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Zoldonrasib (RMC-9805) is a potent and orally active KRAS G12D inhibitor.Zoldonrasib induces apoptosis in KRAS G12D mutant cancer cells. Zoldonrasib has the potential for the research of KRAS G12D mutant cancer .
MRTX1133 is a noncovalent, potent, and selective alkyne-based KRAS G12D inhibitor. MRTX1133 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 prevents SOS1-catalyzed nucleotide exchange and/or formation of the KRAS G12D/GTP/RAF1 complex, thereby inhibiting mutant KRAS-dependent signal transduction. MRTX1133 selectively inhibits KRAS G12D mutant, but not KRAS wild-type, tumor cells. MRTX1133 has single digit nanomolar activity in cellular assays and marked in vivo efficacy in tumor models harboring KRAS G12D mutations .
AMG410 is a non-covalent and selective pan-KRAS inhibitor with IC50 values of 1-4 nM for KRAS G12D, KRAS G12V, and KRAS G13D. AMG410 shows greater than 100-fold selectivity against both HRAS and NRAS. AMG410 is a dual GTP(on)- and GDP(off)-state inhibitor (Kd(GDP-state) of 1 nM; Kd(GTP-state) of 22 nM). AMG410 blocks KRAS signaling in a cycling state-independent manner and also blocks proliferation in wildtype KRAS-amplified tumor cells. AMG410 can be used for the study of colorectal, pancreatic, and lung cancers .
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)) .
KRAS G12D inhibitor 29 (Compound Formula (I)) is an orally active and selective KRAS G12D mutant inhibitor. KRAS G12D inhibitor 29 blocks downstream signaling pathways mediated by KRAS G12D, suppressing tumor cell proliferation. KRAS G12D inhibitor 29 is promising for research of KRAS G12D mutation-related cancers (such as pancreatic cancer, lung cancer, colorectal cancer) .
HRS-4642 is a high affinity, selective, long-acting, and non-covalent KRAS G12D inhibitor with a Kd value of 0.083 nM. HRS-4642 inhibits the binding of KRAS G12D to SOS1 or RAF1, thereby blocking the downstream MEK-ERK signaling pathway. HRS-4642 promotes Apoptosis. HRS-4642 alone or combined with Carfilzomib (HY-10455) effectively shapes the tumor microenvironment. HRS-4642 has an anti-cancer effect on pancreatic and colorectal cancers carrying the KRAS G12D mutation[1][2][3].
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.
PROTAC K-Ras Degrader-4 (Compound 4) is a PROTAC degrader for KRAS that degrades KRAS G12D in GP5d and degrades KRAS G12V in cell SW620 with DC50s of 1 nM and 13 nM. PROTAC K-Ras Degrader-4 inhibits MAPK signaling pathway . (Pink: ligand for target protein pan-KRAS degrader 1 (HY-162960); Black: linker (HY-159790); Blue: ligand for E3 ligase VHL (HY-W998248))
RP03707 is a PROTAC degrader of KRAS G12D. RP03707 forms a ternary complex with KRAS G12D and the CRBN E3 ligase, promoting the ubiquitination and proteasomal degradation of KRAS G12D. RP03707 inhibits the growth of KRAS G12D-positive tumor cells .
2,4,7-Trichloro-8-fluoropyridopyrimidine is a pyridopyrimidine synthetic intermediate of MRTX1133 (HY-134813), which can be used for the synthesis of non-covalent KRAS G12D inhibitors .
KRAS inhibitor-9, a potent KRAS inhibitor (Kd=92 μM), blocks the formation of GTP-KRAS and downstream activation of KRAS. KRAS inhibitor-9 binds to KRAS G12D, KRAS G12C and KRAS Q61H protein with a moderate binding affinity. KRAS inhibitor-9 causes G2/M cell cycle arrest and induces apoptosis. KRAS inhibitor-9 selectively inhibits the proliferation of NSCLC cells with KRAS mutation but not normal lung cells .
