Ming-Tsang Chiao

Suberoylanilide hydroxamic acid (SAHA) causes tumor growth slowdown and triggers autophagy in glioblastoma stem cells

Although suberoylanilide hydroxamic acid (SAHA), a histone deacetylase inhibitor, has been used in clinical trials for cancer therapies, its pharmacological effects occur through a poorly understood mechanism. Here, we report that SAHA specifically triggers autophagy and reduces cell viability via promotion of apoptosis in the late phase of glioblastoma stem cells (GSCs). Using a cell line cultured from a glioblastoma biopsy, we investigated the properties and effects of GSCs under SAHA treatment in vitro. In vivo xenograft assays revealed that SAHA effectively caused tumor growth slowdown and the induction of autophagy. SAHA was sufficient to increase formation of intracellular acidic vesicle organelles, recruitment of LC3-II to the autophagosomes, potentiation of BECN1 protein levels and reduced SQSTM1 levels. We determined that SAHA triggered autophagy through the downregulation of AKT-MTOR signaling, a major suppressive cascade of autophagy. Interestingly, upon depletion or pharmacological inhibition of autophagy, SAHA facilitates apoptosis and results in cell death at the early phase, suggesting that SAHA-induced autophagy functions probably act as a prosurvival mechanism. Furthermore, our results also indicated that the inhibition of SAHA-induced autophagy using chloroquine has synergistic effects that further increase apoptosis. Moreover, we found that a reduced dose of SAHA functioned as a potent modulator of differentiation and senescence. Taken together, our results provide a new perspective on the treatment of GSCs, indicating that SAHA is a promising agent for targeting GSCs through the induction of autophagy.

Transplantation of Adipose Tissue-Derived Stem Cells for Treatment of Focal Cerebral Ischemia

The neurological functional disabilities caused by cerebral infarction significantly deteriorate life quality and increase the medical and socio-economic costs. Although some molecular agents show potential in acting against the pathological mechanisms in animal studies, none has been proven effective for cerebral ischemia treatment in human patients. New treatment strategy needs to be developed. Stem cell therapy is promising for neural regeneration and thus become one of the current trends. More evidence has shown stem cells, such as embryonic stem cells (ESCs), skeletal muscle satellite cells and mesenchymal stem cells, to be useful in tissue repair and regeneration. However all these stem cells mentioned above have limitations. Adipose tissue-derived stem cells (ADSCs) are an alternative autologous stem cell source for the characters as abundant, easy to obtain, immunological and ethic problem free. So far, this treatment strategy has been rarely adopted on ischemic brain injury. In this study, we investigated the transplantation effects of rat ADSCs for the treatment of cerebral ischemia in rats. ADSCs were isolated from rat adipose tissue and then induced to initiate neural differentiation. Following neural induction, ADSCs developed neural morphology and displayed molecular expression of Nestin, MAP2 and GFAP. We evaluate the neurobehavioral function, infarct volume and cell properties as apoptosis, survival, migration, proliferation, differentiation and immunogenicity. Treatment with i-ADSCs (induction from ADSCs) results in better functional recovery and more reduction in hemispheric atrophy then without i-ADSCs in other groups. Our study demonstrates that i-ADSCs therapy is promising in stroke treatment and finally leads to an efficacious therapeutic modalities for much better outcome in clinical patients.

