From 11:00 pm to 12:00 pm EST ( 8:00 pm to 9:00 pm PST ) on January 6th, the website will be under maintenance. We are sorry for the inconvenience. Please arrange your schedule properly.
Elironrasib is an orally active and covalent inhibitor of KRAS G12C(ON). Elironrasib forms a tri-complex within tumor cells between KRAS G12C(ON) and cyclophilin A (CypA). Thus, Elironrasib prevents KRAS G12C(ON) from signaling via steric blockade of RAS effector binding. Elironrasib inhibits ERK signaling and induced apoptosis in KRASG12C-mutant H358 cells. Elironrasib also inhibits the proliferation of KRAS G12C mutant cells with a median IC50 of 0.11 nM .
Setidegrasib (KRAS G12D inhibitor 17, ASP3082) is a PROTACKRAS degrader (DC50: 37 nM). Setidegrasib induces the degradation of G12D-mutationKRAS protein. Setidegrasib suppresses p-ERK, p-AKT, p-S6 levels in AsPC-1 cells. Setidegrasib exhibits anti-tumor activity in various cancer xenograft models in mice. Setidegrasib can be used for the study of KRAS(G12D)-mutated solid tumors. (Blue: VHL ligase ligand (HY-168699); Black: linker (HY-168698); Pink: G12D ligand (HY-168700)) .
Tunlametinib is a highly selective, orally active MEK1/2 inhibitor (IC50=1.9 nM, MEK1). Tunlametinib blocks the RAS-RAF-MEK-ERK signaling pathway, arrests tumor cell cycle and promotes apoptosis. Tunlametinib potently inhibits the proliferation of RAS/RAF mutant cancer cells (such as BRAF V600E, KRAS G12C mutant cells). Tunlametinib shows synergistic anti-tumor effects with BRAF/KRASG12C/SHP2 inhibitors, Docetaxel (HY-B0011). Tunlametinib can be used to study targeted therapy for RAS/RAF mutation-driven malignancies (such as melanoma, colorectal cancer, and non-small cell lung cancer) .
BI-2852 is a KRAS inhibitor for the switch I/II pocket (SI/II-pocket) by structure-based agent design with nanomolar affinity. BI-2852 is mechanistically distinct from covalent KRASG12C inhibitor (binds to switch II pocket) and binds ten-fold more strongly to active KRASG12D versus KRASwt (740 nM vs 7.5 μM). BI-2852 blocks GEF, GAP, and effector interactions with KRAS, leading to inhibition of downstream signaling and an antiproliferative effect in KRAS mutant cells.
MRTX0902 is a potent, selective, brain-penetrant, and orally active SOS1 inhibitor with a Ki of 1.9 nM. MRTX0902 disrupts the SOS1:KRASG12C protein-protein interaction (PPI). MRTX0902 can be used in research on pancreatic ductal adenocarcinoma .
K-Ras(G12C) inhibitor 12 is an irreversible inhibitor of K-Ras(G12C). K-Ras(G12C) inhibitor 12 can alter the nucleotide-binding preference of K-Ras and block its interaction with effector proteins. K-Ras(G12C) inhibitor 12 can reduce cell viability and induce apoptosis in lung cancer cell lines with G12C mutations. K-Ras(G12C) inhibitor 12 has anti-tumor activity .
TH-Z827 is a mutant selective KRAS(G12D) inhibitor with an IC50 of 2.4 μM. TH-Z827 does not bind KRAS(WT) or KRAS(G12C). TH-Z827 blocked the KRAS(G12D)-CRAF interaction with an IC50 value of 42 μM .
HRX-0233 is a small-molecule MAP2K4 inhibitor. HRX-0233 results in strong tumor shrinkage without any apparent toxicity in H358 KRASG12C-mutant non-small cell lung cancers (NSCLC) in vivo. HRX-0233 efficiently prevents feedback activation of receptor tyrosine kinases (RTKs) upon monotherapy KRAS inhibitor Sotorasib (HY-114277) and causes a more sustained and complete inhibition of MAPK signaling. HRX-0233 is promising for research of AR-negative prostate cancer, lung and colon cancers .
KRASG12C IN-13 (LY3499446) is a potent KRAS G12C inhibitor. KRASG12C IN-13 is promising for research of advanced solid tumors including non-small cell lung cancer and colorectal cancer .
