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.
RMC-7977 is an orally active triple-complex RAS inhibitor that can simultaneously bind to cyclophilin A (CYPA) (Kd = 195 nM) and KRAS (G12V) (Kd = 292 μM). It exhibits broad-spectrum inhibitory activity against KRAS, NRAS, and HRAS proteins and their various wild-type and mutant variants. RMC-7977 induces apoptosis by inhibiting the phosphorylation of ERK, CRAF, and RSK, as well as increasing PARP cleavage. This leads to tumor regression, reduces resistance in KRAS G12C cancer models, and demonstrates good tolerability across various RAS cancer models .
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 .
RMC-5127 is a small molecule inhibitor that binds to GTP-targeted KRAS G12V, with oral bioavailability and blood-brain barrier permeability. RMC-5127 inhibits the activities of the RAS and MAPK pathways, suppresses the proliferation of KRAS G12V-mutant cancer cells and induces their apoptosis. RMC-5127 can be used for the research of KRAS G12V-mutant non-small cell lung cancer, pancreatic ductal adenocarcinoma, colorectal cancer and intracranial KRAS G12V tumors .
Basroparib (STP1002) is a selective, orally active inhibitor of tankyrase (TNKS1/TNKS2) with IC50 of 29.94 nM and 3.68 nM for TNKS1 and TNKS2, respectively. Basroparib has an IC50 of >10 μM for PARP1. Basroparib binds to TNKS, stabilizes AXIN1/2 proteins, blocks Wnt/β-catenin signaling pathway, inhibits tumor cell proliferation and induces apoptosis, while reducing cancer stem cell properties. Basroparib can be used in colorectal cancer (CRC) studies with KRAS mutations (such as G12V/G12D) to overcome acquired resistance to MEK inhibitors. STP1002 has synergistic antitumor activity with MEK inhibitors .
pan-KRAS-IN-18 is a panKRAS inhibitor that inhibits KRAS WT and KRAS G12V with IC50s of 29 and 9 nM, respectively. pan-KRAS-IN-18 exhibits antiproliferative activity in KRAS-mutant cell lines. pan-KRAS-IN-18 can be used for lung cancer research .
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))
MCB-36 is a VHL-recruiting pan-KRAS PROTAC degrader without affecting KRAS transcription. MCB-36 exhibits minimal effects on HRAS and NRAS protein levels. MCB-36 binds to the GDP-loaded state of G12D, G12C, G12V, and wild-type KRAS with high affinities Kd ≈ 1 pM). MCB-36 decreases p-ERK levels, leading to cell apoptosis. MCB-36 effectively suppress KRAS G12C inhibitor-resistant cancer cells and remodel the tumor immune microenvironment. MCB-36 can be used for the study of colorectal cancer and lung cancer (Pink: Target protein ligand; Blue: E3 ligand (HY-112078); Black: Linker (HY-W091879)) .
RSC-1255 is a potent and selective Vacuolar H⁺-ATPase (V-ATPase) inhibitor that directly binds the mammalian V-ATPase complex with a Kd = 23 nM. RSC-1255 exhibits preferential cytotoxicity toward KRAS-mutant cancer cells, especially KRAS G13D and KRAS G12V cells. RSC-1255 induces apoptosis and blocks lysosomal acidification, autophagy, and macropinocytosis in cancer cells. RSC-1255 can be used for the study of KRAS-driven lung and colon cancers .
Rineterkib (compound B) is an orally available ERK1 and ERK2 inhibitor in the treatment of a proliferative disease characterized by activating mutations in the MAPK pathway. The activity is particularly related to the treatment of KRAS-mutant NSCLC, BRAF-mutant NSCLC, KRAS-mutant pancreatic cancer, KRAS-mutant colorectal cancer (CRC) and KRAS-mutant ovarian cancer. Rineterkib hydrochloride can also inhibit RAF .
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 .
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 .
RAS inhibitor Abd-7, a potent RAS-binding compound (Kd=51 nM), is a RAS-effector protein-protein interaction (PPI) inhibitor. RAS inhibitor Abd-7 interacts with RAS inside the cells, prevents RAS-effector interactions and inhibits endogenous RAS-dependent signaling. RAS inhibitor Abd-7 impairs the PPI of various mutant KRAS proteins with PI3K, CRAF and RALGDS as well as NRAS Q61H and HRAS G12V .
