Targeting of melanoma brain metastases using engineered neural stem/progenitor cells

Brain metastases are an increasingly frequent and serious clinical problem for cancer patients, especially those with advanced melanoma. Given the extensive tropism of neural stem/progenitor cells (NSPCs) for pathological areas in the central nervous system, we expanded investigations to determine whether NSPCs could also target multiple sites of brain metastases in a syngeneic experimental melanoma model. Using cytosine deaminase-expressing NSPCs (CD-NSPCs) and systemic 5-fluorocytosine (5-FC) pro-drug administration, we explored their potential as a cell-based targeted drug delivery system to disseminated brain metastases. Our results indicate a strong tropism of NSPCs for intracerebral melanoma metastases. Furthermore, in our therapeutic paradigm, animals with established melanoma brain metastasis received intracranial implantation of CD-NSPCs followed by systemic 5-FC treatment, resulting in a significant (71%) reduction in tumor burden. These data provide proof of principle for the use of NSPCs for targeted delivery of therapeutic gene products to melanoma brain metastases.     

Transplantation of prodrug-converting neural progenitor cells for brain tumor therapy

Since neural progenitor cells can engraft stably into brain tumors and differentiate along the neuronal and glial line, we tested the hypothesis that transplanted cytosine deaminase (CD)-expressing ST14A cells (an immortalized neural progenitor cell line) can convert locally 5-fluorocytosine (5-FC) into 5-fluorouracil (5-FU) and produce a regression of glioma tumors. ST14A, retrovirally transduced with the E. coli CD gene, showed a strong bystander effect on glioma cells as assessed by in vitro assay. Intracerebral injection of C6 glioma cells generated a rapidly growing tumoral mass. DiI prelabeled ST14A, coinjected into the rat brain with C6 glioma cells, survived in the tumoral mass up to 10 days and their number was not affected by in vivo 5-FC treatment. In contrast, a significant decrease of the glioma tumoral mass (-50%) was observed in 5-FC-treated rats. 5-FC had no effect on the tumor in the absence of CD-expressing ST14A cells. Our results support the feasibility of systems based on intratumoral transplantation of prodrug-converting cells for brain tumor therapy.     

Primary neural stem/progenitor cells expressing endostatin or cytochrome P450 for gene therapy of glioblastoma

Despite recent technical improvements in surgical excision techniques and adjuvant radio- and chemotherapy, the clinical outcome of patients with grade IV astrocytoma (glioblastoma) remains very poor, with a median survival of less than 12 months. A promising approach to therapy employs gene-engineered neural stem/progenitor cells (NSCs) as a cellular therapeutic delivery system, to track glioblastoma cells and deliver anticancer molecules. However, most results on their tumor tropism have been derived by immortalized NSCs. We now report that primary murine gene-engineered NSCs displayed in vivo tropism for glioblastoma cells. Ten days after injection into the brain, many NSCs continued to express the transgene and the NSC marker, nestin. NSCs transduced with a retroviral vector co-expressing a secretable form of human endostatin and eGFP (NSC/endo-eGFP) released potentially antiangiogenetic concentrations of endostatin into the culture medium. Conditioned medium of NSC/endo-eGFP cells inhibited the growth of mouse pulmonary microvascular endothelial cells (PMVECs). A good correlation between endostatin levels and PMVEC growth inhibition was observed. In NSCs co-expressing cytochrome P450 2B6 (CYP2B6) and eGFP (NSC/CYP2B6-eGFP), the forced expression of CYP2B6 resulted in intracellular activation of CPA and subsequent cell death. In the presence of NSC/CYP2B6-eGFP, we observed CPA cytotoxicity to DsRed-expressing U87Mg glioma cells. In vivo treatment of intracranial GL-261 glioblastoma with NSC/endo-eGFP caused a 65% reduction in tumor size, compared to untreated control mice or mice treated with NSC/eGFP cells. Our data suggest that primary NSCs transduced with retroviral vectors expressing endostatin and/or CYP2B6 have a potential role in glioblastoma therapy.     

