Glucagon-like Peptide-1 (GLP-1) Diminishes Neuronal Degeneration and Death Caused by NGF Deprivation by Suppressing Bim Induction

Glucagon-like peptide-1 (GLP-1) is a glucoincretin hormone most intensively studied for its actions on insulin secreting β-cells. GLP-1 and its receptor are also found in brain and accumulating evidence indicates that GLP-1 has neuroprotective actions. Here, we investigated whether GLP-1 protects neuronal cells from death evoked by nerve growth factor (NGF) withdrawal. Compromised trophic factor signaling may underlie neurodegenerative diseases ranging from Alzheimer disease to diabetic neuropathies. We report that GLP-1 provides sustained protection of cultured neuronal PC12 cells and sympathetic neurons from degeneration and death caused by NGF deprivation. Past work shows that NGF deprivation induces the pro-apoptotic protein Bim which contributes to neuron death. Here, we find that GLP-1 suppresses Bim induction promoted by NGF deprivation. Thus, GLP-1 may protect neurons, at least in part, by suppressing Bim induction. Our findings support the idea that drugs that mimic or elevate GLP-1 represent potential therapeutics for neurodegenerative diseases.     

Apoptosome dependent caspase-3 activation pathway is non-redundant and necessary for apoptosis in sympathetic neurons

Although sympathetic neurons are a well-studied model for neuronal apoptosis, the role of the apoptosome in activating caspases in these neurons remains debated. We find that the ability of sympathetic neurons to undergo apoptosis in response to nerve growth factor (NGF) deprivation is completely dependent on having an intact apoptosome pathway. Genetic deletion of Apaf-1, caspase-9, or caspase-3 prevents apoptosis after NGF deprivation, and importantly, allows these neurons to recover and survive long-term following readdition of NGF. The inability of caspase-3 deficient sympathetic neurons to undergo apoptosis is particularly striking, as apoptosis in dermal fibroblasts and cortical neurons proceeds even in the absence of caspase-3. Our results show that in contrast to dermal fibroblasts and cortical neurons, sympathetic neurons express no detectable levels of caspase-7. The strict requirement for an intact apoptosome, coupled with a lack of effector caspase redundancy, provides sympathetic neurons with a markedly increased control over their apoptotic pathway.     

Viral proteins E1B19K and p35 protect sympathetic neurons from cell death induced by NGF deprivation

To study molecular mechanisms underlying neuronal cell death, we have used sympathetic neurons from superior cervical ganglia which undergo programmed cell death when deprived of nerve growth factor. These neurons have been microinjected with expression vectors containing cDNAs encoding selected proteins to test their regulatory influence over cell death. Using this procedure, we have shown previously that sympathetic neurons can be protected from NGF deprivation by the protooncogene Bcl-2. We now report that the E1B19K protein from adenovirus and the p35 protein from baculovirus also rescue neurons. Other adenoviral proteins, E1A and E1B55K, have no effect on neuronal survival. E1B55K, known to block apoptosis mediated by p53 in proliferative cells, failed to rescue sympathetic neurons suggesting that p53 is not involved in neuronal death induced by NGF deprivation. E1B19K and p35 were also coinjected with Bcl-Xs which blocks Bcl-2 function in lymphoid cells. Although Bcl-Xs blocked the ability of Bcl- 2 to rescue neurons, it had no effect on survival that was dependent upon expression of E1B19K or p35.     

The p75 neurotrophin receptor: effects on neuron survival in vitro and interaction with death domain-containing adaptor proteins