Salvianolic acid F is a KRAS inhibitor, especially for KRAS G12D. Salvianolic acid F inhibits NF-kB, MMP-9, and NO simultaneously. Salvianolic acid F inhibits cancer cell growth, invasion, and migration and induces apoptosis via the EP300/PI3K/AKT pathway in vitro. Salvianolic acid F inhibits the growth of KRAS-dependent lung cancer cells via the PI3K/AKT signaling pathway in vivo. Salvianolic acid F can be used in the research of various cancers, including KRASG12D-driven non-small cell lung cancer (NSCLC) and ovarian cancer .
KRAS G12D inhibitor 14 is a potent KRAS G12D inhibitor with a KD of 33 nM for binding to KRAS G12D protein. KRAS G12D inhibitor 14 decreases the active form of KRAS G12D (KRAS G12D-GTP) but not KRAS G13D .
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 .
PROTAC K-Ras Degrader-5 is a cereblon-based K-Ras PROTAC degrader with a DC50 of <100 nM for KRAS G12D. PROTAC K-Ras Degrader-5 recruits KRAS G12D to the cereblon E3 ubiquitin ligase complex for ubiquitination and subsequent proteasomal degradation. PROTAC K-Ras Degrader-5 suppresses pERK levels downstream of KRAS G12D degradation in cancer cells. PROTAC K-Ras Degrader-5 reduces proliferation of cancer cells. PROTAC K-Ras Degrader-5 induces caspase 3/7 activity and cPARP, markers of apoptosis, in pancreatic cancer spheroids and tumors. PROTAC K-Ras Degrader-5 can be used for the research of pancreatic cancer and colorectal cancer .
TH-Z835 is a mutant selective KRAS (G12D) inhibitor with an IC50 of 1.6 μM. TH-Z835 inhibits both mantGMPPNP/GPPNP exchange and GPPNP/mantGMPPNP exchange .
KRAS inhibitor-31 (compound 33) is a KRAS inhibitor, with KD (SPR) values of 0.019 nM, 0.019 nM and 0.096 nM for KRas G12D, KRas G12C and KRas G12V, respectively .
IPS-06061 is an orally active molecular glue forming a ternary complex of CRBN-KRAS G12D-IPS06061, degrading KRAS G12D with a DC50 value lower than 500 nM. IPS-06061 shows a strong anti-tumor efficacy .
PROTAC K-Ras Degrader-3 (compound 40) is a PROTAC degrader of K-Ras with a DC50 of ≤ 1 nM against SW620 KRAS G12D, and a GI50 of ≤ 10 nM against SW620 3D cell growth. PROTAC K-Ras Degrader-3 can be utilized in cancer research, such as non-small-cell lung cancer (NSCLC) .
Eras-4001 (Compound 14-1) is a pan-KRAS inhibitor. Eras-4001 has potent antitumor activities and significantly inhibits the proliferation of wild-type and mutant (such as KRAS G12D, KRAS G12V and KRAS G12C) cancer cells. Eras-4001 effectively inhibits tumor growth in GP2D and Panc0403 xenograft mouse models .
(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 .
PROTAC KRAS G12D degrader 2 is a peptidomimetic PROTAC specifically targeting the dimeric SARS-CoV-2 3CL Pro protein. PROTAC KRAS G12D degrader 2 inhibits SARS-CoV-2 3CLPro with an IC50 of 21.2 μM. PROTAC KRAS G12D degrader 2 specifically binds to the active site of SARS-CoV-2 3CL Pro. PROTAC KRAS G12D degrader 2 reduces protein levels of SARS-CoV-2 3CL Pro without affecting cell viability. PROTAC KRAS G12D degrader 2 can be used for the study of viral infections in Coronavirus genera .
KRAS G12D inhibitor 3 TFA is a KRAS G12D inhibitor with an IC50 of <500 nM. KRAS G12D inhibitor 3 TFA has antitumor effects (WO2022002102A1; compound 146) . KRAS G12D inhibitor 3 (TFA) is a click chemistry reagent, it contains an Alkyne group and can undergo copper-catalyzed azide-alkyne cycloaddition (CuAAc) with molecules containing Azide groups.
