曲美替尼与GSK2126458联合用药逆转结直肠癌SW480细胞的耐药

近年来, 肿瘤靶向药物因其特异性强与对正常细胞损伤小等特点,已成为癌症治疗的热点药物。但由肿瘤异质性导致的靶向药物的耐受现象,成为癌症治疗需要解决的难题之一。为解决单一药物的耐受现象,可以通过药物组合来达到理想的治疗效果。本课题以结直肠癌为研究对象,评估8种结直肠癌细胞对30种靶向药物的敏感性,并筛选可逆转耐药的药物组合,探究药物组合的作用。通过MTT实验测定细胞存活率,计算IC50值进行敏感性分析,敏感标准为IC50值≤100 nmol/L。对敏感的单药进行组合筛选,选取细胞存活率最小的组合。采用流式细胞术和Western印迹检测联合用药对细胞凋亡及MAPK、PI3K通路相关蛋白质表达水平的影响。MTT结果显示,结直肠癌SW480细胞耐受30种肿瘤靶向药物,经联合用药筛选,SW480细胞对曲美替尼与GSK2126458组合最为敏感,与对照组和单药组相比,该组合可使SW480细胞凋亡明显增加。免疫印迹结果显示,ERK、Akt和mTOR磷酸化水平降低,Cleaved PARP表达增加。上述结果表明,8种结直肠癌细胞存在不同程度耐受靶向抑制剂的现象,曲美替尼与GSK2126458联合应用可逆转结直肠癌SW480细胞的耐药现象。     

MEK inhibitor GSK1120212-mediated radiosensitization of pancreatic cancer cells involves inhibition of DNA double-strand break repair pathways

Purpose: Over 90% of pancreatic adenocarcinoma PC express oncogenic mutant KRAS that constitutively activates the Raf-MEK-MAPK pathway conferring resistance to both radiation and chemotherapy. MEK inhibitors have shown promising anti-tumor responses in recent preclinical and clinical studies, and are currently being tested in combination with radiation in clinical trials. Here, we have evaluated the radiosensitizing potential of a novel MEK1/2 inhibitor GSK1120212 (GSK212,or trametinib) and evaluated whether MEK1/2 inhibition alters DNA repair mechanisms in multiple PC cell lines.Methods: Radiosensitization and DNA double-strand break (DSB) repair were evaluated by clonogenic assays, comet assay, nuclear foci formation (γH2AX, DNA-PK, 53BP1, BRCA1, and RAD51), and by functional GFP-reporter assays for homologous recombination (HR) and non-homologous end-joining (NHEJ). Expression and activation of DNA repair proteins were measured by immunoblotting.Results: GSK212 blocked ERK1/2 activity and radiosensitized multiple KRAS mutant PC cell lines. Prolonged pre-treatment with GSK212 for 24-48 hours was required to observe significant radiosensitization. GSK212 treatment resulted in delayed resolution of DNA damage by comet assays and persistent γH2AX nuclear foci. GSK212 treatment also resulted in altered BRCA1, RAD51, DNA-PK, and 53BP1 nuclear foci appearance and resolution after radiation. Using functional reporters, GSK212 caused repression of both HR and NHEJ repair activity. Moreover, GSK212 suppressed the expression and activation of a number of DSB repair pathway intermediates including BRCA1, DNA-PK, RAD51, RRM2, and Chk-1.Conclusion: GSK212 confers radiosensitization to KRAS-driven PC cells by suppressing major DNA-DSB repair pathways. These data provide support for the combination of MEK1/2 inhibition and radiation in the treatment of PC.     