(R)-G12Di-7 is a covalent ligand for KRAS-G12D, which selectively labels K-Ras-G12D·GDP and K-Ras-G12D·GppNHp. (R)-G12Di-7 exhibits inhibitory activity against G12D mutated cancer cells .
KRASG12D-IN-1 (compound 22) is a KRAS G12D Inhibitor. KRASG12D-IN-1 has dose-dependent anti-tumor efficacy in the AsPC-1 xenograft mouse models with a tumor growth inhibition .
Divarasib (GDC-6036) adipate is an orally active, selective KRASG12C inhibitor with an IC50 of <0.01 μM. Divarasib adipate covalently binds Cys12 in GDP-bound KRASG12C, occupies the switch II pocket, blocks GTP binding and SOS-mediated reactivation, and inhibits oncogenic KRAS signaling. Divarasib adipate induces tumor shrinkage and robust tumor growth inhibition in KRASG12C-positive models and cancer cells. Divarasib adipate can be used for the research of non-small cell lung cancer, colorectal adenocarcinoma, pancreatic ductal adenocarcinoma, and other KRASG12C-mutated solid tumors .
YN14 is a KRASG12C proteolysis targeting chimera (PROTAC). YN14 is highly potent and selective KRASG12C degrader and induces a stable KRASG12C: YN14: VHL ternary complex with low binding free energy (ΔG). YN14 has antiproliferative effects and significantly inhibits KRASG12C-mutant cancer cell growth. YN14 leads to tumor regression with tumor growth inhibition (TGI%) rates more than 100 % in the MIA PaCa-2 xenograft model.
KRASG12D-IN-3 is an orally active KRAS G12D inhibitor. KRASG12D-IN-3 inhibits the growth of gastric cancer and pancreatic cancer cells. KRASG12D-IN-3 inhibits the activity of p-ERK in gastric cancer cells. KRASG12D-IN-3 can be used for the research of gastric cancer and pancreatic cancer .
KRASG12D-IN-2 (compound 28) is a KRAS G12D Inhibitor. KRASG12D-IN-1 has dose-dependent anti-tumor efficacy in the AsPC-1 xenograft mouse models with a tumor growth inhibition .
CH091138 is a potent and selective KRASG12D PROTAC degrader with DC50s of 148.3 nM in HeLa cells and 469.8 nM in AsPC-1 cells. CH091138 selectively degrades exogenous and endogenous KRASG12D but not KRAS WT or other KRAS mutants (G12C/G12S/G12V), depending on the VHL-mediated ubiquitin-proteasome system. CH091138 exhibits potent anti-tumor activity and induces cancer cell apoptosis. CH091138 can be used for the studies of pancreatic cancer and colon cancer. (Pink: KRASG12D ligand (HY-175144); Blue: VHL E3 ligase ligand (HY-138678); Black: Linker; VHL E3 ligase ligand + Linker (HY-136006B)) .
(R)-BI-2852 is the isomer of BI-2852 (HY-126247), and can be used as an experimental control. BI-2852 is a KRAS inhibitor for the switch I/II pocket (SI/II-pocket) by structure-based agent design with nanomolar affinity. BI-2852 is mechanistically distinct from covalent KRASG12C inhibitor (binds to switch II pocket) and binds ten-fold more strongly to active KRASG12D versus KRASwt (740 nM vs 7.5 μM). BI-2852 blocks GEF, GAP, and effector interactions with KRAS, leading to inhibition of downstream signaling and an antiproliferative effect in KRAS mutant cells.
KRASG12C IN-17 is an orally active covalent KRAS G12C inhibitor, showing strong inhibitory activity in KRAS G12C-mutant cancer cells (NCI-H23 IC50 = 0.7 nM; NCI-H358 IC50 = 0.5 nM).
KRASG12C IN-17 covalently and irreversibly binds to KRAS G12C with > 96% modification efficiency in both GDP-bound and GMPPNP-bound conformations.
KRASG12C IN-17 can be used for studies of KRAS-driven cancers, including colorectal cancer .
KRAS-IN-48 (Compound 1-01) is a KRAS mutant inhibitor, with Kd values of 2.58 nM and 5.49 μM for KRAS-G12D and KRAS-G12V, respectively. KRAS-IN-48 can be used in the research of cancer .