KRAS G12V Peptide is a specific peptide derived from the Kirsten rat sarcoma virus (KRAS) gene carrying the G12V oncogenic mutation. KRAS G12V Peptide induces responses like IFN-γ secretion and cytotoxicity. KRAS G12V Peptide can be used for the study of immune responses against KRAS G12V-mutant tumors .
KRAS G12V Peptide TFA is the trifluoroacetate salt of KRAS G12V Peptide (HY-P11355). KRAS G12V Peptide is a specific peptide derived from the Kirsten rat sarcoma virus (KRAS) gene carrying the G12V oncogenic mutation. KRAS G12V Peptide induces responses like IFN-γ secretion and cytotoxicity. KRAS G12V Peptide can be used for the study of immune responses against KRAS G12V-mutant tumors .
MCB-294 is a dual-state pan-KRAS inhibitor that selectively inhibits KRAS over NRAS and HRAS. MCB-294 capable of binding both the active (GTP-bound) and inactive (GDP-bound) forms of KRAS with Kds of approximately 1 pM and 10 nM, respectively. MCB-294 broadly impairs the growth of hTERT-HPNE cells expressing G12D, G12C, G12V, G12S, G13D, and wild-type KRAS, with IC50s of approximately 700 nM. MCB-294 induces irreversible apoptosis in KRAS-mutated tumors. MCB-294 effectively suppress KRAS G12C inhibitor-resistant cancer cells and remodel the tumor immune microenvironment. MCB-294 can be used for the study of pancreatic cancer, colorectal cancer and lung cancer .
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 .
PROTAC pan-KRAS degrader-1 is a pan-KRASPROTAC degrader for degrading different KRAS mutation types, such as G12D, G12C, G12V, and G13D. PROTAC pan-KRAS degrader-1 potently degrades KRAS mutation (G12D) in AGS cells, with a DC50 of 1.1 nM, Dmax of 95%. PROTAC pan-KRAS degrader-1 can be used to search diseases caused by KRAS mutation or amplification, especially cancers such as breast cancer, bladder cancer, gastric cancer, etc . Pink: pan-KRAS ligand (HY-176490); Blue: VHL ligase ligand (HY-170353); Black: linker (HY-176491);
pan-KRAS-IN-2 (Compound 6) is a pan-inhibitor with IC50s ≤ 10 nM for KRAS WT and mutants (G12D,G12C, G12V, G12S, G12A and Q61H); and an IC50 > 10 μM for KRAS G13D. pan-KRAS-IN-2 can be used to study various KRAS-mediated cancers, such as pancreatic cancer and colorectal cancer .
KRAS inhibitor-27 (Compound 15h) is the inhibitor for KRAS. KRAS inhibitor-27 inhibits KRAS G12D/G12V mutated cells AsPC-1, SW620 and KRAS wildtype cell HT-29 with IC50 of 378, 0.6 and 3230 nM, respectively. KRAS inhibitor-27 inhibits ERK phosphorylation (IC50 in cell AsPC-1 and SW620 is 0.6 nM and 1 nM), reduces the expression of DUSP4, thereby inhibiting MAPK signaling pathway .
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 .
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 .
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)) .
PROTAC K-Ras degrader-2 (compound 48) is a KRAS G12V PROTAC degrader with an IC50 of 20-200 nM for KRAS G12V/RAF1. PROTAC K-Ras degrader-2 degrades SW620 KRAS G12V with a DC50 of 1-10 nM. PROTAC K-Ras degrader-2 inhibits cell growth of SW620 3D cell with an IC50 of ≤10 nM. PROTAC K-Ras degrader-2 can be used for the study of colorectal cancer (CRC) .
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 .
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 .
KRAS-IN-43 (Compound 9) is a pan-KRAS inhibitor with IC50 values of 0.15 μM, 0.14 μM, and 0.47 μM against KRAS G12V, KRAS G12C and wild-type KRAS, respectively. KRAS-IN-43 disrupts the interaction between KRAS and cRAF, and inhibits ERK phosphorylation. KRAS-IN-43 is promising for research of KRAS mutation-related cancers (such as pancreatic cancer, colorectal cancer, and lung cancer) .
