Paul K.Y. Wong

ATM promotes apoptosis and suppresses tumorigenesis in response to Myc

Overexpression of the c-myc oncogene contributes to the development of a significant number of human cancers. In response to deregulated Myc activity, the p53 tumor suppressor is activated to promote apoptosis and inhibit tumor formation. Here we demonstrate that p53 induction in response to Myc overexpression requires the ataxia-telangiectasia mutated (ATM) kinase, a major regulator of the cellular response to DNA double-strand breaks. In a transgenic mouse model overexpressing Myc in squamous epithelial tissues, inactivation of Atm suppresses apoptosis and accelerates tumorigenesis. Deregulated Myc expression induces DNA damage in primary transgenic keratinocytes and the formation of γH2AX and phospho-SMC1 foci in transgenic tissue. These findings suggest that Myc overexpression causes DNA damage in vivo and that the ATM-dependent response to this damage is critical for p53 activation, apoptosis, and the suppression of tumor development.

Loss of ATM impairs proliferation of neural stem cells through oxidative stress-mediated p38 MAPK signaling.

Ataxia‐telangiectasia (A‐T) is a genetic disorder caused by a mutation of the Atm gene, which controls DNA repair, cell cycling, and redox homeostasis. Even though oxidative stress has been implicated in the neurological anomalies in A‐T, the effects of ATM loss on neural stem cell (NSC) survival has remained elusive. In this study, we investigated the effects of oxidative stress on NSC proliferation in an animal model for A‐T neurodegeneration. We found that cultured subventricular zone neurosphere cells from Atm−/− mice show impaired proliferation, as well as intrinsic elevation of reactive oxygen species (ROS) levels, compared with those from Atm+/+ mice. We also show that increasing the levels of ROS by H2O2 treatment significantly reduces Atm+/+ neurosphere formation and proliferation. In Atm−/− neurosphere cells, the Akt and Erk1/2 pathways are disrupted, together with enhanced activity of the p38 mitogen‐activated protein kinase (MAPK). Treatment of these cells with the antioxidant N‐acetyl‐L‐cysteine (NAC) or with a p38 MAPK inhibitor restores normal proliferation and reduced expression of p21cip1 and p27kip1 in the Atm−/− NSCs. These observations indicate that ATM plays a crucial role in NSC proliferation, by activating Akt and Erk1/2 pathways and by suppressing ROS‐p38 MAPK signaling. Together, our results suggest that p38 MAPK signaling acts as a negative regulator of NSC proliferation in response to oxidative stress. These findings suggest a potential mechanism for neuronal cell loss as a result of oxidative stress in NSCs in progressive neurodegenerative diseases such as A‐T. STEM CELLS 2009;27:1987–1998

Activation of Transcription Factor Nrf-2 and Its Downstream Targets in Response to Moloney Murine Leukemia Virus ts1-Induced Thiol Depletion and Oxidative Stress in Astrocytes

ABSTRACT The neuroimmunodegenerative syndrome that develops in mice infected with ts1, a mutant of Moloney murine leukemia virus, resembles human AIDS. Both ts1 and human immunodeficiency virus type 1 infect astrocytes, microglia, and oligodendrocytes but do not infect neurons. Oxidative stress has been implicated in the neuropathology of AIDS dementia and other neurodegenerative diseases. We report here that ts1 infection of astrocytes (both transformed C1 cells and primary cultures) also induces thiol (i.e., glutathione and cysteine) depletion and reactive oxygen species (ROS) accumulation, events occurring in parallel with viral envelope precursor gPr80env accumulation and upregulated expression of endoplasmic reticulum chaperones GRP78 and GRP94. Furthermore, ts1-infected astrocytes mobilize their thiol redox defenses by upregulating levels of the Nrf-2 transcription factor, as well its targets, the xCT cystine/glutamate antiporter, γ-glutamylcysteine ligase, and glutathione peroxidase. Depleting intracellular thiols by treating uninfected astrocytes with buthionine sulfoximine (BSO), a glutathione synthesis inhibitor, or by culturing in cystine-deficient medium, also induces ROS accumulation, activates Nrf-2, and upregulates Nrf-2 target gene expression in these astrocytes. Overexpression of Nrf-2 in astrocytes specifically increases expression of the above thiol synthesis-related proteins. Further treatment with BSO or N-acetylcysteine in transfected cells modulates this expression. Thiol depletion also accelerates cell death, while thiol supplementation promotes survival of ts1-infected cells. Together, our results indicate that ts1 infection of astrocytes, along with ts1-induced gPr80env accumulation, endoplasmic reticulum stress, thiol depletion, and oxidative stress, accelerates cell death; in response to the thiol depletion and oxidative stress, astrocytes activate their Nrf-2-mediated thiol antioxidant defenses, promoting cell survival.