Cancer stem cells and brain tumors: uprooting the bad seeds

The cancer stem cell (CSC) hypothesis is predicated on the idea that not all cells have equal proliferative potential and that, in brain tumors, the cells with the greatest ability to proliferate and contribute to tumorigenesis have phenotypic and functional properties similar to normal neural stem cells (NSCs). Over the past few years, multiple investigators have shown that CSCs isolated from human brain tumors (glioma and medulloblastoma) undergo self-renewal and multilineage cell differentiation, similar to normal NSCs. In addition, CSCs from these tumors, when implanted into rodent brains, generate tumors histologically identical to the parental tumors, suggesting that progenitor/stem cells can fully recapitulate the neoplastic phenotype in vivo. While these seminal studies clearly highlight the central role of stem cells in brain tumors, they also evoke important questions regarding the importance of these unique cells to tumor initiation, maintenance and treatment.     

Cancer stem cells and brain tumors: uprooting the bad seeds

The cancer stem cell (CSC) hypothesis is predicated on the idea that not all cells have equal proliferative potential and that, in brain tumors, the cells with the greatest ability to proliferate and contribute to tumorigenesis have phenotypic and functional properties similar to normal neural stem cells (NSCs). Over the past few years, multiple investigators have shown that CSCs isolated from human brain tumors (glioma and medulloblastoma) undergo self-renewal and multilineage cell differentiation, similar to normal NSCs. In addition, CSCs from these tumors, when implanted into rodent brains, generate tumors histologically identical to the parental tumors, suggesting that progenitor/stem cells can fully recapitulate the neoplastic phenotype in vivo. While these seminal studies clearly highlight the central role of stem cells in brain tumors, they also evoke important questions regarding the importance of these unique cells to tumor initiation, maintenance and treatment.     

A 3-dimensional extracellular matrix as a delivery system for the transplantation of glioma-targeting neural stem/progenitor cells

Neural stem/progenitor cells (NSPCs) display inherent pathotropic properties that can be exploited for targeted delivery of therapeutic genes to invasive malignancies in the central nervous system. Optimizing transplantation efficiency will be essential for developing relevant NSPC-based brain tumor therapies. To date, the real-world issue of handling and affixing NSPCs in the context of the neurosurgical resection cavity has not been addressed. Stem cell transplantation using biocompatible devices is a promising approach to counteract poor NSPC graft survival and integration in various types of neurological disorders. Here, we report the development of a 3-dimensional substrate that is based on extracellular matrix purified from tissue-engineered skin cultures (3DECM). 3DECM enables the expansion of embedded NSPCs in vitro while retaining their uncommitted differentiation status. When implanted in intracerebral glioma models, NSPCs were able to migrate out of the 3DECM to targeted glioma growing in the contralateral hemisphere, and this was more efficient than the delivery of NSPC by intracerebral injection of cell suspensions. Direct application of a 3DECM implant into a tumor resection cavity led to a marked NSPC infiltration of recurrent glioma. The semisolid consistency of the 3DECM implants allowed simple handling during the surgical procedure of intracerebral and intracavitary application and ensured continuous contact with the surrounding brain parenchyma. Here, we demonstrate proof-of-concept of a matrix-supported transplantation of tumor-targeting NSPC. The semisolid 3DECM as a delivery system for NSPC has the potential to increase transplantation efficiency by reducing metabolic stress and providing mechanical support, especially when administered to the surgical resection cavity after brain tumor removal.     

Molecular properties of CD133+ glioblastoma stem cells derived from treatment-refractory recurrent brain tumors

Glioblastoma multiforme (GBM) remains refractory to conventional therapy. CD133+ GBM cells have been recently isolated and characterized as chemo-/radio-resistant tumor-initiating cells and are hypothesized to be responsible for post-treatment recurrence. In order to explore the molecular properties of tumorigenic CD133+ GBM cells that resist treatment, we isolated CD133+ GBM cells from tumors that are recurrent and have previously received chemo-/radio-therapy. We found that the purified CD133+ GBM cells sorted from the CD133+ GBM spheres express SOX2 and CD44 and are capable of clonal self-renewal and dividing to produce fast-growing CD133− progeny, which form the major cell population within GBM spheres. Intracranial injection of purified CD133+, not CD133− GBM daughter cells, can lead to the development of YKL-40+ infiltrating tumors that display hypervascularity and pseudopalisading necrosis-like features in mouse brain. The molecular profile of purified CD133+ GBM cells revealed characteristics of neuroectoderm-like cells, expressing both radial glial and neural crest cell developmental genes, and portraying a slow-growing, non-differentiated, polarized/migratory, astrogliogenic, and chondrogenic phenotype. These data suggest that at least a subset of treated and recurrent GBM tumors may be seeded by CD133+ GBM cells with neural and mesenchymal properties. The data also imply that CD133+ GBM cells may be clinically indolent/quiescent prior to undergoing proliferative cell division (PCD) to produce CD133− GBM effector progeny. Identifying intrinsic and extrinsic cues, which promote CD133+ GBM cell self-renewal and PCD to support ongoing tumor regeneration may highlight novel therapeutic strategies to greatly diminish the recurrence rate of GBM. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