KRASG12D-IN-4 (example 38) is a KRas G12D inhibitor with an IC50 of 3.3 nM. KRASG12D-IN-4 inhibits proliferation of pancreatic cancer ASPC-1 cells with an IC50 of 12 nM .
KRASG12D-IN-7 is a selective KRAS G12D inhibitor. KRASG12D-IN-7 displays strong binding activity for KRAS G12D in both its GDP- and GTP- bound states, with Kd value of 1.12 nM and 1.86 nM, respectively. KRASG12D-IN-7 inhibits the proliferation of KRAS G12D harboring AsPC-1 cells with an IC50 value of 10 nM and suppresses MAPK signaling. KRASG12D-IN-7 induces G0/G1 phase arrest and apoptosis in AsPC-1 cells, and strongly inhibits their colony formation. KRASG12D-IN-7 can be used for the study of cancers harboring KRAS G12D mutation, particularly pancreatic ductal adenocarcinoma (PDAC) .
AZD4625 is an orally active, selective irreversible, covalent allosteric GTPase KRASG12C inhibitor with an IC50 of 3 nM. AZD4625 can inhibit the MAPK pathway (with decreased pCRAF, pMEK, and pERK) and the PI3K pathway (with decreased pAKT and pS6), and induce cell apoptosis. AZD4625 has no binding and inhibition of wild-type RAS or isoforms carrying non-KRASG12C mutations. AZD4625 can be used for the study of KRASG12C mutant non-small cell lung cancer .
KRASG12D-IN-5 (Compound 241) is an orally active KRAS(G12D) inhibitor with an IC50 of 11 nM. KRASG12D-IN-5 has potent anticancer activity with no significant cytotoxicity against BxPC-3 (WT), KRAS mutation AsPC-1 (G12D) and MIAPaCa-2 cells (G12C) with CC50s of 10.37, 0.76 and 0.3 μM, respectively. KRASG12D-IN-5 can be used for cancer research, such as lung, pancreatic and colorectal cancer .
KRASG12D-IN-6 is a PROTAC target protein ligand that can be used to synthesize CH091138 (HY-175025). CH091138 is a potent and selective KRASG12D PROTAC degrader with anti-tumor activity .
KRASG12C IN-12 (compound-1) is a KRAS G12C inhibitor. KRASG12C IN-12 (compound-1) can form a ternary complex with intracellular CYPA and the activated KRAS G12C mutant .
ZJK-807 is a highly effective and selective PROTAC degrader targeting KRASG12D (DC50 = 79.5 nM in AsPC-1 cells). ZJK-807 shows minimal impact on wild-type KRAS or other mutants (G12C/S/V, G13D), inducing mutant-specific cytotoxicity. ZJK-807 suppresses RAS/MAPK signaling and uniquely modulates TNF signaling and eukaryotic ribosome biogenesis. ZJK-807 can be used for the study of KRAS-driven pancreatic cancer. Yellow: KRASG12D ligand (HY-W087383); Green: E3 ligase CRBN ligand (HY-178507); Black: Linker (HY-178506) .
SOS1-IN-22 is a son of sevenless homolog 1 (SOS1) inhibitor. SOS1-IN-22 can inhibit KRAS-G12C/SOS1 complex formation with an IC50 value of 40.28 nM. SOS1-IN-22 can reduce phosphorylation ERK levels. SOS1-IN-22 can be used for the research of cancer, such as pancreatic carcinoma and appendiceal carcinoma .
KRASG12C ligand-1 is a PROTAC target protein ligand that can be used to synthesize the PROTAC YN14-H (HY-173250). YN14-H is a PROTAC degrader targeting KRAS G12C and has antitumor activity .
YN14 mixture of diastereomers is the diastereomers of YN14 (HY-155356).
YN14 is a KRASG12C proteolysis targeting chimera (PROTAC). YN14 is highly potent and selective KRASG12C degrader and induces a stable KRASG12C: YN14: VHL ternary complex with low binding free energy (ΔG). YN14 has antiproliferative effects and significantly inhibits KRASG12C-mutant cancer cell growth .
K-Ras-IN-58 is a K-RAS inhibitor and shows inhibitory activity against KRASG12D,KRASG12C and KRAS WT. K-Ras-IN-58 inhibits proliferation of cancer cells .