ATM deficiency induces oxidative stress and endoplasmic reticulum stress in astrocytes.

ATM kinase, the product of the ataxia telangiectasia mutated (Atm) gene, is activated by genomic damage. ATM plays a crucial role in cell growth and development. Here we report that primary astrocytes isolated from ATM-deficient mice grow slowly, become senescent, and die in culture. However, before reaching senescence, these primary Atm−/− astrocytes, like Atm−/− lymphocytes, show increased spontaneous DNA synthesis. These astrocytes also show markers of oxidative stress and endoplasmic reticulum (ER) stress, including increased levels of heat shock proteins (HSP70 and GRP78), malondialdehyde adducts, Cu/Zn superoxide dismutase, procaspase 12 cleavage, and redox-sensitive phosphorylation of extracellular signal-regulated protein kinase 1 and 2 (ERK1/2). In addition, HSP70 and ERK1/2 phosphorylation are upregulated in the cerebella of ATM-deficient mice. This increase in ERK1/2 phosphorylation is seen primarily in cerebellar astrocytes, or Bergmann glia, near degenerating Purkinje cells. ERK1/2 activation and astrogliosis are also found in other parts of the brain, for example, the cortex. We conclude that ATM deficiency induces intrinsic growth defects, oxidative stress, ER stress, and ERKs activation in astrocytes.

Oxidative Stress Is Linked to ERK1/2-p16 Signaling-mediated Growth Defect in ATM-deficient Astrocytes

The gene that encodes the ATM protein kinase is mutated in ataxia-telangiectasia (A-T). One of the prominent features of A-T is progressive neurodegeneration. We have previously reported that primary astrocytes isolated from Atm-/- mice grow slowly and die earlier than control cells in culture. However, the mechanisms for this remain unclear. We show here that intrinsic elevated intracellular levels of reactive oxygen species (ROS) are associated with the senescence-like growth defect of Atm-/- astrocytes. This condition is accompanied by constitutively higher levels of ERK1/2 phosphorylation and p16Ink4a in Atm-/- astrocytes. We also observe that ROS-induced up-regulation of p16Ink4a occurs correlatively with ERK1/2-dependent down-regulation and subsequent dissociation from chromatin of Bmi-1. Furthermore, both mitogen-activated protein kinase (MAPK)/ERK inhibitor PD98059 and antioxidant N-acetyl-l-cysteine restored normal proliferation of Atm-/- astrocytes. These results suggest that ATM is required for normal astrocyte growth through its ability to stabilize intracellular redox status and that the inability to control ROS is the molecular basis of limited cell growth of Atm-/- astrocytes. This defect may be mediated by a mechanism involving ERK1/2 activation and Bmi-1 derepression of p16Ink4a. These data identify new potential targets for therapeutic intervention in A-T neurodegeneration.

Possible involvement of both endoplasmic reticulum– and mitochondria-dependent pathways in MoMuLV-ts1–induced apoptosis in astrocytes

The Moloney murine leukemia virus (MoMuLV)-ts1 retrovirus, a naturally occurring mutant of MoMuLV-TB, causes a neuroimmunodegenerative syndrome in mice. The authors show here that ts1 triggers apoptosis in immortalized astrocytes, C1 cells, and primary cultured astrocytes, and that this apoptosis is caused by endoplasmic reticulum (ER) stress resulting from accumulation of the viral envelope preprotein gPr80env. In ts1-infected C1 cells, an unfolded protein response was identified by activation of the ER-resident transmembrane protein kinase PERK, an event that leads to hyperphosphorylation of eIF2α, up-regulation of GRP78, increased amounts of GADD153/CHOP, and cleavage of procaspase-12. Up-regulation of GRP78 and cleavage of procaspase-12 were also detected in primary cultured astrocytes infected with ts1. In ts1-infected C1 cells, ER stress was followed by mitochondrial stress, detected as mitochondrial transmembrane potential dissipation, cleavage of procaspase-9, and induction of activated caspase-3. In the brain-stems of ts1-infected mice, activated caspase-3 and damaged mitochondria were identified in astrocytes within areas showing spongiform degeneration. Together the data imply that both ER stress- and mitochondrial stress-related apoptotic pathways are involved in ts1-induced astrocyte death.

ts1, A mutant of moloney murine leukemia virus-TB, causes both immunodeficiency and neurologic disorders in BALB/c Mice

BALB/c mice infected with ts1, a mutant of Moloney murine leukemia virus-TB, develop generalized body wasting, profound neurologic disorders, severe thymic atrophy and lymphopenia due to destruction of T lymphocytes and drastic immunodeficiency. ts1 was found not only able to infect T lymphocytes but also to impair their function. In addition, ts1 also infects and induces syncyntia formation in macrophages. The genetic determinant(s) responsible for ts1s ability to induce immunodeficiency has been localized to the env gene.

