardiomyocyte differentiation, Wnt/BMP-related signaling is often activated first to establish mesoderm, followed by inhibition of specific pathways at later stages to promote cardiomyocyte maturation.
(2) Vascular and endothelial differentiation
BMP4, BMP9 and BMP10 can all participate in vascular endothelial regulation. When combined with factors such as VEGF and FGF, they can improve endothelial marker expression and vascular-like structure formation.
(3) Hematopoietic models
BMP signaling participates in primitive hematopoiesis and angiogenesis-related developmental processes. In in vitro models, BMP signal intensity, Wnt activity and cell aggregation state can affect hematopoietic lineage induction efficiency.
4 Applications in Organoid Culture
4.1 Intestinal Organoids
(1) Stem cell maintenance
In the intestinal crypt microenvironment, BMP signaling is usually antagonized to maintain the stem cell zone. Noggin is often used together with EGF and R-spondin in intestinal organoid culture to inhibit BMP signaling and support LGR5-positive stem cell maintenance.
(2) Differentiation regulation
When BMP antagonism is reduced or BMP signaling is enhanced, intestinal organoids may show increased differentiation, reduced proliferative zones and changes in crypt-like structures. BMP intensity can be used to regulate the balance between stem cell maintenance and epithelial differentiation.
(3) Disease models
BMP pathway abnormalities are associated with intestinal epithelial renewal, inflammatory repair and tumorigenesis. By regulating BMP or Noggin levels, changes in the intestinal niche can be simulated to analyze epithelial regeneration and pathological differentiation processes.
4.2 Gastric, Pancreatic and Liver Organoids
(1) Gastric organoids
BMP signaling participates in gastric epithelial regionalization and glandular structure formation. In vitro, BMP inhibition is often used to maintain a stem cell-like state, while BMP activation can promote differentiation and tissue structure maturation.
(2) Pancreatic organoids
Pancreatic lineage formation has stage-specific requirements for BMP signaling. Excessively strong BMP signaling at early stages may affect foregut and pancreatic fate selection, while moderate regulation at later stages can influence the proportions of duct-like, acinar-like or endocrine-like cells.
(3) Liver organoids
BMP works together with FGF, HGF, OSM and other signals to participate in hepatocyte-like cell induction and maturation. Early BMP signaling helps establish hepatic progenitor fate, but subsequent maturation stages require coordinated optimization with other factors.
4.3 Neural and Brain Organoids
(1) Neural induction
In brain organoid and neural organoid construction, BMP inhibition is commonly used to improve neural ectoderm induction efficiency. If BMP signaling is not sufficiently inhibited, cells may deviate toward non-neural ectodermal, epidermal-like or mesenchymal-like directions.
(2) Regional patterning
In specific brain region organoids, BMP signaling can work together with Wnt, SHH, FGF and RA to regulate dorsal-ventral axes, anterior-posterior axes and cortical-like structure formation. BMP regulation at different time windows affects neural progenitor proportions and neuronal differentiation directions.
(3) Neural crest and boundary structures
Moderate BMP signaling can participate in neural crest cell induction. If the study focuses on neural crest, ectodermal boundaries or sensory nerve-related models, BMP signaling should not simply be inhibited, but needs to be jointly regulated with Wnt and FGF.
5 Applications in Developmental Research
5.1 Embryonic Pattern Formation
(1) Axis establishment
BMP signaling plays a key role in embryonic dorsal-ventral axis formation, ectodermal patterning and gastrulation movements. By changing BMP ligand or antagonist levels, different signaling gradients can be simulated to analyze tissue regionalization and fate allocation mechanisms.
(2) Germ layer boundary formation
BMP signaling works together with Nodal, Wnt, FGF and other pathways to determine germ layer boundaries. In vitro embryoid structures, embryo-like models and micropatterned culture systems often use BMP4 to induce spatialized cell fate distribution.
(3) Morphogenesis
BMP not only regulates gene expression, but also affects cell migration, epithelial-mesenchymal transition, cell polarity and tissue folding. Developmental models should therefore evaluate both molecular markers and morphological changes.
