Survival factor-mediated BAD phosphorylation raises the mitochondrial threshold for apoptosis.

Growth factor suppression of apoptosis correlates with the phosphorylation and inactivation of multiple proapoptotic proteins, including the BCL-2 family member BAD. However, the physiological events required for growth factors to block cell death are not well characterized. To assess the contribution of BAD inactivation to cell survival, we generated mice with point mutations in the BAD gene that abolish BAD phosphorylation at specific sites. We show that BAD phosphorylation protects cells from the deleterious effects of apoptotic stimuli and attenuates death pathway signaling by raising the threshold at which mitochondria release cytochrome c to induce cell death. These findings establish a function for endogenous BAD phosphorylation, and elucidate a mechanism by which survival kinases block apoptosis in vivo.

Disruption of ErbB receptor signaling in adult non-myelinating Schwann cells causes progressive sensory loss.

Here we studied the role of signaling through ErbB-family receptors in interactions between unmyelinated axons and non-myelinating Schwann cells in adult nerves. We generated transgenic mice that postnatally express a dominant-negative ErbB receptor in non-myelinating but not in myelinating Schwann cells. These mutant mice present a progressive peripheral neuropathy characterized by extensive Schwann cell proliferation and death, loss of unmyelinated axons and marked heat and cold pain insensitivity. At later stages, C-fiber sensory neurons die by apoptosis, a process that may result from reduced GDNF (glial cell line-derived neurotrophic factor) expression in the sciatic nerve. Neuregulin 1 (NRG1)-ErbB signaling mediates, therefore, reciprocal interactions between non-myelinating Schwann cells and unmyelinated sensory neuron axons that are critical for Schwann cell and C-fiber sensory neuron survival. This study provides new insights into ErbB signaling in adult Schwann cells, the contribution of non-myelinating Schwann cells in maintaining trophic support of sensory neurons, and the possible role of disrupted ErbB signaling in peripheral sensory neuropathies.

IGF2 knockout mice are resistant to kainic acid-induced seizures and neurodegeneration.

Insulin-like growth factor 2 (Igf2), a member of the insulin gene family, is important for brain development and has known neurotrophic properties. Though Igf2, its receptors, and binding proteins, are expressed in the adult CNS, their role in the adult brain is less well-understood. Here we studied how Igf2 deficiency affects brains of adult Igf2 knockout (Igf2(-/-)) mice following neurotoxic insult produced by the glutamate analog kainic acid (KA). Igf2(-/-) mice exhibited attenuated epileptiform activity in response to KA and were less susceptible to hippocampal neurodegeneration compared with Igf2(+/+) mice. Other brain areas protected by the lack of Igf2 included the amygdala complex, septal nuclei, and thalamic region. Apoptosis, as determined by TUNEL and Hoechst 33342 staining, was accordingly less for Igf2(-/-) mice. Hippocampal slices from Igf2(-/-) mice also were protected against the effects epileptogenic effects of KA compared to Igf2(+/+) mice suggesting that neuroprotection afforded by a lack of Igf2 may be developmental in origin and experiments demonstrating enhanced synaptic inhibition in slices taken from Igf2(-/-) mice support this hypothesis. Taken together, these results suggest that Igf2 may be important for mechanisms and circuits that contribute to neurodegeneration and epilepsy.

Partial rescue of the p35-/- brain phenotype by low expression of a neuronal-specific enolase p25 transgene.

Cyclin-dependent kinase 5 (Cdk5) is activated on binding of activator proteins p35 and p39. A N-terminally truncated p35, termed p25, is generated through cleavage by the Ca(2+)-dependent protease calpain after induction of ischemia in rat brain. p25 has been shown to accumulate in brains of patients with Alzheimer's disease and may contribute to A-beta peptide-mediated toxicity. Studies from transfected neurons as well as p35 and p25 transgenic mice have indicated that Cdk5, when activated by p25, gains some toxic function compared with p35/Cdk5. It remains unclear, however, whether p25/Cdk5 signaling additionally channels into pathways usually used by p35/Cdk5 and whether p25 is associated with a loss of p35 function. To clarify these issues, we have generated p25-transgenic mice in a p35-null background. We find that low levels of p25 during development induce a partial rescue of the p35-/- phenotype in several brain regions analyzed, including a rescue of cell positioning of a subset of neurons in the neocortex. In accordance with the partial rescue of brain anatomy, phosphorylation of the Cdk5 substrate mouse disabled 1 is partially restored during development. Besides this, p25/Cdk5 fails to phosphorylate other substrates that are normally phosphorylated by p35/Cdk5. Our results show that p25 can substitute for p35/Cdk5 under certain circumstances during development. In addition, they suggest that p25 may have lost some functions of p35.

Insulin receptor substrate-2 deficiency impairs brain growth and promotes tau phosphorylation.

Insulin resistance and diabetes might promote neurodegenerative disease, but a molecular link between these disorders is unknown. Many factors are responsible for brain growth, patterning, and survival, including the insulin-insulin-like growth factor (IGF)-signaling cascades that are mediated by tyrosine phosphorylation of insulin receptor substrate (IRS) proteins. Irs2 signaling mediates peripheral insulin action and pancreatic beta-cell function, and its failure causes diabetes in mice. In this study, we reveal two important roles for Irs2 signaling in the mouse brain. First, disruption of the Irs2 gene reduced neuronal proliferation during development by 50%, which dissociated brain growth from Irs1-dependent body growth. Second, neurofibrillary tangles containing phosphorylated tau accumulated in the hippocampus of old Irs2 knock-out mice, suggesting that Irs2 signaling is neuroprotective. Thus, dysregulation of the Irs2 branch of the insulin-Igf-signaling cascade reveals a molecular link between diabetes and neurodegenerative disease.

