Dissection of mitogenic and neurodegenerative actions of cystine and glutamate in malignant gliomas

Savaskan, Nicolai Ε.; Seufert, Sebastian; Hauke, Jan; Tränkle, Christian; Eyüpoglu, I Y; Hahnen, Eric

doi:10.1038/onc.2010.391

Cited by 34 publications

(39 citation statements)

References 42 publications

(63 reference statements)

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“…In exchange, cysteine is taken up into tumor cells via the same transporter as antiport34. Further, suppressed transporter expression leads to reduced glutamate export and levels in the extracellular space, and glutamate accumulates intracellular in tumor cells.…”

Section: Resultsmentioning

confidence: 99%

“…Since these target genes are often ubiquitously expressed, the problem naturally lies in the ability to modulate them in a specific manner in cancer cells without disturbing generally the physiological homeostasis. We identified xCT as a target gene playing a decisive role in the progression of malignant gliomas1734. Due to its ubiquitous expression, it falls under the restrictions attendant to target genes and would therefore have limited therapeutic scope.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Histone deacetylases inhibition by SAHA/Vorinostat normalizes the glioma microenvironment via xCT equilibration

Wolf

Fan

Rauh

et al. 2014

Sci Rep

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Malignant gliomas are characterized by neurodegenerative actions leading to the destruction of surrounding brain parenchyma. The disturbance in glutamate homeostasis caused by increased expression of the glutamate transporter xCT plays a key role in glioma progression. We demonstrate that the HDAC-inhibitor SAHA specifically inhibits the xCT-transporter expression. Thereby, tumor cell stress is engendered, marked by increase in ROS. Moreover, SAHA dependent xCT-reduction correlates with the inhibition of ATF4-expression, a factor known to foster xCT expression. Since xCT/system Xc- is pivotal for the brain tumor microenvironment, normalization of this system is a key in the management of malignant gliomas. To date, the problem lay in the inability to specifically target xCT due to the ubiquitous expression of the xCT-transporter—i.e. in non-cancerously transformed cells too—as well as its essential role in physiological CNS processes. Here, we show xCT-transporter equilibration through SAHA is specific for malignant brain tumors whereas SAHA does not affect the physiological xCT levels in healthy brain parenchyma. Our data indicate that SAHA operates on gliomas specifically via normalizing xCT expression which in consequence leads to reduced extracellular glutamate levels. This in turn causes a marked reduction in neuronal cell death and normalized tumor microenvironment.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Histone deacetylases inhibition by SAHA/Vorinostat normalizes the glioma microenvironment via xCT equilibration

Wolf

Fan

Rauh

et al. 2014

Sci Rep

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“…We describe here a bridge technique, i.e. the organotypic glioma invasion model (OGIM), which combines the advantages of in vitro assays with that of the organotypic brain environment as an in vivo situation [98]. The OGIM is a robust in vitro assay enabling the investigation of key events of tumor angiogenesis within the brain.…”

Section: Resultsmentioning

confidence: 99%

“…Moreover a high-density microvessel network is produced via tumor-induction. The organotypic brain slice model represents the tumor microenvironment in vitro in a three-dimensional culture [98], which is biologically more relevant, but technically more challenging than migration, proliferation and cytotoxic assays being an appropriate possibility to test and optimize anti-cancer compounds.…”

Section: The Organotypic Glioma Invasion Model (Ogim)mentioning

confidence: 99%

Brain Tumor–Induced Angiogenesis: Approaches and Bioassays

Hock¹,

Fan²,

Buchfelder³

et al. 2013

Evolution of the Molecular Biology of Brain Tumors and the Therapeutic Implications

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“…10 It should be noted, however, that other studies showed no effect of cell proliferation when glioma cells were treated with AMPA receptor antagonists. 41,47 Despite these contradictory results, it is possible that protection from glutamate transporter overexpression in the peritumoral tissue could be due to decreased tumor AMPA receptor activation in addition to protection against AMPA and NMDA receptor–mediated excitotoxic cell death in noncancerous tissue. This hypothesis is further confirmed by the study described above showing increased survival in patients treated with AMPA receptor antagonist talampanel when combined with radiation therapy and chemotherapy (temozolomide).…”

Section: Discussionmentioning

confidence: 99%

Increased expression of glutamate transporter GLT-1 in peritumoral tissue associated with prolonged survival and decreases in tumor growth in a rat model of experimental malignant glioma

Sattler¹,

Tyler

Hoover³

et al. 2013

JNS

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Object Gliomas are known to release excessive amounts of glutamate, inducing glutamate excitotoxic cell death in the peritumoral region and allowing the tumor to grow and to expand. Glutamate transporter upregulation has been shown to be neuroprotective by removing extracellular glutamate in a number of preclinical animal models of neurodegenerative diseases, including amyotrophic lateral sclerosis and Parkinson disease as well as psychiatric disorders such as depression. The authors therefore hypothesized that the protective mechanism of glutamate transporter upregulation would be useful for the treatment of gliomas as well. Methods In this study 9L gliosarcoma cells were treated with a glutamate transporter upregulating agent, thiamphenicol, an antibiotic approved in Europe, which has been shown previously to increase glutamate transporter expression and has recently been validated in a human Phase I biomarker trial for glutamate transporter upregulation. Cells were monitored in vitro for glutamate transporter levels and cell proliferation. In vivo, rats were injected intracranially with 9L cells and were treated with increasing doses of thiamphenicol. Animals were monitored for survival. In addition, postmortem brain tissue was analyzed for tumor size, glutamate transporter levels, and neuron count. Results Thiamphenicol showed little effects on proliferation of 9L gliosarcoma cells in vitro and did not change glutamate transporter levels in these cells. However, when delivered locally in an experimental glioma model in rats, thiamphenicol dose dependently (10–5000 μM) significantly increased survival up to 7 days and concomitantly decreased tumor size from 46.2 mm2 to 10.2 mm2 when compared with lesions in nontreated controls. Furthermore, immunohistochemical and biochemical analysis of peritumoral tissue confirmed an 84% increase in levels of glutamate transporter protein and a 72% increase in the number of neuronal cells in the tissue adjacent to the tumor. Conclusions These results show that increasing glutamate transporter expression in peritumoral tissue is neuroprotective. It suggests that glutamate transporter upregulation for the treatment of gliomas should be further investigated and potentially be part of a combination therapy with standard chemotherapeutic agents.

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Dissection of mitogenic and neurodegenerative actions of cystine and glutamate in malignant gliomas

Cited by 34 publications

References 42 publications

Histone deacetylases inhibition by SAHA/Vorinostat normalizes the glioma microenvironment via xCT equilibration

Histone deacetylases inhibition by SAHA/Vorinostat normalizes the glioma microenvironment via xCT equilibration

Brain Tumor–Induced Angiogenesis: Approaches and Bioassays

Increased expression of glutamate transporter GLT-1 in peritumoral tissue associated with prolonged survival and decreases in tumor growth in a rat model of experimental malignant glioma

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