The p75 neurotrophin receptor (p75NTR) is a death domain (DD) containing receptor of the TNF/FAS(APO-1) family. p75NTR has recently been shown to mediate apoptosis in certain types of neurons as well as in oligodendrocytes. The molecular mechanisms by which p75NTR stimulates apoptosis are still unknown. Here, we have tested whether overexpression of p75NTR could modulate survival of sympathetic neurons cultured in the presence or absence of NGF. Moreover, using the yeast two-hybrid system, we tested whether p75NTR intracellular domain was able to dimerize or interact with known DD-containing proteins including FADD, RIP, RAIDD and TRADD. We found that over-expression of p75NTR had no effect on the survival of sympathetic neurons cultured in the presence of NGF but instead delayed neuronal death following NGF deprivation. These results strongly support the finding that p75NTR is not involved in the apoptosis process induced by NGF deprivation in sympathetic neurons. We also foun d that the intracellular domain of p75NTR failed to associate either with itself or with other known DD-containing proteins. This suggests that the mechanisms by which p75NTR triggers apoptosis in certain cell types are different from those used by other receptors of the TNF/FAS family.     

Essential postmitochondrial function of p53 uncovered in DNA damage-induced apoptosis in neurons

In postmitotic sympathetic neurons, unlike most mitotic cells, death by apoptosis requires not only the release of cytochrome c from the mitochondria, but also an additional step to relieve X-linked inhibitor of apoptosis protein (XIAP)'s inhibition of caspases. Here, we examined the mechanism by which XIAP is inactivated following DNA damage and found that it is achieved by a mechanism completely different from that following apoptosis by nerve growth factor (NGF) deprivation. NGF deprivation relieves XIAP by selectively degrading it, whereas DNA damage overcomes XIAP via a p53-mediated induction of Apaf-1. Unlike wild-type neurons, p53-deficient neurons fail to overcome XIAP and remain resistant to cytochrome c after DNA damage. Restoring Apaf-1 induction in p53-deficient neurons is sufficient to overcome XIAP and sensitize cells to cytochrome c. Although a role for p53 in apoptosis upstream of cytochrome c release has been well established, this study uncovers an additional, essential role for p53 in regulating caspase activation downstream of mitochondria following DNA damage in neurons.     

Dominant-negative c-Jun promotes neuronal survival by reducing BIM expression and inhibiting mitochondrial cytochrome c release

Sympathetic neurons require nerve growth factor for survival and die by apoptosis in its absence. Key steps in the death pathway include c-Jun activation, mitochondrial cytochrome c release, and caspase activation. Here, we show that neurons rescued from NGF withdrawal-induced apoptosis by expression of dominant-negative c-Jun do not release cytochrome c from their mitochondria. Furthermore, we find that the mRNA for BIM(EL), a proapoptotic BCL-2 family member, increases in level after NGF withdrawal and that this is reduced by dominant-negative c-Jun. Finally, overexpression of BIM(EL) in neurons induces cytochrome c redistribution and apoptosis in the presence of NGF, and neurons injected with Bim antisense oligonucleotides or isolated from Bim(-/-) knockout mice die more slowly after NGF withdrawal.     

Characterization of apoptosis in cultured rat sympathetic neurons after nerve growth factor withdrawal

Sympathetic neurons depend on nerve growth factor (NGF) for their survival both in vivo and in vitro. In culture, the neurons die after NGF withdrawal by an autonomous cell death program but whether these neurons die by apoptosis is under debate. Using vital DNA stains and in situ nick translation, we show here that extensive chromatin condensation and DNA fragmentation occur before plasma membrane breakdown during the death of NGF-deprived rat sympathetic neurons in culture. Furthermore, kinetic analysis of chromatin condensation events within the cell population is consistent with a model which postulates that after NGF deprivation nearly all of the neurons die in this manner. Although the dying neurons display membrane blebbing, cell fragmentation into apoptotic bodies does not occur. Apoptotic events proceed rapidly at around the time neurons become committed to die, regardless of neuronal culture age. However the duration of NGF deprivation required to commit neurons to die, and the rate at which apoptosis occurs, increase with culture age. Thus, within the first week of culture, apoptosis is the predominant form of cell death in sympathetic neurons.     