KRAS inhibitor-3 is an inhibitor of KRAS inhibitor. KRAS inhibitor-3 binds to WT and oncogenic KRAS mutants with high affinity (KD: 0.28 μM for KRAS WT, 0.63 μM for KRAS G12C, 0.37 μM for KRAS G12D, 0.74 μM for KRAS Q61H). KRAS inhibitor-3 also disrupts interaction of KRAS with Raf .
(2R,7aS)-2-Fluorotetrahydro-1H-pyrrolizine-7a(5H)-methanol is a drug intermediate for synthesis of various active compounds. (2R,7aS)-2-Fluorotetrahydro-1H-pyrrolizine-7a(5H)-methanol is a core structural framework of the compounds targeting KRAS G12D mutation.
SAH-SOS1A TFA is a peptide-based SOS1/KRAS protein interaction inhibitor. SAH-SOS1A TFA binds to wild-type and mutant KRAS (G12D, G12V, G12C, G12S, and Q61H) with nanomolar affinity (EC50=106-175 nM). SAH-SOS1A TFA directly and independently blocks nucleotide association. SAH-SOS1A TFA impairs KRAS-driven cancer cell viability and exerts its effects by on-mechanism blockade of the ERK-MAPK phosphosignaling cascade downstream of KRAS .
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 .
KRAS G12D-IN-30 (Compound 4) is a KRAS inhibitor. KRAS G12D-IN-30 inhibits the activation of the downstream MAPK signaling cascade (Raf1-MEK-ERK) by blocking the activity of the KRAS G12 mutant. KRAS G12D-IN-30 can be used for the research of cancer .
KRAS G12D inhibitor 10 is a potent inhibitor of KRAS G12D. The Ras family of proteins is an important intracellular signaling molecule that plays an important role in growth and development. KRAS G12D inhibitor 10 has the potential for the research of KRAS G12D-mediated cancer (extracted from patent WO2021108683A1, compound 34) .
KRAS G12D inhibitor 13 is a potent inhibitor of KRAS G12D. The Ras family of proteins is an important intracellular signaling molecule that plays an important role in growth and development. KRAS G12D inhibitor 13 has the potential for the research of KRAS G12D-mediated cancer (extracted from patent WO2021108683A1, compound 142) .
MRTX-EX185 formic is a potent KRAS (G12D) inhibitor with an IC50 of 90 nM. MRTX-EX185 formic can binds both GDP-loaded and active GNP states of KRAS and KRAS (G12D). MRTX-EX185 formic exhibits broad-spectrum binding properties with IC50s of 110, 290, 130 and 240 nM for KRAS WT, KRAS (G12C), KRAS (Q61H), KRAS (G13D). MRTX-EX185 formic also binds GDP-loaded HRAS. MRTX-EX185 formic can be used to study various RAS-driven tumors (such as pancreatic cancer) .
SS-3091 is a pan-KRas inhibitor active across KRasG12D, KRasG12C, KRasG12V, KRasG12S mutants, with minimal effects on non-KRas-driven cancer cells. SS-3091 binds to the KRas·ARaf interaction interface, destabilizes the complex, and attenuates KRas activity. SS-3091 suppresses phosphorylation of S6K, Akt, and ERK. SS-3091 reduces proliferation and decreases colony formation of cancer cells bearing KRasG12 mutations. SS-3091 can be used for the research of KRas-driven cancers .
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-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 .
KRAS G12D inhibitor 1 is a KRAS G12D inhibitor with an IC50 value of 0.4 nM. KRAS G12D inhibitor 1 inhibits KRas G12D-mediated ERK phosphorylation. KRAS G12D inhibitor 1 can be used for cancer research .
(R)-KRAS G12D inhibitor 28 hydrochloride dehydrate is the hydrochloride dehydrate of (R)-KRAS G12D inhibitor 28 (HY-172626). KRAS G12D inhibitor 28 (Compound 2) is a KRAS G12D inhibitor. KRAS G12D inhibitor 28 (Compound 2) can be used in the cancer research .