5.2 Organogenesis Models
(1) Skeletal and cartilage development
BMP signaling promotes osteochondral progenitor formation and matrix deposition, making it an important regulatory axis for studying skeletal development, bone regeneration and cartilage formation. Excessive BMP activity may also induce ectopic ossification or cartilage hypertrophy.
(2) Kidney and urinary system development
BMP7 plays an important role in kidney development and renal progenitor cell maintenance. In kidney organoids or kidney development models, BMP signaling needs to be regulated together with Wnt, FGF and RA signaling.
(3) Vascular and cardiac development
BMP9, BMP10 and BMPR2-related signaling are closely associated with vascular endothelium, cardiovascular development and vascular homeostasis. Combined regulation with VEGF, FGF and Wnt can be used to construct vascularized organoids or cardiovascular development models.
5.3 Disease and Regeneration Research
(1) Fibrosis and abnormal differentiation
Abnormal BMP signaling may participate in fibrosis, ectopic ossification and tissue remodeling. By regulating BMP activity or the Gremlin-BMP antagonistic axis, researchers can analyze fibroblast activation, mesenchymal transition and pathological matrix deposition.
(2) Tissue injury repair
BMP participates in fracture repair, cartilage injury, skin regeneration and epithelial repair. In different tissues, BMP signaling may have dual roles in promoting repair and inducing abnormal remodeling.
(3) Genetic developmental disease models
Mutations in BMP pathway-related genes can affect skeletal, cardiovascular, neural and organ formation. Stem cell and organoid models can be used to reconstruct disease-related developmental abnormalities in vitro.
6 Experimental Design and Evaluation Indicators
6.1 Design of Regulatory Strategies
(1) Dose gradient
BMP signaling shows clear dose dependence. Low doses may be insufficient to induce lineage conversion, while high doses may lead to non-target lineages or cellular stress. Experiments should include concentration gradients of ligands, agonists or inhibitors.
(2) Time window
BMP signaling is stage-dependent. Early activation and late activation may produce completely different cell fate outcomes. In stem cell differentiation and organoid culture, the timing of regulation is often more important than a single concentration.
(3) Combinatorial regulation
BMP should be designed together with Wnt, TGF-β/Activin/Nodal, FGF, RA and matrix conditions. Changing BMP alone may make complex phenotypes difficult to interpret, so pathway crosstalk should be analyzed.
6.2 Detection of Pathway Activity
(1) p-SMAD1/5/8
p-SMAD1/5/8 is an important indicator for evaluating activation of the canonical BMP pathway. Its expression and nuclear localization can be detected by Western blot, immunofluorescence, flow cytometry or immunohistochemistry.
(2) Downstream target genes
ID1, ID2, ID3, MSX1 and MSX2 are commonly used as downstream response genes of BMP signaling. Downstream gene profiles may differ among cell types, so indicators should be selected based on the research model.
(3) Detection of ligands and antagonists
Factors such as BMP2, BMP4, BMP7, BMP9, Noggin and Gremlin can be evaluated by ELISA, immunoassays or transcript-level analysis to determine signaling input and the antagonistic environment in the culture system.
6.3 Functional and Structural Evaluation
(1) Evaluation of 2D differentiation
In 2D differentiation systems, cell fate conversion can be evaluated by qPCR, Western blot, immunofluorescence, flow cytometry and functional staining. Osteogenic differentiation can be assessed by ALP activity and mineralized nodules, while neural differentiation can be assessed by neural epithelial and neuronal markers.
(2) Evaluation of organoid structure
Organoid research should assess formation efficiency, size, branching structure, polarity, cellular composition and regionalization markers. Detection of a single gene expression marker is insufficient to judge organoid quality.
(3) Evaluation of developmental models
Developmental research should combine spatial markers, tissue morphology, cell migration and temporal dynamics. For embryoid structures or patterning models, signaling gradients and spatial distribution are more important than average expression levels.