人卵巢癌细胞系干/祖细胞分离及其鉴定

目的:自人卵巢癌细胞系SK-OV-3中分离干/祖细胞并进行鉴定。方法:采用无血清球形体形成法从SKOV-3中分离培养卵巢癌干/祖细胞;采用实时定量PCR和蛋折质印迹法测定球形体细胞干/祖细胞相关标志ABCG2、Oct-4、Nanog基因和蛋白的表达;流式细胞仪检测其耐药性;双层软琼脂检测其克隆形成能力;NOD/SCID小鼠检测其体内致瘤性。结果:球形体细胞表达干/祖细胞相关标志Oct-4、ABCG2、Nanog;对顺铂高耐药;在双层软琼脂上克隆形成率达(13.67±1.48)%;1 000个球形体形成细胞就能在NOD/SCID鼠中成瘤。结论:采用无血清培养基中球形体形成法从SKOV-3细胞系中可以分离出具有干/祖特性的卵巢癌细胞,可为今后研究卵巢癌的发生、发展、复发及其化疗药物筛选提供简便实用的体外模型。     

Stromal cell CD9 and the differentiation of hematopoietic stem/progenitor cells

CD9 belongs to the tetraspan family of proteins that facilitates the regulation of cell proliferation, motility, and adhesion. In mouse hematopoietic organs, CD9 is expressed by myeloid and stromal cells. Although the precise mechanisms are not clear, antibody ligation of CD9 on stromal cells regulates the adhesion between stromal cells and hematopoietic stem cells, the production of myeloid cells in long term bone marrow cultures and the differentiation of hematopoietic stem cells. A 100 kD protein co-precipitated with CD9 is distinct from several previously reported CD9-associated molecules with respect to size and distribution. Identification and analysis of this interesting protein may clarify the molecular mechanisms through which CD9 bearing stromal cells control the differentiation of hematopoietic stem cells and/or allow them to maintain their vital self-renewal capacity.     

Glioma-produced extracellular matrix influences brain tumor tropism of human neural stem cells

Summary A major obstacle in the treatment of gliomas is the invasive capacity of the tumor cells. Previous studies have demonstrated the capability of neural stem cells (NSCs) to target these disseminated tumor cells and to serve as therapeutic delivery vehicles. Less is known about the factors involved in brain tumor tropism of NSCs and their interactions within the tumor environment. As gliomas progress and invade, an extensive modulation of the extracellular matrix (ECM) occurs. Tumor-ECM derived from six glioblastoma cell lines, ECM produced by normal human astrocytes and purified ECM compounds known to be upregulated in the glioma environment were analyzed for their effects on NSCs motility in vitro. We found that tumor-produced ECM was highly permissive for NSC migration. Laminin was the most permissive substrate for human NSC migration, and tenascin-C the strongest inducer of a directed human NSC migration (haptotaxis). A positive correlation between the degree of adhesion and migration of NSCs on different ECM compounds exists, as for glioma cells. Our in vitro data suggest that the ECM of malignant gliomas is a modulator of NSC migration. ECM proteins preferentially expressed in areas of glioma cell invasion may provide a permissive environment for NSC tropism to disseminated tumor cells. ^† These authors contributed equally to this work.     