Mitogen‐activated protein kinase dependency in BRAF/RAS wild‐type melanoma: A rationale for combination inhibitors

Inhibitors targeting the mitogen‐activated protein kinase (MAPK) pathway and immune checkpoint molecules have dramatically improved the survival of patients with BRAF^V600‐mutant melanoma. For BRAF/RAS wild‐type (WT) melanoma patients, however, immune checkpoint inhibitors remain the only effective therapeutic option with 40% of patients responding to PD‐1 inhibition. In the present study, a large panel of 10 BRAF^V600‐mutant and 13 BRAF/RAS WT melanoma cell lines was analyzed to examine MAPK dependency and explore the potential utility of MAPK inhibitors in this melanoma subtype. We now show that the majority of BRAF/RAS WT melanoma cell lines (8/13) display some degree of sensitivity to trametinib treatment and resistance to trametinib in this melanoma subtype is associated with, but not mediated by NF1 suppression. Although knockdown of NF1 stimulates RAS and CRAF activity, the activation of CRAF by NF1 knockdown is limited by ERK‐dependent feedback in BRAF‐mutant cells, but not in BRAF/RAS WT melanoma cells. Thus, NF1 is not a dominant regulator of MAPK signaling in BRAF/RAS WT melanoma, and co‐targeting multiple MAP kinase nodes provides a therapeutic opportunity for this melanoma subtype.     

Vertical inhibition of the MAPK pathway enhances therapeutic responses in NRAS‐mutant melanoma

The MEK inhibitor MEK162 is the first targeted therapy agent with clinical activity in patients whose melanomas harbor NRAS mutations; however, median PFS is 3.7 months, suggesting the rapid onset of resistance in the majority of patients. Here, we show that treatment of NRAS‐mutant melanoma cell lines with the MEK inhibitors AZD6244 or trametinib resulted in a rebound activation of phospho‐ERK (pERK). Functionally, the recovery of signaling was associated with the maintenance of cyclin‐D1 expression and therapeutic escape. The combination of a MEK inhibitor with an ERK inhibitor suppressed the recovery of cyclin‐D1 expression and was associated with a significant enhancement of apoptosis and the abrogation of clonal outgrowth. The MEK/ERK combination strategy induced greater levels of apoptosis compared with dual MEK/CDK4 or MEK/PI3K inhibition across a panel of cell lines. These data provide the rationale for further investigation of vertically co‐targeting the MAPK pathway as a potential treatment option for NRAS‐mutant melanoma patients.     

BRAF internal deletions and resistance to BRAF/MEK inhibitor therapy

BRAF and MEK inhibitors have improved clinical outcomes in advanced, BRAF^V600‐mutated melanomas. Acquired resistance occurs in most patients, with numerous and diverse drivers. We obtained pretreatment and progression biopsies from a patient who progressed on dabrafenib and trametinib. In addition to a preserved BRAF^V600E mutation, an internal deletion (rearrangement) of BRAF was observed in the progression sample. This deletion involved exons 2–8, which includes the Ras‐binding domain, and is analogous to previously documented BRAF fusions and splice variants known to reactivate RAS‐RAF‐MEK‐ERK signaling. In a large cohort of melanomas, 10 additional internal deletions were identified (0.4% of all melanomas; nine of which had concurrent BRAF mutations), as well as sporadically in other tumor types. Thus, we describe a novel mechanism of resistance to BRAF and MEK inhibition.     

曲美替尼与GSK2126458联合用药逆转结直肠癌SW480细胞的耐药

近年来, 肿瘤靶向药物因其特异性强与对正常细胞损伤小等特点,已成为癌症治疗的热点药物。但由肿瘤异质性导致的靶向药物的耐受现象,成为癌症治疗需要解决的难题之一。为解决单一药物的耐受现象,可以通过药物组合来达到理想的治疗效果。本课题以结直肠癌为研究对象,评估8种结直肠癌细胞对30种靶向药物的敏感性,并筛选可逆转耐药的药物组合,探究药物组合的作用。通过MTT实验测定细胞存活率,计算IC50值进行敏感性分析,敏感标准为IC50值≤100 nmol/L。对敏感的单药进行组合筛选,选取细胞存活率最小的组合。采用流式细胞术和Western印迹检测联合用药对细胞凋亡及MAPK、PI3K通路相关蛋白质表达水平的影响。MTT结果显示,结直肠癌SW480细胞耐受30种肿瘤靶向药物,经联合用药筛选,SW480细胞对曲美替尼与GSK2126458组合最为敏感,与对照组和单药组相比,该组合可使SW480细胞凋亡明显增加。免疫印迹结果显示,ERK、Akt和mTOR磷酸化水平降低,Cleaved PARP表达增加。上述结果表明,8种结直肠癌细胞存在不同程度耐受靶向抑制剂的现象,曲美替尼与GSK2126458联合应用可逆转结直肠癌SW480细胞的耐药现象。     

