DNA-damage inducible genes

Gadd45a inhibits cell migration and invasion by altering the global RNA expression

Gadd45a, the first well-defined p53 downstream gene, can be induced by multiple DNA-damaging agents, which plays important roles in the control of cell cycle checkpoint, DNA repair process and signaling transduction. Our previous findings suggested that Gadd45a maintains cell-cell adhesion and cell contact inhibition. However, little is known about how Gadd45a participates in the suppression of malignancy in human cancer cells. To examine the functions of Gadd45a in cell invasion and metastasis, we performed the adhesion, wound-healing and transwell assays in Gadd45a (+/+) and Gadd45a (-/-) MEF cell lines. We found the adhesion, migration and invasive abilities were much higher in Gadd45a deficient cells. We furthermore applied high-throughput cDNA microarray analysis and bioinformatics analysis to analyze the mechanisms of Gadd45a gene in invasion and metastasis. Compared with the Gadd45a wild type cells, the Gadd45a deficient cells showed a wide range of transcripts alterations. The altered gene pathways were predicted by the MAS software, which indicated focal adhesion,cell communication,ECM-receptor interaction as the three main pathways. Real-time PCR was employed to validate the differentially expressed genes. Interestingly, we figured out that the deregulations of these genes are caused neither by genomic aberrations nor methylation status. These findings provided a novel insight that Gadd45a may involve in tumor progression by regulating related genes expressions.

GADD45A protects against cell death in dorsal root ganglion neurons following peripheral nerve injury

A significant loss of neurons in the dorsal root ganglia (DRG) has been reported in animal models of peripheral nerve injury. Neonatal sensory neurons are more susceptible than adult neurons to axotomy- or nerve growth factor (NGF) withdrawal-induced cell death. To develop therapies for preventing irreversible sensory cell loss, it is essential to understand the molecular mechanisms responsible for DRG cell death and survival. Here we describe how the expression of the growth arrest- and DNA damage-inducible gene 45α (GADD45A) is correlated with neuronal survival after axotomy in vivo and after NGF withdrawal in vitro. GADD45A expression is low at birth and does not change significantly after spinal nerve ligation (SNL). In contrast, GADD45A is robustly up-regulated in the adult rat DRG 24 hr after SNL, and this up-regulation persists as long as the injured fibers are prevented from regenerating. In vitro delivery of GADD45A protects neonatal rat DRG neurons from NGF withdrawal-induced cytochrome c release and cell death. In addition, in vivo knockdown of GADD45A expression in adult injured DRG by small hairpin RNA increased cell death. Our results indicate that GADD45A protects neuronal cells from SNL-induced cell death.

Gadd45a, a p53- and BRCA1-regulated stress protein, in cellular response to DNA damage

Mammalian cells exhibit complex, but intricate cellular responses to genotoxic stress, including cell cycle checkpoints, DNA repair and apoptosis. Inactivation of these important biological events may result in genomic instability and cell transformation, as well as alterations of therapeutic sensitivity. Gadd45a, a p53- and BRCA1-regulated stress-inducible gene, has been characterized as one of the important players that participate in cellular response to a variety of DNA damage agents. Interestingly, the signaling machinery that regulates Gadd45a induction by genotoxic stress involves both p53-dependent and -independent pathways; the later may employ BRCA1-related or MAP kinase-mediated signals. Gadd45a protein has been reported to interact with multiple important cellular proteins, including Cdc2 protein kinase, proliferating cell nuclear antigen (PCNA), p21Waf1/Cip1 protein, core histone protein and MTK/MEKK4, an up-stream activator of the JNK/SAPK pathway, indicating that Gadd45a may play important roles in the control of cell cycle checkpoint, DNA repair process, and signaling transduction. The importance of Gadd45a in maintaining genomic integrity is well manifested by the demonstration that disruption of endogenous Gadd45a in mice results in genomic instability and increased carcinogenesis. Therefore, Gadd45a appears to be an important component in the cellular defense network that is required for maintenance of genomic stability.