Autocrine/paracrine platelet-derived growth factor regulates proliferation of neural progenitor cells

Growth factors play an important role in regulating neural stem cell proliferation and differentiation. This study shows that platelet-derived growth factor (PDGF) induces a partial differentiation of neural stem/progenitor cells (NSPCs) in the absence of other mitogens in vitro. NSPCs thus acquire an immature morphology and display markers for both neurons and glia. In addition, these cells do not readily mature in the absence of further stimuli. When NSPC cultures treated with PDGF were exposed to additional differentiation factors, however, the differentiation proceeded into neurons, astrocytes, and oligodendrocytes. We find that NSPC cultures are endowed with an endogenous PDGF-BB production. The PDGF-BB expression peaks during early differentiation and is present both in cell lysates and in conditioned medium, allowing for autocrine as well as paracrine signaling. When the NSPC-derived PDGF was inhibited, progenitor cell numbers decreased, showing that PDGF is involved in NSPC expansion. Addition of a PDGF receptor (PDGFR) inhibitor resulted in a more rapid differentiation. Neurons and oligodendrocytes appeared earlier and had more elaborate processes than in control cultures where endogenous PDGFR signaling was not blocked. Our observations point to PDGF as an inducer of partial differentiation of NSPC that also sustains progenitor cell division. Such an intermediate stage in stem cell differentiation is of relevance for the understanding of brain tumor development because autocrine PDGF stimulation is believed to drive malignant conversion of central nervous system progenitor cells.     

Rapamycin induces differentiation of glioma stem/progenitor cells by activating autophagy

Glioma stem/progenitor cells (GSPCs) are considered to be responsible for the initiation, propagation, and recurrence of gliomas. The factors determining their differentiation remain poorly defined. Accumulating evidences indicate that alterations in autophagy may influence cell fate during mammalian development and differentiation. Here, we investigated the role of autophagy in GSPC differentiation. SU-2 cells were treated with rapamycin, 3-methyladenine (3-MA) plus rapamycin, E64d plus rapamycin, or untreated as control. SU-2 cell xenografts in nude mice were treated with rapamycin or 3-MA plus rapamycin, or untreated as control. Western blotting and immunocytochemistry showed up-regulation of microtubule-associated protein light chain-3 (LC3)-II in rapamycin-treated cells. The neurosphere formation rate and the number of cells in each neurosphere were significantly lower in the rapamycin treatment group than in other groups. Real-time PCR and immunocytochemistry showed down-regulation of stem/progenitor cell markers and up-regulation of differentiation markers in rapamycin-treated cells. Transmission electron microscopy revealed autophagy activation in rapamycin-treated tumor cells in mice. Immunohistochemistry revealed decreased Nestin-positive cells and increased GFAP-positive cells in rapamycin-treated tumor sections. These results indicate that rapamycin induces differentiation of GSPCs by activating autophagy.     

Hemangioblastomas might derive from neoplastic transformation of neural stem cells/progenitors in the specific niche

The cytological origin of central nervous system hemangioblastoma (HB) remains unclear and controversial, largely owing to a lack of in-depth characterization of tumorigenic cells and their progeny tracking. We have now detected a cell subpopulation by stage-specific embryonic antigen-1 expression, which were defined as tumor-initiating cells (TICs) in both sporadic and familial HBs. These TICs subpopulations had universal neural stem cell characteristics. Nevertheless, the freshly sorted TICs endowed with potential of multi-progeny derivatives, including HB components and non-HB ingredients, depended on environmental induction in vitro. Importantly, the freshly harvested TICs formed malignant tumors by injection into conventional mice model, while did redevelop the characteristic HB-like structures within a special mice model with HB-microenvironment, indicating HB niche dependency for the TICs derivative specification. Taken together, the data of the present study suggested that HBs might derive from neoplastic transformation of neural stem cells/progenitors in the specific niche.     

肿瘤干细胞介导脑肿瘤化放疗抗拒性研究进展

目的:探讨脑肿瘤干细胞(tumor stem cells,TSCs)研究的最新进展,旨在从中获取有益的治疗信息。方法:外文文献依据PubMed检索系统,中文文献依据维普检索系统,检索年限为2002-2008年,以肿瘤干细胞、化放疗抗拒性和脑肿瘤为关键词;查询文献时使用医学主题词,筛选出肿瘤干细胞介导脑肿瘤化放疗抗拒性研究相关文献107篇,最后纳入文献22篇。结果:TSCs能通过自再生而致脑瘤发生,促进肿瘤进展,并介导化、放疗抗拒性。这意味着未来的肿瘤治疗应该靶向杀灭TSCs,才有可能彻底控制癌症。虽然一些研究支持TGS假设,但仍然有许多不确定因素,诸如理论技术及实验结果阐述等方面存在争议。结论:如果TSCs假设成立,这将对肿瘤分类及治疗产生深远影响。     

Genetically engineered human neural stem cells with rabbit carboxyl esterase can target brain metastasis from breast cancer