KRAS G12D inhibitor 3 is a KRAS G12D inhibitor with an IC50 of <500 nM. KRAS G12D inhibitor 3 has antitumor effects (WO2022002102A1; compound 146) . KRAS G12D inhibitor 3 is a click chemistry reagent, it contains an Alkyne group and can undergo copper-catalyzed azide-alkyne cycloaddition (CuAAc) with molecules containing Azide groups.
KRAS G12D ligand-Linker Conjugate 2 is a conjugate of the KRAS (G12D) ligand (HY-175859) and the linker (HY-168698). KRAS G12D ligand-Linker Conjugate 2 can be used for synthesizing PROTAC KRAS (G12D) degrader ASP-3082 (HY-157505) .
KRAS G12D inhibitor 15 is a potent inhibitor of KRAS G12D. KRAS G12D inhibitor 15 has the potential for the research of various diseases or disorders, such as cancer or cancer metastasis (extracted from patent WO2022042630A1, compound 243) . KRAS G12D inhibitor 15 is a click chemistry reagent, it contains an Alkyne group and can undergo copper-catalyzed azide-alkyne cycloaddition (CuAAc) with molecules containing Azide groups.
KRAS G12D inhibitor 12 is a potent inhibitor of KRAS G12D. The Ras family of proteins is an important intracellular signaling molecule that plays an important role in growth and development. KRAS G12D inhibitor 12 has the potential for the research of KRAS G12D-mediated cancer (extracted from patent WO2021108683A1, compound 134) .
KRAS G12D inhibitor 11 is a potent inhibitor of KRAS G12D. The Ras family of proteins is an important intracellular signaling molecule that plays an important role in growth and development. KRAS G12D inhibitor 11 has the potential for the research of KRAS G12D-mediated cancer (extracted from patent WO2021108683A1, compound 52) .
KRAS G12D inhibitor 8 is a potent inhibitor of KRAS G12D. The Ras family of proteins is an important intracellular signaling molecule that plays an important role in growth and development. KRAS G12D inhibitor 8 has the potential for the research of KRAS G12D-mediated cancer (extracted from patent WO2021107160A1, compound 2) .
KRAS G12D-IN-34 (Compound 13) is a KRAS (G12D) inhibitor with IC50 values for KRAS (G12D) and KRAS (WT) of 1.05 nM and 1.59 μM respectively. KRAS G12D-IN-34 can be used for research on non-small cell lung cancer .
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)) .
KRAS inhibitor-37 (compound 2) is a potent KRAS inhibitor with KDs of 0.004 nM, 0.041 nM, 0.019 nM and 0.144 nM for KRAS wild type, KRAS G12D, KRAS G12C and KRAS G12V by SPR binding assay, respectively. KRAS inhibitor-37 inhibits cell proliferation with IC50s of <2 nM-14 nM for H358, SW620, PANC08.13 cells, respectively. KRAS inhibitor-37 has the potential for cancer research .
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 .
KRAS G12D inhibitor 16 is a KRAS G12D inhibitor. KRAS G12D inhibitor 16 has inhibitory activity against KRAS G12D and KRAS G12D mutation with IC50 value of 0.7 nM and 0.35 μM, respectively. KRAS G12D inhibitor 16 can be used for the research of many malignant tumor, such as pancreatic ductal adenocarcinomas (PDAC), colon and rectal carcinomas (CRC), non-small cell lung carcinomas (NSCLC) .
KRAS G12D inhibitor 23 (compound 46-3) is a potent inhibitor of KRAS G12D, with the IC50 of 0.007 μM. KRAS G12D inhibitor 23 plays an important role in cancer research .
KRAS G12D inhibitor 22 (compound 6) is a inhibitor of KRAS mutation. KRAS G12D inhibitor 22 has high activity (IC50<100 nM), good selectivity and low toxicity.KRAS G12D inhibitor 22 can be used in breast cancer research .
KRAS G12D-IN-31 is a potent KRAS G12D inhibitor with an IC50 of < 100 nM. KRAS G12D-IN-31 inhibits the proliferation of RAS-dependent cells (KRAS G12C, KRAS G12D, KRAS G12V and KRAS WT). KRAS G12D-IN-31 can be used to study non-small cell lung cancer, gastric cancer, colon cancer, and malignant melanoma .