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 .
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 .
Pan-RAS-IN-6 (compound 24) is an inhibitor targeting DUSP6, which reduces MAPK activation in the brain of the NCI-H1373-Luc model (DUSP6), at the same time, it shows significant tumor growth inhibition and tumor regression effects in the NSCLC brain metastasis mouse model. Pan-RAS-IN-6 shows high selectivity and strong inhibitory effects, especially in KRAS mutation-related signaling pathways, demonstrating varying inhibitory activity against different KRAS mutants and interacting proteins. The IC50 values for KRAS G12C, G12D, and G12V are 1.3 nM, 4.7 nM, and 0.3 nM, respectively .
pan-KRAS-IN-7 (Compound 25) is an inhibitor for in human tumor mutated genes KRAS, which inhibits proliferation of KRAS mutated cells AsPC-1 (G12D mutant) and SW480 (G12V mutant) with IC50 of 0.35 and 0.51 nM, respectively .
pan-KRAS-IN-10 (Compound 58) is an inhibitor for in human tumor mutated genes KRAS, which inhibits proliferation of KRAS mutated cells AsPC-1 (G12D mutant) and SW480 (G12V mutant) with IC50 of 0.7 and 0.24 nM, respectively .
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 .
pan-KRAS-IN-8 (Compound 38) is an inhibitor for in human tumor mutated genes KRAS, which inhibits proliferation of KRAS mutated cells AsPC-1 (G12D mutant) and SW480 (G12V mutant) with IC50 of 0.07 and 0.18 nM, respectively .
pan-KRAS-IN-9 (Compound 52) is an inhibitor for in human tumor mutated genes KRAS, which inhibits proliferation of KRAS mutated cells AsPC-1 (G12D mutant) and SW480 (G12V mutant) with IC50 of 0.24 and 0.30 nM, respectively .
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-51 (Compound 597a) is a KRas G12V inhibitor, with its IC50 for KRas G12V being 2.9 nM; KD values are 17 (at 20°C) and 68 (at 37°C) nM. KRAS-IN-51 inhibits the phosphorylation of pERK. KRAS-IN-51 has anti-proliferative activity against SW620 and MIAPaCa-2. KRAS-IN-51 can be used for research on colorectal cancer and 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 .
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 .
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 .
Rineterkib hydrochloride (compound B) is an orally available ERK1 and ERK2 inhibitor in the treatment of a proliferative disease characterized by activating mutations in the MAPK pathway. The activity is particularly related to the treatment of KRAS-mutant NSCLC, BRAF-mutant NSCLC, KRAS-mutant pancreatic cancer, KRAS-mutant colorectal cancer (CRC) and KRAS-mutant ovarian cancer. Rineterkib hydrochloride can also inhibit RAF .
NPA101.3 is an orally active RET receptor tyrosine kinase and VEGFR2 inhibitor (RET IC50 = 0.001 μM, RET V804MIC50 = 0.008 μM, VEGFR2 IC50 = 0.003 μM). NPA101.3 inhibits purified TRKA (IC50 = 32 nM) and CSF1R (IC50 = 46 nM). NPA101.3 completely suppresses tumor formation in RET/C634Y-transformed cells and also attenuates tumor formation in HRAS/G12V-transformed cells. NPA101.3 can be used in the research of RET-driven cancers .
Rineterkib (compound B) is an orally available ERK1 and ERK2 inhibitor in the treatment of a proliferative disease characterized by activating mutations in the MAPK pathway. The activity is particularly related to the treatment of KRAS-mutant NSCLC, BRAF-mutant NSCLC, KRAS-mutant pancreatic cancer, KRAS-mutant colorectal cancer (CRC) and KRAS-mutant ovarian cancer. Rineterkib hydrochloride can also inhibit RAF .
KRAS G12V Peptide is a specific peptide derived from the Kirsten rat sarcoma virus (KRAS) gene carrying the G12V oncogenic mutation. KRAS G12V Peptide induces responses like IFN-γ secretion and cytotoxicity. KRAS G12V Peptide can be used for the study of immune responses against KRAS G12V-mutant tumors .