7 Selection of BMP Signaling Pathway Regulators
7.1 BMP Signaling Pathway Regulators and Validation Tools
Product Module | Cat. No. | Product Name | Grade/Purity | Functional Positioning | Recommended Application Scenario |
BMP pathway agonist | BMP agonist 1 | Activates BMP-related signaling | BMP pathway activation, stem cell differentiation induction, pathway functional enhancement experiments | ||
BMP pathway agonist | BMP agonist 2 | ≥99% | Activates BMP-related signaling | BMP pathway activation, developmental signal simulation, osteogenic/mesoderm induction research | |
BMP4 agonist | SB 4 | ≥98% | Agonist of BMP4-related signaling | BMP4-dependent differentiation, developmental patterning and pathway activation validation | |
BMP receptor inhibitor | LDN-193189 | ≥98% | Inhibits BMP type I receptor | Neural induction, dual SMAD inhibition, organoid patterning, BMP-dependence validation | |
BMP receptor inhibitor | DMH-1 | ≥98% | Inhibits BMP type I receptor | Neural differentiation, vascular models, BMP-SMAD signal blockade experiments | |
BMP receptor inhibitor | DMH2 | ≥98%(HPLC) | Inhibits type I BMP receptor | Stem cell lineage regulation, BMP signaling inhibition in organoid culture | |
BMP receptor inhibitor | K 02288 | ≥98% | Inhibits type I BMP receptor | BMP pathway inhibition, p-SMAD1/5/8 downregulation validation | |
BMPR2 inhibitor | BMPR2-IN-1 TFA | ≥99% | Regulates BMPR2-related signaling | BMPR2 functional research, vascular/development-related BMP signaling analysis | |
BMP1/PCP inhibitor | UK 383367 | ≥98% | Inhibits BMP1/PCP-related protease activity | Matrix remodeling, osteochondral development and tissue morphogenesis-related research | |
BMP-derived peptide | BMP2-derived peptide | ≥98% | BMP2-related functional peptide | BMP2 structure-function research, ligand active fragment and material modification experiments | |
BMP ligand protein | Recombinant Human BMP-2 GMP Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,High Performance,sterile,≥95%(SDS-PAGE) | Activates BMP2 signaling | Osteogenic differentiation, bone regeneration, GMP-grade cell culture systems | |
BMP ligand protein | Recombinant Human BMP-4 GMP Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,High Performance,His Tag,≥95%(SDS-PAGE),See COA | Activates BMP4 signaling | Mesoderm induction in pluripotent stem cells, embryoid models, GMP-grade culture systems | |
BMP ligand protein | Recombinant Human BMP2 Protein | ≥90%(SDS-PAGE) | Activates BMP2 signaling | Osteogenic, chondrogenic and mesenchymal lineage induction | |
BMP ligand protein | Recombinant Human BMP4 Protein | ≥95%(SDS-PAGE) | Activates BMP4 signaling | Mesoderm induction, embryo-like models, developmental patterning experiments | |
BMP ligand protein | Recombinant Human BMP7 Protein | ≥90%(SDS-PAGE) | Activates BMP7 signaling | Kidney development, epithelial differentiation, tissue protection and repair research | |
BMP ligand protein | Recombinant Human BMP9 Protein | ≥90%(SDS-PAGE) | Activates BMP9/GDF2-related signaling | Vascular endothelial differentiation, hepatocyte-like cell models, angiogenesis research | |
BMP ligand protein | Recombinant Human BMP9 Protein | ≥90%(SDS-PAGE) | Activates BMP9/GDF2-related signaling | Endothelial cell function, vascular development and BMP9 pathway research | |
BMP ligand protein | Recombinant Human BMP3 Protein | ActiBioPure™, Bioactive, Animal Free, Carrier Free, Azide Free, High performance, ≥95%(SDS-PAGE&HPLC) | BMP3-related developmental regulation | Bone development, bone metabolism and BMP family functional comparison | |
BMP ligand protein | Recombinant Rat BMP2 Protein | ≥90%(SDS-PAGE) | Activates rat BMP2-related signaling | Differentiation of rat-derived cells, in vitro validation related to animal models | |
BMP ligand protein | BMP-10 | Moligand™ | BMP10-related signaling | Cardiovascular development, endothelial function and BMP family comparison research | |
