Therapeutic Potential of Mesenchymal Stem Cells for Cancer Therapy

Hmadcha, Abdelkrim; Martín-Montalvo, Aléjandro; Gauthier, Benoit R.; Soria, Bernat; Capilla-González, Vivian

doi:10.3389/fbioe.2020.00043

Cited by 262 publications

(250 citation statements)

References 135 publications

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“…Currently, the application of unmodified MSC in cancer is not under clinical investigation as MSCs have shown pro-or antitumour property, depending on the donor and types of MSC [64]. Engineering of MSCs with therapeutic genes is necessary as it offers a safer and more efficient cancer therapy as compared to the unstable and heterogenous unmodified cells [15,65,66]. The significant challenge here is then to efficiently deliver the desired therapeutic gene into MSCs so as to generate cells with high payload, high viability and yet with no changes in phenotypes, ideally, without the use of virus.…”

Section: Discussionmentioning

confidence: 99%

“…Owing to their immune-privilege and tumour-nesting properties, mesenchymal stem cells (MSCs) have been explored as cellular vehicles for cell-directed enzyme prodrug therapy (CDEPT) in targeting GBM [11][12][13][14][15]. CDEPT is one of the safer alternatives to conventional chemotherapy as it overcomes dose-limiting toxicities by enabling maximum cytotoxic effect at the vicinity of tumours through the in situ conversion of a non-toxic prodrug into active drug [16,17].…”

Section: Introductionmentioning

confidence: 99%

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A facile and scalable in production non-viral gene engineered mesenchymal stem cells for effective suppression of temozolomide-resistant (TMZR) glioblastoma growth

et al. 2020

Stem Cell Res Ther

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Background Mesenchymal stem cells (MSCs) serve as an attractive vehicle for cell-directed enzyme prodrug therapy (CDEPT) due to their unique tumour-nesting ability. Such approach holds high therapeutic potential for treating solid tumours including glioblastoma multiforme (GBM), a devastating disease with limited effective treatment options. Currently, it is a common practice in research and clinical manufacturing to use viruses to deliver therapeutic genes into MSCs. However, this is limited by the inherent issues of safety, high cost and demanding manufacturing processes. The aim of this study is to identify a facile, scalable in production and highly efficient non-viral method to transiently engineer MSCs for prolonged and exceptionally high expression of a fused transgene: yeast cytosine deaminase::uracil phosphoribosyl-transferase::green fluorescent protein (CD::UPRT::GFP). Methods MSCs were transfected with linear polyethylenimine using a cpg-free plasmid encoding the transgene in the presence of a combination of fusogenic lipids and β tubulin deacetylase inhibitor (Enhancer). Process scalability was evaluated in various planar vessels and microcarrier-based bioreactor. The transfection efficiency was determined with flow cytometry, and the therapeutic efficacy of CD::UPRT::GFP expressing MSCs was evaluated in cocultures with temozolomide (TMZ)-sensitive or TMZ-resistant human glioblastoma cell lines. In the presence of 5-fluorocytosine (5FC), the 5-fluorouracil-mediated cytotoxicity was determined by performing colometric MTS assay. In vivo antitumor effects were examined by local injection into subcutaneous TMZ-resistant tumors implanted in the athymic nude mice. Results At > 90% transfection efficiency, the phenotype, differentiation potential and tumour tropism of MSCs were unaltered. High reproducibility was observed in all scales of transfection. The therapeutically modified MSCs displayed strong cytotoxicity towards both TMZ-sensitive and TMZ-resistant U251-MG and U87-MG cell lines only in the presence of 5FC. The effectiveness of this approach was further validated with other well-characterized and clinically annotated patient-derived GBM cells. Additionally, a long-term suppression (> 30 days) of the growth of a subcutaneous TMZ-resistant U-251MG tumour was demonstrated. Conclusions Collectively, this highly efficient non-viral workflow could potentially enable the scalable translation of therapeutically engineered MSC for the treatment of TMZ-resistant GBM and other applications beyond the scope of this study.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A facile and scalable in production non-viral gene engineered mesenchymal stem cells for effective suppression of temozolomide-resistant (TMZR) glioblastoma growth

et al. 2020

Stem Cell Res Ther

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“…These interesting findings seems very promising for designing novel trials for treating HCC using MSCs as a vector. In accordance with the clinical trials, MSCs have been extensively investigated in treatment of various types of cancer such as ovarian cancer, head and neck cancer and prostate cancer [86][87][88].…”

