Redistribution of GFAP and αB-crystallin after thermal stress in C6 glioma cell line

Tseng, Wei-Chia; Lu, Kuo‐Shyan; Lee, Wen-Ching; Chien, Chung‐Liang

doi:10.1007/s11373-006-9091-9

Cited by 11 publications

(5 citation statements)

References 41 publications

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“…αB-crystallin is well known as a binding partner for type III intermediate filaments, including vimentin [37], desmin [38], and GFAP [39]. Studies in both C6 cells and in primary astrocytes demonstrate that αB-crystallin can influence GFAP integration into the cytoskeletal network, both by regulating normal assembly and by assisting in recovery from stress [37,40]. …”

Section: Discussionmentioning

confidence: 99%

Properties of astrocytes cultured from GFAP over-expressing and GFAP mutant mice

Cho

Messing

2009

Experimental Cell Research

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Summary Alexander disease is a fatal leukoencephalopathy caused by dominantly-acting coding mutations in GFAP. Previous work has also implicated elevations in absolute levels of GFAP as central to the pathogenesis of the disease. However, identification of the critical astrocyte functions that are compromised by mis-expression of GFAP has not yet been possible. To provide new tools for investigating the nature of astrocyte dysfunction in Alexander disease, we have established primary astrocyte cultures from two mouse models of Alexander disease, a transgenic that over-expresses wild type human GFAP, and a knock-in at the endogenous mouse locus that mimics a common Alexander disease mutation. We find that mutant GFAP, as well as excess wild type GFAP, promotes formation of cytoplasmic inclusions, disrupts the cytoskeleton, decreases cell proliferation, increases cell death, reduces proteasomal function, and compromises astrocyte resistance to stress.

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Section: Discussionmentioning

confidence: 99%

Properties of astrocytes cultured from GFAP over-expressing and GFAP mutant mice

Cho

Messing

2009

Experimental Cell Research

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“…Several reports indicated that a-crystallin may interact with different cellular components, like cytoplasmic membrane, cytoskeletal elements, and mediators of cell death (Cobb and Petrash 2000;Kamradt et al 2001;Liu et al 2004;Mao et al 2004;Li et al 2005). As a result of these interactions, a-crystallin maintains the stability of the cellular structures and inhibits the activity of caspases to reduce the stress-induced damage (Nicholl and Quinlan 1994;Wang and Spector 1996;Djabali et al 1997;Tseng et al 2006;Xi et al 2006).…”

Section: )mentioning

confidence: 99%

“…As a result of these interactions, α‐crystallin maintains the stability of the cellular structures and inhibits the activity of caspases to reduce the stress‐induced damage (Nicholl and Quinlan 1994; Wang and Spector 1996; Djabali et al. 1997; Tseng et al. 2006; Xi et al.…”

mentioning

confidence: 99%

Phosphorylation of Ser45 and Ser59 of αB‐crystallin and p38/extracellular regulated kinase activity determine αB‐crystallin‐mediated protection of rat brain astrocytes from C2‐ceramide‐ and staurosporine‐induced cell death

Li¹,

Reiser²

2011

Journal of Neurochemistry

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J. Neurochem. (2011) 118, 354–364. Abstract We previously demonstrated that αB‐crystallin and protease‐activated receptor (PAR) are involved in protection of astrocytes against C2‐ceramide‐ and staurosporine‐induced cell death [Li et al. (2009) J. Neurochem.110, 1433–1444]. Here, we further investigated the mechanism of cytoprotection by αB‐crystallin. Our current data revealed that after down‐regulation of αB‐crystallin by siRNA, cell death caused by C2‐ceramide and staurosporine is increased. Furthermore, we investigated the mechanism of cytoprotection of astrocytes by intracellular αB‐crystallin. Application of specific inhibitors of p38 and extracellular regulated kinase (ERK) abrogates the protection of astrocytes by over‐expression of αB‐crystallin. Thus, p38 and ERK contribute to protective processes by αB‐crystallin. To reveal the molecular mechanism of αB‐crystallin‐mediated cytoprotection, we mimicked phosphorylation or unphosphorylation of αB‐crystallin. In these experiments, we found that the phosphorylation of αB‐crystallin at Ser45 and Ser59 is required for protection. Ser19 phosphorylation of αB‐crystallin does not contribute to protection. Moreover, we detected that PAR‐2 activation increases the phosphorylation level of αB‐crystallin at Ser59, but does not affect the expression level of αB‐crystallin. Thus, endogenous αB‐crystallin has protective capacity employing a mechanism, which involves regulation of the phosphorylation status of αB‐crystallin and p38 and ERK activity. Moreover, we report that PAR‐2 activation evokes the phosphorylation of αB‐crystallin to increase astrocytes survival.

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“…The GFAP gene is first expressed as astrocytes mature and in the adult is strongly up-regulated in response to central nervous system damage. It has been suggested that RFs may represent a metabolite of upregulation of GFAP in response to stress [13,18,23]. The abundant RFs seen in association with our case of CD may represent a dysregulation of α-B-crystallin aggregating in association with GFAP or be secondary to the severity of the CD that produces a dys/up-regulation of GFAP to levels sufficient to induce RFs and localized leukodystrophy, in some cases, due to astrocytic dysfunction [18].…”

Section: Discussionmentioning

confidence: 62%

Cortical dysplasia with prominent Rosenthal fiber formation in a case of intractable pediatric epilepsy

Khanlou

Mathern²,

Mitchell

et al. 2009

Human Pathology

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Redistribution of GFAP and αB-crystallin after thermal stress in C6 glioma cell line

Cited by 11 publications

References 41 publications

Properties of astrocytes cultured from GFAP over-expressing and GFAP mutant mice

Properties of astrocytes cultured from GFAP over-expressing and GFAP mutant mice

Phosphorylation of Ser45 and Ser59 of αB‐crystallin and p38/extracellular regulated kinase activity determine αB‐crystallin‐mediated protection of rat brain astrocytes from C2‐ceramide‐ and staurosporine‐induced cell death

Cortical dysplasia with prominent Rosenthal fiber formation in a case of intractable pediatric epilepsy

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