CD133+ Glioblastoma Stem-Like Cells Induce Vascular Mimicry in Vivo

Glioblastoma is one of the most angiogenic malignancy, the neoplastic vessels of which are likely to arise by angiogenesis and vasculogenesis. An alternative mechanism of tumor vasculature is described, termed vasculogenic mimicry, by which highly aggressive tumor cells can form vessel-like structures themselves, by virtue of their high cellular plasticity. Evidence suggests that cancer stem cells acquire a multi-potent plastic phenotype and show vasculogenic potential. In this study, we report that glioblastoma stem-like cells (GSCs) can form vasculogenic mimicry in tumor xenografts and express pro-vascular molecules. We isolated GSCs from resected human glioblastoma tissues and demonstrated their stemness, differentiation, and in vivo tumor-initiating potential. Through a limiting dilution assay, CD133+ (CD133(+)-GSC) and CD133- (CD133(-)-GSC) subpopulation of GSCs were obtained. Orthotopic xenotransplantation study revealed that these two subpopulations of GSCs shared similar efficacy in tumor formation but showed distinct intratumor vasculature. In comparison with CD133(-)-GSC, a highly vascularized anaplastic tumor, mimicking vasculogenic mimicry, was found in CD133(+)-GSC-derived tumor xenografts. Subsets of CD133(+)-GSC but not CD133(-)-GSC were capable of vascular smooth muscle-like cell differentiation, in vitro and in vivo. In tumor xenografts, endothelium-associated CD31 gene was detected in implanted CD133(-)-GSC and exclusively dispersed within the tumor tissues. Although the detailed action mechanisms required further investigation, this study demonstrated the vasculogenic capacity of brain GSCs and their cellular plasticity. The results of expression of pro-vascular molecules and differentiation of vascular-like cells suggest that GSCs may contribute to form vessel-like structures and provide a blood supply for glioblastoma cells.

Intravenous Implanted Neural Stem Cells Migrate to Injury Site, Reduce Infarct Volume, and Improve Behavior after Cerebral Ischemia

Stroke represents one of the leading causes of death and disability in humans, but despite intense research, only a few options exist for the treatment of stroke-related infarction of brain tissue. Thus far, in experimental strokes, cell therapy appears to partly reverse some behavioral deficits. However, the mechanisms of action remain uncertain as most studies reveal only little, if any, evidence for neuronal replacement and observed behavioral improvements. This present study was performed to test rodent fetus forebrain derived neural stem cells (NSCs) implantation into rats subjected to suture-induced middle cerebral artery occlusion (MCAO). Efficacy of cell therapy was studied regarding behavior recovery, infarct volume, and protection possibility of related molecular mechanisms. Here, we show that grafted cells can home in on damaged regions by MCAO and significantly improve behavior of ischemic rats. Infarct volumes and brain atrophy were diminished after grafted NSCs treatment. Furthermore, we detected inflammation related molecules such as COX-2 and IL-1beta and found that grafted NSCs treatment after ischemic stroke could repress expression of inflammation molecular protein levels. We also detected protein levels of heat shock protein 27 (HSP27) as a protective protein against apoptosis. The results showed that grafted NSCs treatment induced the protein level of HSP27 and down-regulated activity of caspase-3 compared with the vehicle control. Our results demonstrate that transplanted NSCs provide benefits in behavioral function recovery after MCAO and increase neuroprotection whilst repressing inflammatory destruction. These data reveal another essential explanation of cellular transplantation therapy in damage recovery from ischemic stroke and offer new therapeutic possibilities.

Characterization of Endogenous Neural Progenitor Cells after Experimental Ischemic Stroke

Neural progenitors cells are capable of promoting neurogenesis after ischemic stroke in the adult mammalian brain; however the function of these cells and their fate is still not clear. Therefore the purpose of this study investigated the relationship between neural progenitors and reactive astrocytes after middle cerebral artery occlusion (MCAO). Brain infarction was induced by occlusion of a right cerebral artery in male Wistar rats. The fate of progenitor cells and the surrounding cells was investigated by immunochemical staining for nestin, vimentin and glial fibrillary acidic protein (GFAP) positive cells at several locations. Vimentin and nestin positive cells were observed in the ipsilateral subventricular zone (SVZ), striatum, and cortex at 3 and 7 days after MCAO, but those cells were not found at 28 days after ischemia. In contrast, reactive astrocyte positive cells increased following MCAO. These reactive astrocytes induced astrocytes differentiation of progenitor cells and formed dense astroglioses surrounding the ischemic lesion. Reactive astrocytes are thought to protect the penumbra during brain ischemia. We examined which brain cell expressed nestin and GFAP in the ipsilateral co-expression at 7 days after MCAO, especially at the core of injury. These results suggest that robust reactive astrocytes after MCAO were possibly differentiation from the induced nestin-positive cells after early ischemia.

Low-level laser stimulation on adipose-tissue-derived stem cell treatments for focal cerebral ischemia in rats.