Ceramide selectively inhibits apoptosis-associated events in NGF-deprived sympathetic neurons

Ceramide manifests both neurotoxic and neuroprotective properties depending on the experimental system. Ito and Horigome previously reported that ceramide delays apoptosis in a classic model of developmental programmed cell death, i.e. sympathetic neurons undergoing NGF deprivation.1 Here, we investigated the actions of ceramide upon the biochemical and genetic changes that occur in NGF deprived neurons. We correlate ceramide's neuroprotective actions with the ability of ceramide to antagonize NGF deprivation-induced oxidative stress and c-jun induction, both of which contribute to apoptosis in this model. However, ceramide did not block NGF deprivation-induced declines in RNA and protein synthesis, suggesting that ceramide does not slow all apoptosis-related events. Overall, these results are significant in that they show that ceramide acts early in the death cascade to antagonize two events necessary for NGF-deprivation induced neuronal apoptosis. Moreover, these results dissociate declines in neuronal function, i.e. macromolecular synthesis, from the neuronal death cascade.     

Nerve growth factor (NGF) down-regulates the Bcl-2 homology 3 (BH3) domain-only protein Bim and suppresses its proapoptotic activity by phosphorylation

Bim is a proapoptotic, BH3-domain-only member of the Bcl-2 family that plays a role in death of trophic factor-deprived sympathetic neurons as well as in other paradigms of apoptotic death. We report here that nerve growth factor (NGF) leads to both a slow down-regulation of Bim expression in neuronal PC12 cells and rapid Bim phosphorylation. Both effects appear to be mediated by the MEK/MAPK pathway. An assay for Bim-mediated death revealed that NGF-promoted phosphorylation suppresses the proapoptotic activity of Bim. The phosphorylation sites responsible for this effect in the extra long form of rBim were identified as Ser-109 and Thr-110. Thus, NGF protects neurons from the proapoptotic effects of Bim both by acute phosphorylation and the longer term repression of expression.     

Comparison Between the Timing of JNK activation, c-Jun Phosphorylation, and Onset of Death Commitment in Sympathetic Neurones

Abstract: We have investigated the relationship between c-Jun N-terminal kinase (JNK) activity, apoptosis, and the potential of survival factors to rescue primary rat sympathetic neurones deprived of trophic support. Incubation of sympathetic neurones in the absence of nerve growth factor (NGF) caused a time-dependent increase in JNK activity, which became apparent by 3 h and attained maximal levels that were three- to fourfold higher than activity measured in neurones maintained for the same periods with NGF. Continuous culture in the presence of either NGF or the cyclic AMP analogue 4-(8-chlorophenylthio) cyclic AMP (CPTcAMP) not only prevented JNK activation from occurring, but also suppressed JNK activity that had been elevated by prior culture of the neurones in the absence of trophic support. When either NGF or CPTcAMP was added to cultures that had been initially deprived of neurotrophic support for up to 10 h, this resulted in complete suppression of total JNK activity, arrest of apoptosis, and rescue of >90% of the neurones that did not display apoptotic morphology by this time. However, when either agent was added after more protracted periods of initial neurotrophin deprivation (≥ 14 h), although this also resulted in near-complete suppression of total JNK activity and short-term arrest of apoptosis, not all of the neurones that appeared to be nonapoptotic at the time of agent addition were rescued. The lack of death commitment after 10 h of maintained JNK activity was not due to a late induction of c-Jun expression, because the majority of newly isolated sympathetic neurones had already been expressing high levels of c-Jun in their nuclei for several hours, yet were capable of being rescued by NGF. Elevation of JNK activity as a result of neurotrophic-factor deprivation was also associated with enhanced phosphorylation of c-Jun, assessed by immunoblot analysis and immunocytochemistry, and addition of NGF to cultures previously deprived of neurotrophic support resulted in a reversion of the state of phospho-c-Jun to that observed in cultures that had been maintained in the continuous presence of trophic support. We conclude that activation of JNK and c-Jun phosphorylation are not necessarily rate-limiting for apoptosis induction. In some neurones undergoing prolonged NGF deprivation, suppression of JNK activity and c-Jun dephosphorylation by NGF may be insufficient to effect their rescue. Thus, if c-Jun mediates death by increasing the expression of “death” genes, these must become effective very close to the death commitment point.