KRAS-IN-41 is an inhibitor of KRAS with IC50 values of <0.01 μM for KRAS G12D and KRAS G12V. KRAS-IN-41 inhibits RAS mutant cell lines, GP2D (KRAS-G12D) and SW620 (KRAS-G12V). KRAS-IN-41 can be used in cancer research .
(3R,10R,14aS)-AZD4625 is the isomer of AZD4625 (HY-146223), and can be used as an experimental control. AZD4625 is an orally active, selective irreversible, covalent allosteric GTPase KRASG12C inhibitor with an IC50 of 3 nM. AZD4625 can inhibit the MAPK pathway (with decreased pCRAF, pMEK, and pERK) and the PI3K pathway (with decreased pAKT and pS6), and induce cell apoptosis. AZD4625 has no binding and inhibition of wild-type RAS or isoforms carrying non-KRASG12C mutations. AZD4625 can be used for the study of KRASG12C mutant non-small cell lung cancer .
KRASG12C IN-16 (Compound SK-17) is a selective, covalent and an orally active KRAS G12C inhibitor. KRASG12C IN-16 induces Apoptosis. KRASG12C IN-16 effectively prevents the activation of MAPK and PI3K/mTOR signaling pathways. KRASG12C IN-16 displays anti-tumor activity against pancreatic cancer .
KRASG12C IN-14 (compound 15) is an inhibitor targeting the KRAS G12C mutation. KRASG12C IN-14 inhibits CYPA-dependent KRAS-BRAF with an IC50 of 0.002 μM. KRASG12C IN-14 inhibits ERK phosphorylation in NCI-H358 cells with an IC50 of 0.002 μM .
KRASG12C IN-15 (Compound 21) is the orally active inhibitor for KRAS G12C, and inhibits SOS1-mediated GDP/GTP exchange with an IC50 of 19 nM. KRASG12C IN-15 inhibits the phosphorylation of ERK with IC50 of 0.051 μM. KRASG12C IN-15 inhibits the cell viability of KRAS G12C mutated MIA PaCa-2 with IC50 of 0.023 μM. KRASG12C IN-15 exhibits antitumor effect in MIA PaCa-2 xenograft mouse models .
MRTX1133 formic is a noncovalent, potent, and selective KRAS G12D inhibitor. MRTX1133 formic optimally fills the switch II pocket and extends three substituents to favorably interact with the protein, resulting in an estimated KD against KRAS G12D of 0.2 pM. MRTX1133 formic prevents SOS1-catalyzed nucleotide exchange and/or formation of the KRASG12D/GTP/RAF1 complex, thereby inhibiting mutant KRAS-dependent signal transduction. MRTX1133 formic shows efficacy in tumor models harboring KRAS G12D mutations .
SOS1-IN-17 (Compound 8d) is an orally active inhibitor for SOS1-KRASG12C interaction with an IC50 of 5.1 nM. SOS1-IN-17 inhibits ERK phosphorylation in DLD-1 cell with an IC50 of 18 nM. SOS1-IN-17 exhibits anti-proliferative activity in KRASG12C mutated Mia-Paca-2 cell with an IC50 of 0.11 μM. SOS1-IN-17 exhibits antitumor efficacy against pancreatic cancer in mouse model .
KRASG12C IN-20 is an orally potent KRAS G12C inhibitor with an EC50 of 3.9 nM. KRASG12C IN-20 covalently modifies KRAS G12C in its inactive GDP-bound state and locks it to block oncogenic signal transduction. KRASG12C IN-20 exhibits significant activity in lung adenocarcinoma xenograft models. KRASG12C IN-20 can be used for research related to lung adenocarcinoma .
CFL-137 is a potent KRasG12C inhibitor. CFL-137 shows an antiproliferative effect. CFL-137 shows anticancer activity. CFL-137 has the potential for the research of lung cancer .
KRAS G12C inhibitor 60 (compound 23) is a Kras-G12C inhibitor. KRAS G12C inhibitor 60 can be used for the research of lung cancer, colorectal cancer, pancreatic cancer .
KRASG12C IN-19 is a selective and orally active KRAS G12C inhibitor. KRASG12C IN-19 exerts potent antiproliferative activity against the KRAS G12C-mutant non small cell lung cancer (NSCLC) cell line H358 with an IC50 of 7.6 nM, and effectively suppresses downstream ERK phosphorylation (IC50 = 24.06 nM). KRASG12C IN 19 has no significant inhibitory activity against KRAS G12V and KRAS G12D-mutant cancer cells (PANC 1, Panc, AsPC 1, and GP2d cells) with IC50 > 10,000 nM. KRASG12C IN-19 rapidly forms a covalent bond with KRAS G12V-GDP, leading to dose-dependent inhibition of the downstream KRAS pathway. KRASG12C IN 19 can be employed for research in KRAS G12C driven cancers, including non small cell lung cancer, pancreatic cancer, and colorectal cancer .