BMP ligand protein | BMP-15 | Moligand™ | BMP15-related signaling | Reproductive development, ovarian/follicle-related models | |
BMP ligand protein | BMP-6 | Moligand™ | BMP6-related signaling | Bone development, iron metabolism, stem cell differentiation research | |
BMP ligand protein | BMP-7 | Moligand™ | BMP7-related signaling | Kidney, epithelial and tissue repair-related research | |
BMP ligand protein | BMP-9 | Moligand™ | BMP9-related signaling | Angiogenesis, endothelial function, hepatocyte-like differentiation research | |
BMP receptor protein | Recombinant Human BMPR-IA/ALK-3 Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,Azide Free,His Tag,≥95%(SDS-PAGE),See COA | BMP type I receptor | Receptor binding, ligand-receptor interaction and BMP pathway mechanism research | |
BMP receptor protein | Recombinant Human BMPR-IB/ALK-6 Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,High Performance,His Tag,≥90%(SDS-PAGE) | BMP type I receptor | Osteochondral differentiation, receptor function and ligand screening research | |
BMP receptor protein | Recombinant Human BMPR2 protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,Azide Free,His Tag,≥95%(SDS-PAGE) | BMP type II receptor | BMPR2-mediated signaling, vascular development and receptor function validation | |
BMP receptor protein | Recombinant Human BMPR2 Protein | ≥90%(SDS-PAGE) | BMP type II receptor | BMPR2 pathway research, ligand binding and mechanistic analysis | |
BMP antagonistic protein | Recombinant Human Noggin GMP Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,High Performance,Fc Tag,PBS Only,≥90%(SDS-PAGE&SEC-HPLC) | Antagonizes BMP ligands | Intestinal, gastric and pancreatic organoid culture; GMP-grade niche construction | |
BMP antagonistic protein | Recombinant Human Noggin Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,Azide Free,His Tag,≥95%(SDS-PAGE) | Inhibits BMP signaling | Organoid stem cell maintenance, neural induction, BMP-inhibited culture systems | |
BMP antagonistic protein | Recombinant Human Noggin Protein | Animal Free,Carrier Free,His Tag,PBS Only,≥90%(SDS-PAGE),See COA | Inhibits BMP signaling | Organoid culture, epithelial stem cell maintenance and BMP antagonism experiments | |
BMP antagonistic protein | Recombinant Human Gremlin 1 Protein | Carrier Free,Bioactive,ActiBioPure™,Azide Free,His Tag,≥98%(SDS-PAGE) | Antagonizes BMP2/4/7 and related signals | Developmental gradients, fibrosis, tissue remodeling and BMP antagonism mechanism research | |
BMP antagonistic protein | gremlin 1 | Moligand™ | BMP antagonism-related factor | BMP signaling inhibition, developmental regulation and tissue remodeling research | |
Gremlin antibody/blocking tool | Ginisortamab (anti-Gremlin) | Carrier Free, Recombinant, ExactAb™, Low Endotoxin, Azide Free, Validated, Animal Free, ≥95%(SDS-PAGE&SEC-HPLC), See COA | Targets Gremlin | Gremlin-BMP antagonistic axis, fibrosis and disease model research | |
BMP detection antibody | Recombinant BMP4 Antibody | Recombinant, ExactAb™, Validated, High Performance, See COA | Detects BMP4 | BMP4 expression detection, developmental models and organoid immunoanalysis | |
BMP detection antibody | Recombinant BMP7 Antibody | Recombinant, ExactAb™, Validated, See COA | Detects BMP7 | BMP7 expression, kidney/epithelial models and tissue repair research | |
BMP detection antibody | BMP6 Antibody | Carrier Free, ExactAb™, Validated, 1.0 mg/mL | Detects BMP6 | Bone development, iron metabolism and BMP6 pathway analysis | |
BMP detection antibody | BMP10 Antibody | ExactAb™, Validated, 1.0 mg/mL | Detects BMP10 | Cardiovascular development, endothelial function and BMP10 expression analysis | |
BMP detection antibody | BMP3 Antibody | ExactAb™, Validated, 1.0 mg/mL | Detects BMP3 | BMP3 expression, bone metabolism and developmental research | |