Section: Therapeutic Application Of Mscs In Liver Cancermentioning

confidence: 99%

Melatonin and Mesenchymal Stem Cells as a Key for Functional Integrity for Liver Cancer Treatment

Elmahallawy

Mohamed

Abdo

et al. 2020

IJMS

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Hepatocellular carcinoma (HCC) is the most common hepatobiliary malignancy with limited therapeutic options. On the other hand, melatonin is an indoleamine that modulates a variety of potential therapeutic effects. In addition to its important role in the regulation of sleep–wake rhythms, several previous studies linked the biologic effects of melatonin to various substantial endocrine, neural, immune and antioxidant functions, among others. Furthermore, the effects of melatonin could be influenced through receptor dependent and receptor independent manner. Among the other numerous physiological and therapeutic effects of melatonin, controlling the survival and differentiation of mesenchymal stem cells (MSCs) has been recently discussed. Given its controversial interaction, several previous reports revealed the therapeutic potential of MSCs in controlling the hepatocellular carcinoma (HCC). Taken together, the intention of the present review is to highlight the effects of melatonin and mesenchymal stem cells as a key for functional integrity for liver cancer treatment. We hope to provide solid piece of information that may be helpful in designing novel drug targets to control HCC.

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“…Likewise, since MSC biologically active materials are transferred to their released EV, the precise framing of EV functions is still challenging. This implies that to move toward MSC-EV based therapies extreme caution should be devoted to clearly define as to boost their anti-cancer properties, while removing their tumour-promoting activity [146]. Due to their ability to trigger specific immune responses, EV released from both SC and tumour cells may also be considered to be a novel tool for EV-mediated anti-cancer-based therapies [147].…”

Section: Resultsmentioning

confidence: 99%

Extracellular Vesicles in the Tumour Microenvironment: Eclectic Supervisors

Cavallari

Camussi

Brizzi

2020

IJMS

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The tumour microenvironment (TME) plays a crucial role in the regulation of cell survival and growth by providing inhibitory or stimulatory signals. Extracellular vesicles (EV) represent one of the most relevant cell-to-cell communication mechanism among cells within the TME. Moreover, EV contribute to the crosstalk among cancerous, immune, endothelial, and stromal cells to establish TME diversity. EV contain proteins, mRNAs and miRNAs, which can be locally delivered in the TME and/or transferred to remote sites to dictate tumour behaviour. EV in the TME impact on cancer cell proliferation, invasion, metastasis, immune-escape, pre-metastatic niche formation and the stimulation of angiogenesis. Moreover, EV can boost or inhibit tumours depending on the TME conditions and their cell of origin. Therefore, to move towards the identification of new targets and the development of a novel generation of EV-based targeting approaches to gain insight into EV mechanism of action in the TME would be of particular relevance. The aim here is to provide an overview of the current knowledge of EV released from different TME cellular components and their role in driving TME diversity. Moreover, recent proposed engineering approaches to targeting cells in the TME via EV are discussed.

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Therapeutic Potential of Mesenchymal Stem Cells for Cancer Therapy

Cited by 262 publications

References 135 publications

A facile and scalable in production non-viral gene engineered mesenchymal stem cells for effective suppression of temozolomide-resistant (TMZR) glioblastoma growth

A facile and scalable in production non-viral gene engineered mesenchymal stem cells for effective suppression of temozolomide-resistant (TMZR) glioblastoma growth

Melatonin and Mesenchymal Stem Cells as a Key for Functional Integrity for Liver Cancer Treatment

Extracellular Vesicles in the Tumour Microenvironment: Eclectic Supervisors

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