KRAS G12V Peptide TFA is the trifluoroacetate salt of KRAS G12V Peptide (HY-P11355). KRAS G12V Peptide is a specific peptide derived from the Kirsten rat sarcoma virus (KRAS) gene carrying the G12V oncogenic mutation. KRAS G12V Peptide induces responses like IFN-γ secretion and cytotoxicity. KRAS G12V Peptide can be used for the study of immune responses against KRAS G12V-mutant tumors .
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 .
The Kras4B protein interacts specifically with GPR31, dependent on farnesylation. This binding suggests a regulatory role for Kras4B in association with GPR31, emphasizing the importance of the farnesylation process. Comprehensive exploration into the molecular details of this interaction is crucial to understand the precise mechanisms and functional implications in cellular processes or signaling pathways. Kras4B Protein, Human (G12V, His) is the recombinant human-derived Kras4B protein, expressed by E. coli , with N-6*His labeled tag.
KRAS protein is a key Ras family member that binds GDP/GTP and has intrinsic GTPase activity. Its critical role in regulating cell proliferation emphasizes its importance in cellular processes. Kras4B Protein, Human (184a.a, G12V, His) is the recombinant human-derived KRAS protein, expressed by E. coli , with N-6*His labeled tag and G12V mutation.
HLA-A*0301 collaborates with B2M to present viral and tumor peptides that direct CD8-positive T cells to respond against infected or transformed cells. It can also present self-peptides to avoid self-reaction. HLA-A*0301 KRAS G12V Complex Protein, Human (HEK293, His-Avi) is a recombinant protein dimer complex containing HLA-A*0301 and B2M/Beta-2-microglobulin Protein, expressed by HEK293 , with C-Avi, C-His labeled tag and VVGAVGVGK peptide. HLA-A*0301 KRAS G12V Complex Protein, Human (HEK293, His-Avi), has molecular weight of 55-60 kDa.
MCB-294 is a dual-state pan-KRAS inhibitor that selectively inhibits KRAS over NRAS and HRAS. MCB-294 capable of binding both the active (GTP-bound) and inactive (GDP-bound) forms of KRAS with Kds of approximately 1 pM and 10 nM, respectively. MCB-294 broadly impairs the growth of hTERT-HPNE cells expressing G12D, G12C, G12V, G12S, G13D, and wild-type KRAS, with IC50s of approximately 700 nM. MCB-294 induces irreversible apoptosis in KRAS-mutated tumors. MCB-294 effectively suppress KRAS G12C inhibitor-resistant cancer cells and remodel the tumor immune microenvironment. MCB-294 can be used for the study of pancreatic cancer, colorectal cancer and lung cancer .
MCB-36 is a VHL-recruiting pan-KRAS PROTAC degrader without affecting KRAS transcription. MCB-36 exhibits minimal effects on HRAS and NRAS protein levels. MCB-36 binds to the GDP-loaded state of G12D, G12C, G12V, and wild-type KRAS with high affinities Kd ≈ 1 pM). MCB-36 decreases p-ERK levels, leading to cell apoptosis. MCB-36 effectively suppress KRAS G12C inhibitor-resistant cancer cells and remodel the tumor immune microenvironment. MCB-36 can be used for the study of colorectal cancer and lung cancer (Pink: Target protein ligand; Blue: E3 ligand (HY-112078); Black: Linker (HY-W091879)) .
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 .
MCB-294 is a dual-state pan-KRAS inhibitor that selectively inhibits KRAS over NRAS and HRAS. MCB-294 capable of binding both the active (GTP-bound) and inactive (GDP-bound) forms of KRAS with Kds of approximately 1 pM and 10 nM, respectively. MCB-294 broadly impairs the growth of hTERT-HPNE cells expressing G12D, G12C, G12V, G12S, G13D, and wild-type KRAS, with IC50s of approximately 700 nM. MCB-294 induces irreversible apoptosis in KRAS-mutated tumors. MCB-294 effectively suppress KRAS G12C inhibitor-resistant cancer cells and remodel the tumor immune microenvironment. MCB-294 can be used for the study of pancreatic cancer, colorectal cancer and lung 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 .
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 .
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