Identification and characterization of a novel Nogo‐interacting mitochondrial protein (NIMP)

Nogo is a potent inhibitor of regeneration following spinal cord injury. To develop a better understanding of the mechanisms responsible for regenerative failure we used a yeast two‐ hybrid approach to try and identify proteins that interact with Nogo. We identified a novel mitochondrial protein designated Nogo‐interacting mitochondrial protein (NIMP) in a screen of an adult human brain cDNA library. This interaction was confirmed by co‐immunoprecipitation in both brain tissue (endogenous) and transfected HEK293T cells (overexpressed). In support of these studies we demonstrate that Nogo interacts with the UQCRC1 and UQCRC2 components of complex III, within the mitochondrial respiratory chain. The mitochondrial localization of NIMP was evidenced by confocal image analysis and western blot analysis of isolated mitochondria. NIMP is highly conserved and ubiquitously expressed in mitochondria‐enriched tissues. Within the CNS, NIMP‐like immunoreactivity is present in neurons and astrocytes. These data suggest that NIMP is a novel mitochondrial protein that interacts with Nogo. The interaction of Nogo with mitochondrial proteins may provide insight into the mechanisms for Nogo‐induced inhibition of neurite growth.

Attenuation of oxidative stress, inflammation and apoptosis by minocycline prevents retrovirus-induced neurodegeneration in mice

The ts1 mutant of the Moloney murine leukemia virus (MoMuLV) causes neurodegeneration in infected mice that resembles HIV-associated dementia. We have shown previously that ts1 infects glial cells in the brain, but not neurons. The most likely mechanism for ts1-mediated neurodegeneration is loss of glial redox support and glial cell toxicity to neurons. Minocycline has been shown to have neuroprotective effects in various models of neurodegeneration. This study was designed to determine whether and how minocycline prevents paralysis and death in ts1-infected mice. We show here that minocycline delays neurodegeneration in ts1-infected mice, and that it prevents death of cultured astrocytes infected by ts1 through attenuating oxidative stress, inflammation and apoptosis. Although minocycline reduces virus titers in the CNS of infected mice, it does not affect virus titers in infected mice thymi, spleens or infected C1 astrocytes. In addition, minocycline prevents death of primary neurons when they are cocultured with ts1-infected astrocytes, through mechanisms involving both inhibition of oxidative stress and upregulation of the transcription factor NF-E2-related factor 2 (Nrf2), which controls cellular antioxidant defenses. We conclude that minocycline delays retrovirus ts1-induced neurodegeneration involving antioxidant, anti-inflammation and anti-apoptotic mechanisms.

Retrovirus-Induced Oxidative Stress with Neuroimmunodegeneration Is Suppressed by Antioxidant Treatment with a Refined Monosodium α-Luminol (Galavit)

ABSTRACT Oxidative stress is involved in many human neuroimmunodegenerative diseases, including human immunodeficiency virus disease/AIDS. The retrovirus ts1, a mutant of Moloney murine leukemia virus, causes oxidative stress and progressive neuro- and immunopathology in mice infected soon after birth. These pathological changes include spongiform neurodegeneration, astrogliosis, thymic atrophy, and T-cell depletion. Astrocytes and thymocytes are directly infected and killed by ts1. Neurons are not infected, but they also die, most likely as an indirect result of local glial infection. Cytopathic effects of ts1 infection in cultured astrocytes are associated with accumulation of the viral envelope precursor protein gPr80env in the endoplasmic reticulum (ER), which triggers ER stress and oxidative stress. We have reported (i) that activation of the Nrf2 transcription factor and upregulation of antioxidative defenses occurs in astrocytes infected with ts1 in vitro and (ii) that some ts1-infected astrocytes survive infection by mobilization of these pathways. Here, we show that treatment with a refined monosodium α-luminol (Galavit; GVT) suppresses oxidative stress and Nrf2 activation in cultured ts1-infected astrocytes. GVT treatment also inhibits the development of spongiform encephalopathy and gliosis in the central nervous system (CNS) in ts1-infected mice, preserves normal cytoarchitecture in the thymus, and delays paralysis, thymic atrophy, wasting, and death. GVT treatment of infected mice reduces ts1-induced oxidative stress, cell death, and pathogenesis in both the CNS and thymus of treated animals. These studies suggest that oxidative stress mediates ts1-induced neurodegeneration and T-cell loss.