KRAS G12C inhibitor 65 is a potent and covalent KRAS G12C inhibitor that traps KRAS G12C in the GDP-bound state. KRASG12C IN-1 exhibits potent antitumor activity against KRAS-mutant non-small cell lung cancer .
KRAS G12C inhibitor 69 (Compound K09) is the inhibitor for mutant RAS protein KRASG12C with an IC50 of 4.36 nM. KRAS G12C inhibitor 69 inhibits the ERK phosphorylation in NCI-H358 and MIA-PACA-2 with an IC50 of 12 nM and 7 nM. KRAS G12C inhibitor 69 inhibits the proliferation of cancer cell NCI-H358 and MIA-PACA-2 with IC50 of 3.15 nM and 2.33 nM .
KRASG12C IN-18 is an orally active covalent KRAS G12C inhibitor that achieves complete covalent engagement of KRAS G12C in both GDP- and GMPPNP-bound states and displays strong antiproliferative activity against KRAS G12C and resistance-associated variants, including KRAS G12C/R68S, with low-nanomolar IC50 values.
KRASG12C IN-18 exhibits marked in vivo efficacy in KRAS G12C-driven solid tumor and KRAS G12C/R68S xenograft models and can be used for colorectal cancer research .
RNK08954 is an orally active KRASG12D inhibitor with a Kd of 0.0395 nM. RNK08954 selectively binds the inactive GDP-bound KRASG12D form, suppresses downstream KRAS-mediated signaling pathways p-ERK1/2 experssion. RNK08954 inhibits KRASG12D-mutant cell proliferation, induces G0-G1 cell cycle arrest, and inhibits tumor growth in mouse xenograft models. RNK08954 can be used for the research of non-small cell lung cancer, pancreatic ductal adenocarcinoma .
KRAS G12C-IN-78 is a selective SWII-binding KRASG12C dual inhibitor targeting both inactive and active states. KRAS G12C-IN-78 rapidly inhibits ERK1/2 phosphorylation, induces covalent adduct formation with endogenous KRASG12C, suppresses MAPK pathway gene expression, and inhibits cellular proliferation in KRASG12C mutant cells. KRAS G12C-IN-78 can be used for the research of KRASG12C mutant solid tumors, including pancreatic ductal adenocarcinoma and non-small cell lung cancer .
KD36 is a selective KRAS-G12C inhibitor with an IC50 value of 0.92 μM. KD36 can inhibit the phosphorylation of ERK and AKT, induce the accumulation of reactive oxygen species (ROS), reduce mitochondrial membrane potential, thereby leading to apoptosis of KRAS-G12C mutant cells. KD36 can be used in the research of non-small cell lung cancer (NSCLC) .
(R)-ACBI-4 is an isomer of ACBI-4 (HY-176792). ACBI-4 is a selective GTP-loaded active state of KRAS (KRAS(on))PROTAC degrader. ACBI-4 has significant anti-proliferative effect and potently degrades multiple KRAS mutants in cancer cells, such as KRASG12R .
KRAS G12D-IN-36 (Compound 53a) is a highly selective and orally active KRAS-G12D inhibitor with an IC50 of 1.63 nM. KRAS G12D-IN-36 effectively inhibits p-ERK with an IC50 of 8.4 nM. KRAS G12D-IN-36 shows potent anti-proliferative activity against AsPC-1 cells. KRAS G12D-IN-36 can be used for research on pancreatic cancer .
KRASG12D-IN-1 (compound 22) is a KRAS G12D Inhibitor. KRASG12D-IN-1 has dose-dependent anti-tumor efficacy in the AsPC-1 xenograft mouse models with a tumor growth inhibition .
KRASG12D-IN-2 (compound 28) is a KRAS G12D Inhibitor. KRASG12D-IN-1 has dose-dependent anti-tumor efficacy in the AsPC-1 xenograft mouse models with a tumor growth inhibition .