BMP detection antibody | BMP1/PCP Mouse mAb | See COA | Detects BMP1/PCP | Matrix processing, osteochondral development and tissue remodeling research | |
SMAD detection antibody | Recombinant Smad1 Antibody | ExactAb™, Validated, Recombinant, 0.8 mg/mL | Detects SMAD1 | Detection of total SMAD levels in the canonical BMP pathway | |
SMAD detection antibody | Recombinant SMAD Family Member 1 Antibody | KD Validation | Detects SMAD1 | BMP-SMAD pathway validation, knockdown model analysis | |
SMAD detection antibody | Recombinant SMAD5 Antibody | KD Validation | Detects SMAD5 | Downstream validation of p-SMAD1/5/8-related pathways | |
SMAD detection antibody | SMAD5 Mouse mAb | ExactAb™, Validated, 1.6 mg/mL | Detects SMAD5 | BMP signal output, organoid and differentiation model detection | |
SMAD detection antibody | SMAD6 Antibody | Validated, ExactAb™, 1.0 mg/mL | Detects SMAD6 | BMP negative feedback regulation, inhibitory SMAD analysis | |
SMAD detection antibody | SMAD9 Antibody | Carrier Free, ExactAb™, Validated, High Performance, See COA | Detects SMAD9 | Canonical BMP pathway, SMAD8/9-related signaling research | |
ID1 detection antibody | Recombinant Id1 Antibody | ExactAb™, Validated, Recombinant, 1.2 mg/mL | Detects ID1 | Detection of BMP downstream response gene, pathway output validation | |
SMAD negative regulation antibody | MADH7/SMAD7 Antibody | Validated, 1.0 mg/mL | Detects SMAD7 | BMP/TGF-β negative feedback, pathway inhibition mechanism research | |
BMP gene intervention | BMP2 Human Pre-designed siRNA Set A | Downregulates BMP2 | BMP2 loss of function, osteogenic differentiation and pathway-dependence validation | ||
BMP gene intervention | BMP4 Human Pre-designed siRNA Set A | Downregulates BMP4 | Mesoderm induction, embryo-like models and BMP4 function validation | ||
BMP gene intervention | BMP7 Human Pre-designed siRNA Set A | Downregulates BMP7 | BMP7 research related to kidney, epithelium and tissue repair | ||
BMP gene intervention | BMP6 Human Pre-designed siRNA Set A | Downregulates BMP6 | BMP6 loss of function, bone development and iron metabolism-related research | ||
BMP gene intervention | BMP10 Human Pre-designed siRNA Set A | Downregulates BMP10 | Endothelial, cardiovascular development and BMP10 functional research | ||
BMP gene intervention | BMP15 Human Pre-designed siRNA Set A | Downregulates BMP15 | Reproductive development and BMP15-related mechanism research | ||
BMP receptor gene intervention | BMPR1A Human Pre-designed siRNA Set A | Downregulates BMPR1A/ALK3 | BMP receptor-dependence validation, stem cell differentiation mechanism analysis | ||
BMP receptor gene intervention | BMPR1B Human Pre-designed siRNA Set A | Downregulates BMPR1B/ALK6 | Osteochondral differentiation, receptor subtype functional comparison | ||
BMP receptor gene intervention | BMPR2 Human Pre-designed siRNA Set A | Downregulates BMPR2 | BMPR2-mediated signaling, vascular development and disease model research | ||
BMP regulator intervention | BMPER Human Pre-designed siRNA Set A | Downregulates BMPER | BMP regulatory factors, vascular development and endothelial signaling research | ||
SMAD gene intervention | SMAD1 Human Pre-designed siRNA Set A | Downregulates SMAD1 | Loss-of-function validation of the canonical BMP pathway | ||
SMAD gene intervention | SMAD5 Human Pre-designed siRNA Set A | Downregulates SMAD5 | SMAD1/5/8 signal output analysis | ||
SMAD gene intervention | SMAD9 Human Pre-designed siRNA Set A | Downregulates SMAD9 | Canonical BMP pathway, SMAD8/9-related mechanism research | ||
SMAD negative regulation intervention | SMAD6 Human Pre-designed siRNA Set | BioReagent,for DNA and RNA applications,sterile,DNase, RNase free | Downregulates SMAD6 | BMP negative feedback regulation and inhibitory SMAD functional research | |
SMAD negative regulation intervention | SMAD7 Human Pre-designed siRNA Set | BioReagent,sterile,for DNA and RNA applications,DNase, RNase free | Downregulates SMAD7 | BMP/TGF-β crosstalk regulation and negative feedback research | |