Synergistic targeted inhibition of MEK and dual PI3K/mTOR diminishes viability and inhibits tumor growth of canine melanoma underscoring its utility as a preclinical model for human mucosal melanoma

Human mucosal melanoma (MM), an uncommon, aggressive and diverse subtype, shares characteristics with spontaneous MM in dogs. Although BRAF and N‐RAS mutations are uncommon in MM in both species, the majority of human and canine MM evaluated exhibited RAS/ERK and/or PI3K/mTOR signaling pathway activation. Canine MM cell lines, with varying ERK and AKT/mTOR activation levels reflective of naturally occurring differences in dogs, were sensitive to the MEK inhibitor GSK1120212 and dual PI3K/mTOR inhibitor NVP‐BEZ235. The two‐drug combination synergistically decreased cell survival in association with caspase 3/7 activation, as well as altered expression of cell cycle regulatory proteins and Bcl‐2 family proteins. In combination, the two drugs targeted their respective signaling pathways, potentiating reduction of pathway mediators p‐ERK, p‐AKT, p‐S6, and 4E‐BP1 in vitro, and in association with significantly inhibited solid tumor growth in MM xenografts in mice. These findings provide evidence of synergistic therapeutic efficacy when simultaneously targeting multiple mediators in melanoma with Ras/ERK and PI3K/mTOR pathway activation.     

Pharmacokinetics of dabrafenib in a patient with metastatic melanoma undergoing haemodialysis

The combination of dabrafenib and trametinib is a standard of care for the management of BRAF mutant metastatic melanoma. Clinical trials excluded patients with end‐stage kidney disease (ESKD), and as such, no data are available regarding the safety, efficacy and pharmacokinetics of these drugs in such patients. Here, we present the case of a 78‐yr‐old male patient with ESKD managed with haemodialysis (HD), treated with dabrafenib and trametinib at reduced doses. The patient has had a partial response, and this response continues at 9 months since our last follow‐up without any dose escalation. Treatment was complicated by the development of diarrhoea, attributed to trametinib, necessitating temporary cessation of trametinib. Pharmacokinetic profiling of dabrafenib was undertaken, and its metabolites were similar pre‐ and post‐dialysis and comparable to those in patients with normal renal function. Moreover, HD did not lower the plasma concentration of dabrafenib or trametinib. It is feasible to administer dabrafenib, in combination with trametinib, to patients with ESKD undergoing HD.     

Dual MEK/AKT inhibition with trametinib and GSK2141795 does not yield clinical benefit in metastatic NRAS‐mutant and wild‐type melanoma

Aberrant MAPK and PI3K pathway signaling may drive the malignant phenotype in NRAS‐mutant and BRAF^WT NRAS^WT metastatic melanoma. To target these pathways, NRAS‐mutant and BRAF^WT NRAS^WT patients received oral trametinib at 1.5 mg daily and GSK2141795 at 50 mg daily in a two‐cohort Simon two‐stage design. Participants had adequate end‐organ function and no more than two prior treatment regimens. Imaging assessments were performed at 8‐week intervals. A total of 10 NRAS‐mutant and 10 BRAF^WT NRAS^WT patients were enrolled. No objective responses were noted in either cohort. The median PFS and OS were 2.3 and 4.0 months in the NRAS‐mutant cohort and 2.8 and 3.5 months in the wild‐type cohort. Grade 3 and grade 4 adverse events, primarily rash, were observed in 25% of patients. We conclude that the combination of trametinib and GSK2141795 does not have significant clinical activity in NRAS‐mutant or BRAF^WT NRAS^WT melanoma.     

Targeting KRAS-mutant stomach/colorectal tumors by disrupting the ERK2-p53 complex

1. Download : Download high-res image (105KB)
2. Download : Download full-size image