This study investigated the effects of large-area irradiation from a low-level laser on the proliferation and differentiation of i-ADSCs in neuronal cells. MTT assays indicated no significant difference between the amount of cells with (LS+) and without (LS−) laser treatment (P > 0.05). However, immunofluorescent staining and western blot analysis results indicated a significant increase in the neural stem-cell marker, nestin, following exposure to low-level laser irradiation (P < 0.05). Furthermore, stem cell implantation was applied to treat rats suffering from stroke. At 28 days posttreatment, the motor functions of the rats treated using i-ADSCs (LS+) did not differ greatly from those in the sham group and HE-stained brain tissue samples exhibited near-complete recovery with nearly no brain tissue damage. However, the motor functions of the rats treated using i-ADSCs (LS−) remained somewhat dysfunctional and tissue displayed necrotic scarring and voids. The western blot analysis also revealed significant expression of oligo-2 in the rats treated using i-ADSCs (LS+) as well as in the sham group (P < 0.05). The results demonstrated that low-level laser irradiation exerts a positive effect on the differentiation of i-ADSCs and can be employed to treat rats suffering from ischemic stroke to regain motor functions.

An innovative three‐dimensional gelatin foam culture system for improved study of glioblastoma stem cell behavior

Three-dimensional (3-D) tissue engineered constructs provide a platform for examining how the local extracellular matrix contributes to the malignancy of various cancers, including human glioblastoma multiforme. Here, we describe a simple and innovative 3-D culture environment and assess its potential for use with glioblastoma stem cells (GSCs) to examine the diversification inside the cell mass in the 3-D culture system. The dissociated human GSCs were cultured using gelatin foam. These cells were subsequently identified by immunohistochemical staining, reverse transcriptase-polymerase chain reaction, and Western blot assay. We demonstrate that the gelatin foam provides a suitable microenvironment, as a 3-D culture system, for GSCs to maintain their stemness. The gelatin foam culture system contributes a simplified assessment of cell blocks for immunohistochemistry assay. We show that the significant transcription activity of hypoxia and the protein expression of inflammatory responses are detected at the inside of the cell mass in vitro, while robust expression of PROM1/CD133 and hypoxia-induced factor-1 alpha are detected at the xenografted tumor in vivo. We also examine the common clinical trials under this culture platform and characterized a significant difference of drug resistance. The 3-D gelatin foam culture system can provide a more realistic microenvironment through which to study the in vivo behavior of GSCs to evaluate the role that biophysical factors play in the hypoxia, inflammatory responses and subsequent drug resistance.

Corrigendum to “Low-Level Laser Stimulation on Adipose-Tissue-Derived Stem Cell Treatments for Focal Cerebral Ischemia in Rats”

[This corrects the article DOI: 10.1155/2013/594906.].

High expression of a novel splicing variant of VEGF, L-VEGF144 in glioblastoma multiforme is associated with a poorer prognosis in bevacizumab treatment

IntroductionA previous study confirmed that a novel splicing variant of large vascular endothelial growth factor (L-VEGF) termed L-VEGF144, a nucleolus protein, is found in glioblastoma cells and specimens, but the actual biological function and clinical significance of L-VEGF144 remain unclear.MethodsIn this study, we analyzed the expression of L-VEGF144 in 68 glioblastoma multiforme specimens using reverse transcriptase-polymerase chain reaction analysis.ResultsThe results showed that the high expression of L-VEGF144 was associated with a poor prognosis in the bevacizumab plus concurrent chemoradiotherapy with temozolomide treatment. In addition, we constructed a series truncated and mutant form of L-VEGF144 to confirm that exon 6a of L-VEGF144 is able to engage in the nuclear importation and found that 8 lysines within exon 6a play a critical role in the nucleolus aggregation of L-VEGF144. Also, the transfection of the L-VEGF144 increased the number of nucleoli. Furthermore, the recombinant protein Flag-L-VEGF144 and commercial VEGF protein have similar growth stimulatory activities in terms of inducing glioblastoma cell proliferation in vitro.ConclusionsTaken together, these results indicated that the expression of L-VEGF144 could potentially serve as an independent indicator of poor prognosis in bevacizumab treatment.