KRAS-IN-5 (Compound Ex 6) is an orally active and selective inhibitor targeting KRAS mutants (including KRAS G12D, KRAS G12V, KRAS WT) with a GNE IC50 value of 1.3 nM against KRAS G12D. KRAS-IN-5 blocks tumor cell proliferation by inhibiting KRAS-mediated signaling pathways (e.g., reducing ERK phosphorylation). KRAS-IN-5 is promising for research of KRAS mutation-related cancers, such as pancreatic cancer, colorectal cancer, lung cancer .
(S)-AZD0022 is an isomer of AZD0022, AZD0022 is a selective and orally active KRAS G12D inhibitor. AZD0022 inhibits KRAS pathway suppression in the GP2D xenograft model .
MRTX-EX185 is a potent KRAS (G12D) inhibitor with an IC50 of 90 nM. MRTX-EX185 can binds both GDP-loaded and active GNP states of KRAS and KRAS (G12D). MRTX-EX185 exhibits broad-spectrum binding properties with IC50s of 110, 290, 130 and 240 nM for KRAS WT, KRAS (G12C), KRAS (Q61H), KRAS (G13D). MRTX-EX185 also binds GDP-loaded HRAS. MRTX-EX185 can be used to study various RAS-driven tumors (such as pancreatic cancer) .
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) .
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) .
SAH-SOS1A is a peptide-based SOS1/KRAS protein interaction inhibitor. SAH-SOS1A binds to wild-type and mutant KRAS (G12D, G12V, G12C, G12S, and Q61H) with nanomolar affinity (EC50=106-175 nM), directly and independently blocks nucleotide association, impairs KRAS-driven cancer cell viability, and exerts its effects by on-mechanism blockade of the ERK-MAPK phosphosignaling cascade downstream of KRAS .
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 .
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 .
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 .
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 .
KRAS G12D modulator-1 (compound 6) is a potent KRAS G12D modulator with IC50 values of 1-10 μM for NEA-G12D, PPI-G12D, and p ERK-AGS, respectively. KRAS G12D modulator-1 can be used in research of cancer .
KRAS G12D inhibitor 9 is a potent inhibitor of KRAS G12D. The Ras family of proteins is an important intracellular signaling molecule that plays an important role in growth and development. KRAS G12D inhibitor 9 has the potential for the research of KRAS G12D-mediated cancer (extracted from patent WO2021108683A1, compound 20) .
KRAS G12D inhibitor 25 (Compound 148) is an inhibitor for KRAS G12C and HSP90α with IC50 of < 0.1 μM and 0.1-1 μM, respectively. KRAS G12D inhibitor 25 inhibits the proliferation of MIA PaCa-2 and NCI-H358 with EC50 of < 0.1 μM and 0.1-1 μM, respectively. KRAS G12D inhibitor 25 degrades ERBB2 with a DC50 of 0.1-1 μM .
KRAS-IN-42 (Compound Z1063) is a covalent KRAS G12D mutants inhibitor. KRAS-IN-42 is promising for research of KRAS G12D-mutant cancers (e.g., non-small cell lung cancer, 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 .
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 .
SIAIS562055 is a potent cereblon-based SOS1 PROTAC with a Kd of 95.9 nM. SIAIS562055 exhibits sustained degradation of SOS1 and inhibition of downstream ERK pathways. SIAIS562055 effectively blocked the binding of KRAS G12C or KRAS G12D to SOS1, with the IC50 values of 95.7 nM and 134.5 nM, respectively. SIAIS562055 exhibits potent anticancer activity. (Pink: SOS1 ligand (HY-168638); Black: linker (HY-W539874); Blue: E3 ligase ligand (HY-W076696)) .
KRAS G12D ligand-3 is a KRAS G12D PROTAC ligand. KRAS G12D ligand-3 can be conjugated with E3 ligase Ligand (HY-170348) and linke (HY-W895436) to synthesize KRAS G12D PROTAC degrader MS243 (HY-181728). MS243 can be used for cancer research .