KRASG12D-IN-1 (compound 22) is a KRAS G12D Inhibitor. KRASG12D-IN-1 has dose-dependent anti-tumor efficacy in the AsPC-1 xenograft mouse models with a tumor growth inhibition .
KRASG12D-IN-2 (compound 28) is a KRAS G12D Inhibitor. KRASG12D-IN-1 has dose-dependent anti-tumor efficacy in the AsPC-1 xenograft mouse models with a tumor growth inhibition .
KRASG12C IN-17 is an orally active covalent KRAS G12C inhibitor, showing strong inhibitory activity in KRAS G12C-mutant cancer cells (NCI-H23 IC50 = 0.7 nM; NCI-H358 IC50 = 0.5 nM).
KRASG12C IN-17 covalently and irreversibly binds to KRAS G12C with > 96% modification efficiency in both GDP-bound and GMPPNP-bound conformations.
KRASG12C IN-17 can be used for studies of KRAS-driven cancers, including colorectal cancer .
KRAS-IN-48 (Compound 1-01) is a KRAS mutant inhibitor, with Kd values of 2.58 nM and 5.49 μM for KRAS-G12D and KRAS-G12V, respectively. KRAS-IN-48 can be used in the research of cancer .
KRASG12D-IN-4 (example 38) is a KRas G12D inhibitor with an IC50 of 3.3 nM. KRASG12D-IN-4 inhibits proliferation of pancreatic cancer ASPC-1 cells with an IC50 of 12 nM .
KRASG12C IN-18 is an orally active covalent KRAS G12C inhibitor that achieves complete covalent engagement of KRAS G12C in both GDP- and GMPPNP-bound states and displays strong antiproliferative activity against KRAS G12C and resistance-associated variants, including KRAS G12C/R68S, with low-nanomolar IC50 values.
KRASG12C IN-18 exhibits marked in vivo efficacy in KRAS G12C-driven solid tumor and KRAS G12C/R68S xenograft models and can be used for colorectal cancer research .
RNK08954 is an orally active KRASG12D inhibitor with a Kd of 0.0395 nM. RNK08954 selectively binds the inactive GDP-bound KRASG12D form, suppresses downstream KRAS-mediated signaling pathways p-ERK1/2 experssion. RNK08954 inhibits KRASG12D-mutant cell proliferation, induces G0-G1 cell cycle arrest, and inhibits tumor growth in mouse xenograft models. RNK08954 can be used for the research of non-small cell lung cancer, pancreatic ductal adenocarcinoma .
KRAS G12D-IN-36 (Compound 53a) is a highly selective and orally active KRAS-G12D inhibitor with an IC50 of 1.63 nM. KRAS G12D-IN-36 effectively inhibits p-ERK with an IC50 of 8.4 nM. KRAS G12D-IN-36 shows potent anti-proliferative activity against AsPC-1 cells. KRAS G12D-IN-36 can be used for research on pancreatic cancer .
Inquiry Online
Your information is safe with us. * Required Fields.
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
to a PVDF membrane and blocked with 5% non-fat milk in TBST for 2 hour at room temperature. The primary antibody (1/1000) and Loading control antibody (Beta Actin, HY-P80438, 1/10000) was
used in 5% non-fat milk in TBST at 4°C overnight. Goat Anti-Mouse/Rabbit IgG-HRP Secondary Antibody (1/10000) was used for 1 hour at room temperature.
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
to a PVDF membrane and blocked with 5% non-fat milk in TBST for 2 hour at room temperature. The primary antibody (1/1000) and Loading control antibody (Beta Actin, HY-P80438, 1/10000) was
used in 5% non-fat milk in TBST at 4°C overnight. Goat Anti-Mouse/Rabbit IgG-HRP Secondary Antibody (1/10000) was used for 1 hour at room temperature.
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
to a PVDF membrane and blocked with 5% non-fat milk in TBST for 2 hour at room temperature. The primary antibody (1/1000) and Loading control antibody (Beta Actin, HY-P80438, 1/10000) was
used in 5% non-fat milk in TBST at 4°C overnight. Goat Anti-Mouse/Rabbit IgG-HRP Secondary Antibody (1/10000) was used for 1 hour at room temperature.
