BackgroundHuman mesenchymal stem cell (MSC)-based tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) gene delivery is regarded as an effective treatment for glioblastoma (GBM). However, adverse-free target site homing of the delivery vehicles to the tumor microsatellite nests is challenging, leading to erroneously sustained released of this suicide protein into the normal brain parenchyma; therefore, limiting off-target cytotoxicity and controlled expression of the suicide inductor is a prerequisite for the safe use of therapeutic stem cells.MethodsUtilizing the intrinsic expression profile of GBM and its elevated expression of TGF- relative to normal brain tissue, we sought to engineer human adipose-derived MSCs (hAMSC-SBE4-TRAIL) which augment the expression of TRAIL under the trigger of TGF- signaling. We validated our therapeutic technology in a series of functional in vitro and in vivo assays using primary patient-derived GBM models.ResultsOur current findings show that these biologic delivery vehicles have high tumor tropism efficacy and expression TRAIL gene under the trigger of TGF--secreting GBMs, as well as avoid unspecific TRAIL secretion into normal brain tissue. hAMSC-SBE4-TRAIL inhibited the proliferation and induced apoptosis in experimental GBMs both in vitro and in vivo. In addition, our improved platform of engineered MSCs significantly decreased the tumor volume and prolonged survival time in a murine model of GBM.ConclusionsOur results on the controlled release of suicide inductor TRAIL by exploiting an endogenous tumor signaling pathway demonstrate a significant improvement for the clinical utility of stem cell-mediated gene delivery to treat brain cancers. Harvesting immune-compatible MSCs from patients' fat by minimally invasive procedures further highlights the clinical potential of this approach in the vision of applicability in a personalized manner. The hAMSC-SBE4-TRAIL exhibit great curative efficacy and are a promising cell-based treatment option for GBM to be validated in clinical exploration.
基金:
National Natural Science Foundation of China [81270865, 81502172]; German Federal Ministry of Education and Research [03VP03791]; Volkswagen Foundation [AZ 95 464]; Brigitte and Dr. Konstanze-Wegener Foundation; FW Hempel Family foundation
语种:
外文
被引次数:
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PubmedID:
中科院(CAS)分区:
出版当年[2018]版:
大类|2 区医学
小类|2 区医学:研究与实验3 区细胞生物学
最新[2025]版:
大类|2 区医学
小类|2 区细胞与组织工程2 区细胞生物学2 区医学:研究与实验
JCR分区:
出版当年[2017]版:
Q1MEDICINE, RESEARCH & EXPERIMENTALQ2CELL BIOLOGY
最新[2023]版:
Q1CELL & TISSUE ENGINEERINGQ1CELL BIOLOGYQ1MEDICINE, RESEARCH & EXPERIMENTAL
第一作者单位:[1]Huazhong Univ Sci & Technol,Tongji Med Coll,Tongji Hosp,Dept Neurol,Wuhan,Hubei,Peoples R China[7]Huazhong Univ Sci & Technol,Tongji Med Coll,Tongji Hosp,Dept Anesthesiol,Wuhan,Hubei,Peoples R China
通讯作者:
推荐引用方式(GB/T 7714):
Li Man,Sun Shoujia,Dangelmajer Sean,et al.Exploiting tumor-intrinsic signals to induce mesenchymal stem cell-mediated suicide gene therapy to fight malignant glioma[J].STEM CELL RESEARCH & THERAPY.2019,10:doi:10.1186/s13287-019-1194-0.
APA:
Li, Man,Sun, Shoujia,Dangelmajer, Sean,Zhang, Quan,Wang, Junwen...&Lei, Ting.(2019).Exploiting tumor-intrinsic signals to induce mesenchymal stem cell-mediated suicide gene therapy to fight malignant glioma.STEM CELL RESEARCH & THERAPY,10,
MLA:
Li, Man,et al."Exploiting tumor-intrinsic signals to induce mesenchymal stem cell-mediated suicide gene therapy to fight malignant glioma".STEM CELL RESEARCH & THERAPY 10.(2019)
医学