BMP downstream gene intervention | ID1 Human Pre-designed siRNA Set A | Downregulates ID1 | BMP downstream response, cell fate and differentiation output validation | ||
BMP ELISA detection | Human Bone Morphogenetic Protein 2 (BMP2) ELISA Kit | BioReagent | Quantitatively detects BMP2 | Stem cell differentiation supernatants, tissue samples and secretion level analysis | |
BMP ELISA detection | Human Bone Morphogenetic Protein 4 (BMP4) ELISA Kit | BioReagent | Quantitatively detects BMP4 | Embryoid models, organoid culture medium and BMP4 expression analysis | |
BMP ELISA detection | Human Bone Morphogenetic Protein 7 (BMP7) ELISA Kit | BioReagent | Quantitatively detects BMP7 | Kidney models, epithelial differentiation and tissue repair research | |
BMP ELISA detection | Human Growth Differentiation Factor 2 (GDF-2/BMP-9) ELISA Kit | BioReagent | Quantitatively detects BMP9/GDF2 | Endothelial, angiogenesis and hepatocyte-like differentiation models | |
BMP ELISA detection | Human Bone Morphogenetic Protein 6 (BMP6) ELISA Kit | BioReagent | Quantitatively detects BMP6 | Bone development, iron metabolism and BMP6 secretion level analysis | |
BMP ELISA detection | Human Bone Morphogenetic Protein 10 (BMP10) ELISA Kit | BioReagent | Quantitatively detects BMP10 | Cardiovascular development and endothelial cell function research | |
BMP ELISA detection | Human Bone Morphogenetic Protein 15 (BMP15) ELISA Kit | BioReagent | Quantitatively detects BMP15 | Reproductive development and follicle-related models | |
Noggin detection | Mouse Noggin (NOG) ELISA Kit | BioReagent | Quantitatively detects Noggin | Mouse organoids, developmental models and BMP antagonistic environment analysis | |
Gremlin detection | Human Gremlin 1 (GREM1) ELISA Kit | BioReagent | Quantitatively detects GREM1 | Gremlin-BMP antagonistic axis, fibrosis and tissue remodeling research | |
Gremlin detection | Human Gremlin 2 (GREM2) ELISA Kit | BioReagent | Quantitatively detects GREM2 | BMP antagonist expression, developmental and disease models | |
Gremlin detection | Mouse Gremlin 1 (GREM1) ELISA Kit | BioReagent | Quantitatively detects mouse GREM1 | Mouse developmental models, tissue repair and fibrosis research | |
Chordin-related detection | Human Kielin/chordin-like Protein(KCP) ELISA Kit | BioReagent | Detects KCP | BMP regulatory factors, developmental axial patterning and pathway regulation research | |
SMAD ELISA detection | Human SMAD Family Member 5(Smad5) ELISA Kit | BioReagent | Quantitatively detects SMAD5 | Canonical BMP pathway output, cell differentiation model analysis | |
SMAD ELISA detection | Human SMAD3 ELISA Kit | BioReagent | Quantitatively detects SMAD3 | BMP/TGF-β crosstalk pathway and SMAD signaling research | |
SMAD ELISA detection | Human Mothers Against Decapentaplegic Homolog 4 (Smad4) ELISA Kit | BioReagent | Quantitatively detects SMAD4 | SMAD complex formation and common pathway node analysis | |
SMAD ELISA detection | Human Mothers Against Decapentaplegic Homolog 7 (Smad7) ELISA Kit | BioReagent | Quantitatively detects SMAD7 | Negative feedback regulation, BMP/TGF-β inhibition mechanism research |
The key to BMP signaling pathway regulation lies in dose, time window and pathway combination. In stem cell differentiation, activation or inhibition strategies should be determined according to the target lineage. In organoid culture, niche signals should be integrated to maintain cellular composition and structural maturation. In developmental research, signaling gradients, spatial distribution and dynamic changes should be emphasized. Rational use of BMP ligands, antagonistic proteins, receptor inhibitors and pathway validation tools can improve the ability of in vitro models to simulate real developmental processes.
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