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 .
KRAS G12D-IN-37 is a KRAS G12D inhibitor. KRAS G12D-IN-37 shows antiproliferative activity against KRAS G12D mutant tumor cells and minimal cytotoxicity toward normal cells. KRAS G12D-IN-37 binds stably to KRAS G12D via hydrogen bond interactions with residues His 95, Arg 68, and Asp 12, and inhibits downstream ERK/AKT signaling pathways. KRAS G12D-IN-37 elevates ROS levels, induces apoptosis, disrupts mitochondrial membrane potential. KRAS G12D-IN-37 downregulates the level of anti-apoptotic protein Bcl-2, and upregulates the levels of pro-apoptotic proteins Bax and caspase 3. KRAS G12D-IN-37 can be used for the research of cancer, such as gastric adenocarcinoma and colorectal cancer .
KRAS G12D-IN-32 (Page 158) is a KRAS G12D inhibitor. KRAS G12D-IN-32 can be used to study adenocarcinoma, colorectal cancer, and non-small cell lung cancer .
KRAS G12D-IN-27 (H12a) is an inhibitor of KRAS G12D. KRAS G12D-IN-27 inhibits ERK phosphorylation, with an IC50 of 112 nM. KRAS G12D-IN-27 can be used in cancer research .
KRAS G12D-IN-35 (example 7) is a potent and orally active KRAS G12D inhibitor. KRAS G12D-IN-35 suppresses p-ERK in AGS cells and potently inhibits the proliferation of various KRAS G12D-mutant cancer cell lines. KRAS G12D-IN-35 inhibits tumor growth in HPAC and GP2D mouse models. KRAS G12D-IN-35 can be used for cancer research, such as pancreatic and colorectal cancer .
MS243 is a potent KRAS G12D PROTAC degrader with a DC50 of 4.2 nM. MS243 promotes the proximity between KRAS G12D and the VHL E3 ubiquitin ligase, drives the ubiquitination and proteasomal degradation of KRAS G12D, and inhibits the proliferation of cancer cells harboring KRAS G12D. MS243 can be used in the research of KRAS G12D-carrying cancers, such as colon cancer and pancreatic cancer .
KRAS-IN-58 is a KRAS inhibitor with a IC50 of 0.223 μM against KRAS G12D. KRAS-IN-58 binds to KRAS G12C and KRAS G12D proteins, and reduces the levels of phosphorylated Raf1, AKT and ERK in pancreatic cancer cells. KRAS-IN-58 can be used for the research of pancreatic cancer .
KRAS-IN-48 free base (Compound 1-01) is a mutant KRAS inhibitor, with Kd values of 2.58 nM and 5.49 μM for KRAS G12D and KRAS G12V, respectively. KRAS-IN-48 free base affects pERK expression in cells harboring KRAS G12D and KRAS G12V mutations, with IC50 values of 1.1 μM and 1.51 μM, respectively. KRAS-IN-48 free base can be used in the research of cancer .
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 .
PPI stabilizer-1-1 (Compound 2) is a KRAS dimerizing agent. PPI stabilizer-1-1 dimerizes KRAS with a KD of 3.8 µM. PPI stabilizer-1-1 co-crystallizes with GCP-KRASG12D. PPI stabilizer-1 can be used for the research of KRAS-driven cancers .
E3 Ligase Ligand-linker Conjugate 224 is an E3 Ligase Ligand-Linker Conjugate that incorporates a ligand for VHL (HY-170348) and a PROTAC linker (HY-W895436). E3 Ligase Ligand-linker Conjugate 224 can be used for synthesis of KRAS G12D PROTAC degrader MS243 (HY-181728) .
KRAS-IN-54 is a macrocyclic KRAS inhibitor. KRAS-IN-54 exhibits activity against cell viability and pERK inhibition in cells with KRAS G12D and KRAS G13D mutations. KRAS-IN-54 can be used in the research of KRAS-mutant cancers, including pancreatic adenocarcinoma, colorectal cancer, non-small cell lung cancer, esophageal cancer, gallbladder cancer, melanoma, ovarian cancer and endometrial cancer .