Neural stem cells (NSCs) led to the development of a novel strategy for delivering therapeutic genes to tumors. NSCs expressing rabbit carboxyl esterase (F3.CE), which activates CPT-11, significantly inhibited the growth of MDA-MB-435 cells in the presence of CPT-11. F3.CE cells migrated selectively into the brain metastases located in the opposite hemisphere. The treatment also significantly decreased tumor volume in immune-deficient mice bearing MDA-MB-435 tumors when F3.CE cells were transplanted into the contralateral hemisphere. The survival rate was significantly prolonged with the treatment with F3.CE and CPT-11. This strategy may be considered as an effective treatment regimen for brain metastases.     

Primary gene‐engineered neural stem/progenitor cells demonstrate tumor‐selective migration and antitumor effects in glioma

The prognosis of patients with glioblastoma multiforme (GBM) is generally poor after surgical tumor resection. With the aim of developing new adjuvant therapeutic strategies, we have investigated primary neural stem/progenitor cells (NSPC) in co‐cultures with glioma cells, and in a model of gene therapy on aggressively growing malignant glioma. NSPC exhibited tropism towards medium conditioned by glioma cells, and in adherent low‐cell density co‐culture, were attracted to, and fused with, tumor cells. Similarly, within 24–48 hr of co‐culture in suspension, NSPC‐tumor hybrids were observed, representing 2–3% of the total cell population. NSPC were then coinjected into mouse brain with GBM cells, employing NSPC expressing cyclophosphamide (CPA)‐activating enzyme cytochrome p450 2B6 (CYP2B6), which catalyzes CPA prodrug transformation into membrane diffusible DNA‐alkylating metabolites. Upon CPA administration, NSPC containing CYP2B6 elicited substantial impairment of tumor growth. When implanted intracerebrally at a distant site from the tumor, gene‐engineered NSPC specifically targeted GBM grafts, after traveling through brain parenchyma, and hindered tumor growth through local activation of CPA. Directed migration of primary NSPC corresponded closely with intracerebral and tumoral pattern of expression of vascular endothelial growth factor, which is a motility factor for NSPC. Overall, these findings indicate that therapeutic gene delivery mediated by primary NSPC is a potentially valid strategy for treatment of high‐grade gliomas.     

神经干细胞在恶性脑肿瘤基因治疗中的应用现状及前景

神经干细胞 (neuralstemcell,NSC)是具有增殖能力和分化潜能的细胞。神经干细胞的建立和基因修饰技术的完善 ,为基因治疗恶性脑肿瘤提供了可能。目前 ,NSC在恶性脑肿瘤中基因治疗的应用 ,主要包括构建载体和包装病毒载体。综述了这方面的研究进展和前景     

Platelet factor 4 enhances the adhesion of normal and leukemic hematopoietic stem/progenitor cells to endothelial cells

Platelet factor 4 (PF4) is a growth regulator of hematopoietic stem/progenitor cells (HSPCs), but its role in modulating the adhesive property of normal and leukemic cells remains unclear. We used CD34(+) cord blood cells, KG1a cell line, human umbilical vein endothelial cells (HUVECs) and a transformed HUVECs ECV-304 cells to study the effect of PF4 on cell adhesion. When CD34(+) cord blood cells were cultured either in fibronectin-coated (FN) culture plate or over the layer of HUVECs for 2h, a concentration-dependent increase of the number of adhered cells was observed in the culture containing PF4. FACS analysis revealed that the treatment of PF4 resulted in an increased expression of CD49d and CXCR-4 on CD34(+) cells. Moreover, when CD34(+) cells were expanded in the presence of PF4, the adhesive ability to culture plate of CD34(+) cells was significantly increased. To elucidate the mechanism of action of PF4, KG1a cells were incubated with or without PF4 for 2h on pre-established layer of ECV-304 cells. The percentage of CD49d(+) KG1a cells increased about 1.56 +/- 0.4 fold, and that of CD54(+) ECV-304 increased about 1.7 +/- 0.6 fold. Furthermore, the mRNA expression of CD49d and CD54 was upregulated when KG1a or ECV-304 cells were incubated with PF4. The adhesion capacity of KG1a cells was reduced after incubation with the blocking monoclonal antibodies against CD49d and CD54, respectively. Our data demonstrate that PF4 is able to enhance the adhesive ability of normal and leukemia HSPCs.