Molecular mechanism of endothelial growth arrest by laminar shear stress

This study was designed to elucidate the mechanism underlying the inhibition of endothelial cell growth by laminar shear stress. Tumor suppressor gene p53 was increased in bovine aortic endothelial cells subjected to 24 h of laminar shear stress at 3 dynes (1 dyne = 10 microN)/cm(2) or higher, but not at 1.5 dynes/cm(2). One of the mechanisms of the shear-induced increase in p53 is its stabilization after phosphorylation by c-Jun N-terminal kinase. To investigate the consequence of the shear-induced p53 response, we found that prolonged laminar shear stress caused increases of the growth arrest proteins GADD45 (growth arrest and DNA damage inducible protein 45) and p21(cip1), as well as a decrease in phosphorylation of the retinoblastoma gene product. Our results suggest that prolonged laminar shear stress causes a sustained p53 activation, which induces the up-regulation of GADD45 and p21(cip1). The resulting inhibition of cyclin-dependent kinase and hypophosphorylation of retinoblastoma protein lead to endothelial cell cycle arrest. This inhibition of endothelial cell proliferation by laminar shear stress may serve an important homeostatic function by preventing atherogenesis in the straight part of the arterial tree that is constantly subjected to high levels of laminar shearing.

Down-regulation of mammalian mitochondrial RNAs during oxidative stress

We have identified an RNA species that appears to be induced by oxidative stress in hamster HA-1 fibroblasts using the differential display technique, but instead is found to be degraded when evaluated by Northern blot hybridization. Cloning and subsequent sequencing identified the partially degraded RNA as 16S ribosomal RNA (rRNA), a major component of mitochondrial ribosomes. Degradation, and associated decreases in the levels of the mature- and precursor-species of 16S rRNA, appear to be dependent upon calcium, but not cytoplasmic protein synthesis nor nuclear transcription. Other decreased mitochondrial RNAs were also identified, including 12S rRNA, NADH dehydrogenase subunit 6, ATPase subunit 6, and cytochrome oxidase subunits I and III. A significant part of many, if not all, of these RNA decreases was due to degradation. As compared with 16S rRNA, significantly less degradation was observed for cytoplasmic 28S/18S rRNAs, even at very high peroxide concentration. Analysis of 21 cytoplasmic mRNAs revealed little or no decrease in mature band signal in response to peroxide, and several cytoplasmic mRNAs were actually up-regulated. Thus, a preferential down-regulation of mitochondrial RNAs occurs in HA-1 fibroblasts in response to hydrogen peroxide. Subcellular fractionation analysis, using 16S rRNA degradation as a gauge, indicates that this down-regulation is specific to mitochondria. The down-regulation of mitochondrial RNAs may represent a general mechanism by which cells protect themselves against oxidative stress.

Influence of DNA repair capacity and cell differentiation on UV-induced gene expression

Terminally differentiated (TD) 3T3-T cells have a reduced capacity to repair ultraviolet (UV)-induced DNA damage, as compared with the repair capabilities of growth-arrested and cycling (stem) 3T3-T cells. In this study UV-induced expression of the immediate early response genes c-fos and c-jun and the secondary response gene type IV collagenase in TD, growth-arrested and stem 3T3-T cells was investigated by northern blot analysis. At each UV dose (0-10 J/m2) there was an increase in c-fos and, to a lesser extent, c-jun expression 0.5 h after irradiation in each 3T3-T phenotype as compared with unirradiated controls. Maximum induction of c-fos was reached at 0.5-1 J/m2 in TD and growth-arrested cells, which was 10-fold greater than in stem cells. The induction of c-jun in TD and growth-arrested cells reached maximums at 0.5 J/m2; at this dose each was greater than in stem cells. The increases in c-fos and c-jun expression were transient in each phenotype reaching maximums from 0.5 to 1 h after irradiation. The expression of type IV collagenase was increased in the non-cycling phenotypes at 2-8 h after irradiation. However, collagenase expression was not detected in unirradiated or irradiated stem cells. These results suggest that growth arrest, not differentiation or DNA repair capacity, is the primary influence on gene induction after UV irradiation.