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
to a PVDF membrane and blocked with 5% non-fat milk in TBST for 2 hour at room temperature. The primary antibody (1/1000) and Loading control antibody (Beta Actin, HY-P80438, 1/10000) was
MedchemExpress Validation 03
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
MedchemExpress Validation 04
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
to a PVDF membrane and blocked with 5% non-fat milk in TBST for 2 hour at room temperature. The primary antibody (1/1000) and Loading control antibody (Beta Actin, HY-P80438, 1/10000) was
used in 5% non-fat milk in TBST at 4°C overnight. Goat Anti-Mouse/Rabbit IgG-HRP Secondary Antibody (1/10000) was used for 1 hour at room temperature.
MedchemExpress Validation
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
to a PVDF membrane and blocked with 5% non-fat milk in TBST for 2 hour at room temperature. The primary antibody (1/1000) and Loading control antibody (Beta Actin, HY-P80438, 1/10000) was
used in 5% non-fat milk in TBST at 4°C overnight. Goat Anti-Mouse/Rabbit IgG-HRP Secondary Antibody (1/10000) was used for 1 hour at room temperature.
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
to a PVDF membrane and blocked with 5% non-fat milk in TBST for 2 hour at room temperature. The primary antibody (1/1000) and Loading control antibody (Beta Actin, HY-P80438, 1/10000) was
used in 5% non-fat milk in TBST at 4°C overnight. Goat Anti-Mouse/Rabbit IgG-HRP Secondary Antibody (1/10000) was used for 1 hour at room temperature.
MedchemExpress Validation
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
to a PVDF membrane and blocked with 5% non-fat milk in TBST for 2 hour at room temperature. The primary antibody (1/1000) and Loading control antibody (Beta Actin, HY-P80438, 1/10000) was
used in 5% non-fat milk in TBST at 4°C overnight. Goat Anti-Mouse/Rabbit IgG-HRP Secondary Antibody (1/10000) was used for 1 hour at room temperature.
MedchemExpress Validation
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
to a PVDF membrane and blocked with 5% non-fat milk in TBST for 2 hour at room temperature. The primary antibody (1/1000) and Loading control antibody (Beta Actin, HY-P80438, 1/10000) was
used in 5% non-fat milk in TBST at 4°C overnight. Goat Anti-Mouse/Rabbit IgG-HRP Secondary Antibody (1/10000) was used for 1 hour at room temperature.
MedchemExpress Validation
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
to a PVDF membrane and blocked with 5% non-fat milk in TBST for 2 hour at room temperature. The primary antibody (1/1000) and Loading control antibody (Beta Actin, HY-P80438, 1/10000) was
used in 5% non-fat milk in TBST at 4°C overnight. Goat Anti-Mouse/Rabbit IgG-HRP Secondary Antibody (1/10000) was used for 1 hour at room temperature.
MedchemExpress Validation
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
to a PVDF membrane and blocked with 5% non-fat milk in TBST for 2 hour at room temperature. The primary antibody (1/1000) and Loading control antibody (Beta Actin, HY-P80438, 1/10000) was
used in 5% non-fat milk in TBST at 4°C overnight. Goat Anti-Mouse/Rabbit IgG-HRP Secondary Antibody (1/10000) was used for 1 hour at room temperature.
MedchemExpress Validation
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
to a PVDF membrane and blocked with 5% non-fat milk in TBST for 2 hour at room temperature. The primary antibody (1/1000) and Loading control antibody (Beta Actin, HY-P80438, 1/10000) was
used in 5% non-fat milk in TBST at 4°C overnight. Goat Anti-Mouse/Rabbit IgG-HRP Secondary Antibody (1/10000) was used for 1 hour at room temperature.
MedchemExpress Validation
Western blot analysis of extracts from THP-1(lane 2(20μg), Jurkat (lane 3(20μg) and NIH3T3(lane 4(20μg) using FOXO1A (HY-P80132) Rabbit mAb. Proteins were transferred
to a PVDF membrane and blocked with 5% non-fat milk in TBST for 2 hour at room temperature. The primary antibody (1/1000) and Loading control antibody (Beta Actin, HY-P80438, 1/10000) was
used in 5% non-fat milk in TBST at 4°C overnight. Goat Anti-Mouse/Rabbit IgG-HRP Secondary Antibody (1/10000) was used for 1 hour at room temperature.
MedChemExpress values your privacy and your trust is important to us. We use cookies to enhance your website experience. Some cookies are necessary to run the website.
Privacy and Cookie Policy