KRAS-IN-55 is a pan-KRAS inhibitor with IC50 values of 4.3, 9.6 and 1.6 nM against KRAS G12C, KRAS G12D and KRAS G12V, respectively. KRAS-IN-55 induces the formation of a new binding pocket on KRAS, thereby forming a high-affinity ternary complex with cyclophilin A (CYPA), inhibiting the interactions of KRAS with downstream effectors RAF and PI3K, and blocking oncogenic MAPK and PI3K signaling pathways. KRAS-IN-55 is applicable to cancer research such as colorectal cancer and non-small cell lung cancer .
AMG410 diTFA is a non-covalent and selective pan-KRAS inhibitor with IC50 values of 1-4 nM for KRAS G12D, KRAS G12V, and KRAS G13D. AMG410 diTFA shows greater than 100-fold selectivity against both HRAS and NRAS. AMG410 diTFA is a dual GTP(on)- and GDP(off)-state inhibitor (Kd(GDP-state) of 1 nM; Kd(GTP-state) of 22 nM). AMG410 diTFA blocks KRAS signaling in a cycling state-independent manner and also blocks proliferation in wildtype KRAS-amplified tumor cells. AMG410 diTFA can be used for the study of colorectal, pancreatic, and lung cancers .
(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.
SAH-SOS1A TFA is a peptide-based SOS1/KRAS protein interaction inhibitor. SAH-SOS1A TFA binds to wild-type and mutant KRAS (G12D, G12V, G12C, G12S, and Q61H) with nanomolar affinity (EC50=106-175 nM). SAH-SOS1A TFA directly and independently blocks nucleotide association. SAH-SOS1A TFA impairs KRAS-driven cancer cell viability and exerts its effects by on-mechanism blockade of the ERK-MAPK phosphosignaling cascade downstream of KRAS .
SAH-SOS1A is a peptide-based SOS1/KRAS protein interaction inhibitor. SAH-SOS1A binds to wild-type and mutant KRAS (G12D, G12V, G12C, G12S, and Q61H) with nanomolar affinity (EC50=106-175 nM), directly and independently blocks nucleotide association, impairs KRAS-driven cancer cell viability, and exerts its effects by on-mechanism blockade of the ERK-MAPK phosphosignaling cascade downstream of KRAS .
Salvianolic acid F is a KRAS inhibitor, especially for KRAS G12D. Salvianolic acid F inhibits NF-kB, MMP-9, and NO simultaneously. Salvianolic acid F inhibits cancer cell growth, invasion, and migration and induces apoptosis via the EP300/PI3K/AKT pathway in vitro. Salvianolic acid F inhibits the growth of KRAS-dependent lung cancer cells via the PI3K/AKT signaling pathway in vivo. Salvianolic acid F can be used in the research of various cancers, including KRASG12D-driven non-small cell lung cancer (NSCLC) and ovarian 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 .
KRAS G12D-IN-35 (example 7) is a potent and orally active KRAS G12D inhibitor. KRAS G12D-IN-35 suppresses p-ERK in AGS cells and potently inhibits the proliferation of various KRAS G12D-mutant cancer cell lines. KRAS G12D-IN-35 inhibits tumor growth in HPAC and GP2D mouse models. KRAS G12D-IN-35 can be used for cancer research, such as pancreatic and colorectal cancer .
MRTX1133 is a noncovalent, potent, and selective alkyne-based KRAS G12D inhibitor. MRTX1133 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 prevents SOS1-catalyzed nucleotide exchange and/or formation of the KRAS G12D/GTP/RAF1 complex, thereby inhibiting mutant KRAS-dependent signal transduction. MRTX1133 selectively inhibits KRAS G12D mutant, but not KRAS wild-type, tumor cells. MRTX1133 has single digit nanomolar activity in cellular assays and marked in vivo efficacy in tumor models harboring KRAS G12D mutations .
KRAS inhibitor-31 (compound 33) is a KRAS inhibitor, with KD (SPR) values of 0.019 nM, 0.019 nM and 0.096 nM for KRas G12D, KRas G12C and KRas G12V, respectively .
