Dynamic epigenetic mechanisms including histone and DNA modifications regulate animal behavior and memory. While numerous enzymes regulating these mechanisms have been linked to memory formation, the regulation of active DNA demethylation (i.e. – cytosine-5 demethylation) has only recently been investigated. New discoveries aim towards the Gadd45 family, particularly Gadd45b, in activity-dependent demethylation in the adult CNS. This study found memory-associated expression of gadd45b in the hippocampus and characterized the behavioral phenotype of gadd45b−/− mice. Results indicate normal baseline behaviors and initial learning but enhanced persisting memory in mutants in tasks of motor performance, aversive conditioning and spatial navigation. Furthermore, we showed facilitation of hippocampal long-term potentiation in mutants. These results implicate Gadd45b as a learning-induced gene and a regulator of memory formation and are consistent with its potential role in active DNA demethylation in memory.
Gadd45 proteins, including Gadd45a, Gadd45b and Gadd45g, have been implicated in stress signaling in response to physiological and environmental stress, including oncogenic stress, which can result in cell cycle arrest, DNA repair, cell survival, senescence, and apoptosis. The function of Gadd45 as a stress sensor is mediated via a complex interplay of physical interactions with other cellular proteins implicated in cell cycle regulation and the response of cells to stress, notably PCNA, p21, cdc2/cyclinB1, and the p38 and JNK stress response kinases. Altered expression of Gadd45 has been observed in multiple types of solid tumors as well as in hematopoietic malignancies. Using genetically engineered mouse models and bone-marrow transplantation, evidence has been obtained indicating that Gadd45 proteins can function to either promote or suppress tumor development and leukemia; this is dependent on the molecular nature of the activated oncogene and the cell type, via engagement of different signaling pathways.
The Gadd45 family of proteins is known to play a central role as cellular stress sensors that modulate the response of mammalian cells to stress inflicted by physiologic and environmental stressors. Gadd45a was shown to be a direct target to the p53 and BRCA1 tumor suppressor genes, whose loss of function is known to play a vital role in breast carcinogenesis; however, the role of Gadd45a in the suppression of breast cancer remains unclear. To address this issue, Gadd45a-deficient mice were crossed with breast cancer prone mouse mammary tumor virus-Ras mice to generate mice that express activated Ras and differ in their Gadd45a status. Using this mouse model, we show that the loss of Gadd45a accelerates Ras-driven mammary tumor formation, exhibiting increased growth rates and a more aggressive histologic phenotype. Moreover, it is shown that accelerated Ras-driven tumor formation in the absence of Gadd45a results in both a decrease in apoptosis, which is linked to a decrease in c-Jun NH 2 -terminal kinase (JNK) activation, and a decrease in Ras-induced senescence, which is correlated with a decrease in p38 kinase activation. Altogether, these results provide a novel model for the tumor-suppressive function of Gadd45a in the context of Ras-driven breast carcinogenesis, showing that Gadd45a elicits its function through activation of the stress-induced JNK and p38 kinases, which contribute to increase in apoptosis and Ras-induced senescence. (Cancer Res 2006; 66(17): 8448-54)
Gadd45a (growth arrest and DNA-damage-inducible protein 45 alpha) plays a pivotal role in cellular stress responses and is implicated in DNA repair, cell cycle arrest and apoptosis.1 Recently, it was proposed that GADD45A is a key regulator of active DNA demethylation by way of its role in DNA repair.2 Barreto et al. reported that Gadd45a overexpression activated transcription from methylation-silenced reporter plasmids and promoted global DNA demethylation. siRNA-mediated knockdown of Gadd45a levels resulted in increased levels of DNA methylation at specific endogenous loci. Based on these exciting results, Gadd45a-/- mice might be predicted to have a hypermethylation phenotype. We report here that neither global nor locus-specific methylation is increased in Gadd45a-/- mice.
Gadd45a plays a pivotal role as a stress sensor that modulates cellular responses to various stress stimuli including oncogenic stress. We reported that the stress sensor Gadd45a gene functions as a tumor suppressor in Ras-driven breast tumorigenesis via increasing JNK-mediated apoptosis and p38-mediated senescence. In contrast, here, we show that Gadd45a promotes Myc-driven breast cancer by negatively regulating MMP10 via GSK3 b/b-catenin signaling, resulting in increased tumor vascularization and growth. These novel findings indicate that Gadd45a functions as either tumor promoter or suppressor, is dependent on the oncogenic stress, and is mediated via distinct signaling pathways. Collectively, these novel findings highlight the significance of the type of oncogenic alteration on how stress response genes function during initiation and progression of tumorigenesis. Because Gadd45a is a target for BRCA1 and p53, these findings have implications regarding BRCA1/p53 tumor suppressor functions. Cancer Res; 70(23); 9671-81. Ó2010 AACR.
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