Glial fibrillary acidic protein expression and promoter activity in the inner ear of developing and adult mice.

The intermediate filament glial fibrillary acidic protein (GFAP) is a classic marker for several types of glial cells, including astrocytes and nonmyelinating Schwann cells. The pattern of expression of GFAP in the postnatal murine inner ear, from postnatal day 3 (P3) to P38, was studied by anti-GFAP immunostaining in wild-type mice as well as in two lines of transgenic mice expressing either beta-galactosidase (LacZ) or green fluorescent protein (GFP) under the control of the GFAP promoter. Analysis of protein and promoter activity shows that several classes of supporting cells in the sensory epithelia, as well as Schwann cells and satellite cells express GFAP. Early after birth, all cochlear supporting cells express GFAP, in a gradient decreasing in intensity from base to apex. After P15, GFAP expression in the organ of Corti is mostly restricted to supporting cells of the inner hair cell area (i.e., inner border and inner phalangeal cells) and outer hair cell area (i.e., Deiters' cells). A small population of limbic cells also showed expression in a base-to-apex gradient. In the vestibular organs, high expression was detected in supporting cells in extrastriolar regions of the utricular macula and in the canal ampullae, with weaker staining in the saccular macula. These results suggest that supporting cells of the inner ear have important similarities to glial cells and may play roles similar to those of astrocytes or Schwann cells in supporting the normal development and maintenance of neurons and sensory cells of the inner ear.

Placental glycogen stores are increased in mice with H19 null mutations but not in those with insulin or IGF type 1 receptor mutations.

The function of glycogen in the placenta remains controversial. Whether it is used as a source of fuel for placental consumption or by the fetus in times of need has yet to be determined. Two imprinted genes, insulin-like growth factor 2 (Igf2) and H19 are highly expressed in the placenta. We have previously demonstrated that mice with Igf2 deficiency have lower levels of placental glycogen. In this study, we used mice with targeted disruption of the H19 gene (H19(-/-)) to determine the importance of Igf2 over-expression in placental growth and glycogen stores. In addition, since Igf2 mediates most of its functions by signaling through the insulin and/or IGF Type 1 receptors, we determined whether gene deletions to these receptors could affect placental glycogen stores. Our data demonstrate that placentas from H19(-/-) mice are heavier, have higher number of glycogen cells, and contain larger glycogen concentrations than those of H19(+/+) mice. No differences in GSK-3, ERK, or total Akt expression or phosphorylation were found between genotypes; however, Akt1 protein expression levels were significantly increased in H19(-/-) placentas. Results obtained from insulin receptor or IGF Type 1 receptor mutant mice did not show differences in placental glycogen content compared to their wild-type littermates, supporting the notion of a specific placental Igf2 receptor. Taken together, these results support a role for Igf2 and Akt1, but not the insulin nor the IGF Type 1 receptors, in the regulation of placental growth and glycogen metabolism.

Decreased motoneuron survival in Igf2 null mice after sciatic nerve transection.

The search for therapeutic targets to prevent neurons from dying is ongoing and involves the exploration of a long list of neurotrophic factors. Insulin-like growth factor 2 (IGF2) is a member of the insulin family with known neurotrophic properties. In this study, we used Igf2 knockout (Igf2) neonate mice to determine whether Igf2 deficiency is detrimental to motor neuron survival after axonal injury. Results show that Igf2 neonatal mice are more susceptible to motor neuron damage than Igf2 mice, as they have a significantly lower percentage of motor neuron survival after a sciatic nerve transection. Neuronal survival was significantly improved in Igf2 mice when IGF2 was administered. These results support the role of IGF2 in neonatal motor neuron survival.

Repeated administration of ketamine may lead to neuronal degeneration in the developing rat brain.

BACKGROUND: This study was conducted to investigate, in vivo, the dose and duration effects of ketamine administration on neuronal degeneration in the developing rat brain. METHODS: Seven-day-old (P7) Sprague-Dawley rats were treated with intraperitoneal injections of ketamine, a noncompetitive N-methyl-D-aspartate receptor antagonist. Degenerating neurones were identified by the cupric-silver stain from 10 brain regions using the stereological disector method. RESULTS: A single dose of ketamine (25, 50 and 75 mg.kg-1) did not increase neuronal degeneration compared with the saline-treated control. However, repeated doses of ketamine (25 mg.kg-1) at 90-min intervals over 9 h increased degenerating neurones in seven out of 10 brain regions. CONCLUSIONS: These findings suggest that the duration of ketamine exposure correlates with increased neuronal degeneration in the developing rat brain.

Neurobehavioral and electroencephalographic abnormalities in Ube3a maternal-deficient mice.

Angelman syndrome (AS), characterized by motor dysfunction, mental retardation, and seizures, is caused by several genetic etiologies involving chromosome 15q11-q13, including mutations of the UBE3A gene. UBE3A encodes UBE3A/E6-AP, a ubiquitin-protein ligase, and shows brain-specific imprinting, with brain expression predominantly from the maternal allele. Lack of a functional maternal allele of UBE3A causes AS. In order to understand the causal relationship between maternal UBE3A mutations and AS, we have constructed a mouse model with targeted inactivation of Ube3a. The inactive allele contains a lacZ reporter gene for analysis of brain-specific imprinting. Maternal, but not paternal, transmission of the targeted allele leads to beta-galactosidase activity in hippocampal and cerebellar neurons. Maternal inheritance of the Ube3a mutant allele also causes impaired performance in tests of motor function and spatial learning, as well as abnormal hippocampal EEG recordings. As predicted from the dependence of UBE3A-mediated ubiquitination of p53 on HPV E6 protein, our maternal-deficient mice show normal brain p53 levels.