KRAS G12D inhibitor 3 TFA is a KRAS G12D inhibitor with an IC50 of <500 nM. KRAS G12D inhibitor 3 TFA has antitumor effects (WO2022002102A1; compound 146) . KRAS G12D inhibitor 3 (TFA) is a click chemistry reagent, it contains an Alkyne group and can undergo copper-catalyzed azide-alkyne cycloaddition (CuAAc) with molecules containing Azide groups.
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 .
MRTX-EX185 formic is a potent KRAS (G12D) inhibitor with an IC50 of 90 nM. MRTX-EX185 formic can binds both GDP-loaded and active GNP states of KRAS and KRAS (G12D). MRTX-EX185 formic exhibits broad-spectrum binding properties with IC50s of 110, 290, 130 and 240 nM for KRAS WT, KRAS (G12C), KRAS (Q61H), KRAS (G13D). MRTX-EX185 formic also binds GDP-loaded HRAS. MRTX-EX185 formic can be used to study various RAS-driven tumors (such as 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 .
KRAS G12D inhibitor 1 is a KRAS G12D inhibitor with an IC50 value of 0.4 nM. KRAS G12D inhibitor 1 inhibits KRas G12D-mediated ERK phosphorylation. KRAS G12D inhibitor 1 can be used for cancer research .
KRAS G12D inhibitor 3 is a KRAS G12D inhibitor with an IC50 of <500 nM. KRAS G12D inhibitor 3 has antitumor effects (WO2022002102A1; compound 146) . KRAS G12D inhibitor 3 is a click chemistry reagent, it contains an Alkyne group and can undergo copper-catalyzed azide-alkyne cycloaddition (CuAAc) with molecules containing Azide groups.
KRAS G12D ligand-Linker Conjugate 2 is a conjugate of the KRAS (G12D) ligand (HY-175859) and the linker (HY-168698). KRAS G12D ligand-Linker Conjugate 2 can be used for synthesizing PROTAC KRAS (G12D) degrader ASP-3082 (HY-157505) .
KRAS G12D inhibitor 15 is a potent inhibitor of KRAS G12D. KRAS G12D inhibitor 15 has the potential for the research of various diseases or disorders, such as cancer or cancer metastasis (extracted from patent WO2022042630A1, compound 243) . KRAS G12D inhibitor 15 is a click chemistry reagent, it contains an Alkyne group and can undergo copper-catalyzed azide-alkyne cycloaddition (CuAAc) with molecules containing Azide groups.
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 .
KRAS G12D inhibitor 23 (compound 46-3) is a potent inhibitor of KRAS G12D, with the IC50 of 0.007 μM. KRAS G12D inhibitor 23 plays an important role in cancer research .
MRTX-EX185 is a potent KRAS (G12D) inhibitor with an IC50 of 90 nM. MRTX-EX185 can binds both GDP-loaded and active GNP states of KRAS and KRAS (G12D). MRTX-EX185 exhibits broad-spectrum binding properties with IC50s of 110, 290, 130 and 240 nM for KRAS WT, KRAS (G12C), KRAS (Q61H), KRAS (G13D). MRTX-EX185 also binds GDP-loaded HRAS. MRTX-EX185 can be used to study various RAS-driven tumors (such as pancreatic 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 .
KRAS-IN-42 (Compound Z1063) is a covalent KRAS G12D mutants inhibitor. KRAS-IN-42 is promising for research of KRAS G12D-mutant cancers (e.g., non-small cell lung cancer, colorectal cancer) .
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 .
KRAS-IN-48 free base (Compound 1-01) is a mutant KRAS inhibitor, with Kd values of 2.58 nM and 5.49 μM for KRAS G12D and KRAS G12V, respectively. KRAS-IN-48 free base affects pERK expression in cells harboring KRAS G12D and KRAS G12V mutations, with IC50 values of 1.1 μM and 1.51 μM, respectively. KRAS-IN-48 free base can be used in the research of cancer .
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 .
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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.
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